Effectors of innate immunity determination

Abstract
A method of identifying a polynucleotide or pattern of polynucleotides regulated by one or more sepsis or inflammatory inducing agents and inhibited by a peptide is described. A method of identifying a pattern of polynucleotide expression for inhibition of an inflammatory or septic response. The method includes contacting cells with LPS, LTA, CpG DNA and/or intact microbe or microbial components in the presence or absence of a cationic peptide; detecting a pattern of polynucleotide expression for the cells in the presence and absence of the peptide, wherein the pattern in the presence of the peptide represents inhibition of an inflammatory or septic response. Also included are compounds and agents identified by the methods of the invention. In another aspect, the invention provides methods and compounds for enhancing innate immunity in a subject.
Description
FIELD OF THE INVENTION

The present invention relates generally to peptides and specifically to peptides effective as therapeutics and for drug discovery related to pathologies resulting from microbial infections and for modulating innate immunity or anti-inflammatory activity.


BACKGROUND OF THE INVENTION

Infectious diseases are the leading cause of death worldwide. According to a 1999 World Health Organization study, over 13 million people die from infectious diseases each year. Infectious diseases are the third leading cause of death in North America, accounting for 20% of deaths annually and increasing by 50% since 1980. The success of many medical and surgical treatments also hinges on the control of infectious diseases. The discovery and use of antibiotics has been one of the great achievements of modern medicine. Without antibiotics, physicians would be unable to perform complex surgery, chemotherapy or most medical interventions such as catheterization.


Current sales of antibiotics are US$26 billion worldwide. However, the overuse and sometimes unwarranted use of antibiotics have resulted in the evolution of new antibiotic-resistant strains of bacteria. Antibiotic resistance has become part of the medical landscape. Bacteria such as vancomycin-resistant Enterococcus, VRE, and methicillin-resistant Staphylococcus aureus and MRSA, strains cannot be treated with antibiotics and often, patients suffering from infections with such bacteria die. Antibiotic discovery has proven to be one of the most difficult areas for new drug development and many large pharmaceutical companies have cut back or completely halted their antibiotic development programs. However, with the dramatic rise of antibiotic resistance, including the emergence of untreatable infections, there is a clear unmet medical need for novel types of anti-microbial therapies, and agents that impact on innate immunity would be one such class of agents.


The innate immune system is a highly effective and evolved general defense system. Elements of innate immunity are always present at low levels and are activated very rapidly when stimulated. Stimulation can include interaction of bacterial signaling molecules with pattern recognition receptors on the surface of the body's cells or other mechanisms of disease. Every day, humans are exposed to tens of thousands of potential pathogenic microorganisms through the food and water we ingest, the air we breathe and the surfaces, pets and people that we touch. The innate immune system acts to prevent these pathogens from causing disease. The innate immune system differs from so-called adaptive immunity (which includes antibodies and antigen-specific B- and T-lymphocytes) because it is always present, effective immediately, and relatively non-specific for any given pathogen. The adaptive immune system requires amplification of specific recognition elements and thus takes days to weeks to respond. Even when adaptive immunity is pre-stimulated by vaccination, it may take three days or more to respond to a pathogen whereas innate immunity is immediately or rapidly (hours) available. Innate immunity involves a variety of effector functions including phagocytic cells, complement, etc, but is generally incompletely understood. Generally speaking many innate immune responses are “triggered” by the binding of microbial signaling molecules with pattern recognition receptors termed Toll-like receptors on the surface of host cells. Many of these effector functions are grouped together in the inflammatory response. However too severe an inflammatory response can result in responses that are harmful to the body, and in an extreme case sepsis and potentially death can occur.


The release of structural components from infectious agents during infection causes an inflammatory response, which when unchecked can lead to the potentially lethal condition, sepsis. Sepsis occurs in approximately 780,000 patients in North America annually. Sepsis may develop as a result of infections acquired in the community such as pneumonia, or it may be a complication of the treatment of trauma, cancer or major surgery. Severe sepsis occurs when the body is overwhelmed by the inflammatory response and body organs begin to fail. Up to 120,000 deaths occur annually in the United Stated due to sepsis. Sepsis may also involve pathogenic microorganisms or toxins in the blood (e.g., septicemia), which is a leading cause of death among humans. Gram-negative bacteria are the organisms most commonly associated with such diseases. However, gram-positive bacteria are an increasing cause of infections. Gram-negative and Gram-positive bacteria and their components can all cause sepsis.


The presence of microbial components induce the release of pro-inflammatory cytokines of which tumor necrosis factor-α (TNF-α) is of extreme importance. TNF-α and other pro-inflammatory cytokines can then cause the release of other pro-inflammatory mediators and lead to an inflammatory cascade. Gram-negative sepsis is usually caused by the release of the bacterial outer membrane component, lipopolysaccharide (LPS; also referred to as endotoxin). Endotoxin in the blood, called endotoxemia comes primarily from a bacterial infection, and may be released during treatment with antibiotics. Gram-positive sepsis can be caused by the release of bacterial cell wall components such as lipoteichoic acid (LTA), peptidoglycan (PG), rhamnose-glucose polymers made by Streptococci, or capsular polysaccharides made by Staphylococci. Bacterial or other non-mammalian DNA that, unlike mammalian DNA, frequently contains unmethylated cytosine-guanosine dimers (CpG DNA) has also been shown to induce septic conditions including the production of TNF-α. Mammalian DNA contains CpG dinucleotides at a much lower frequency, often in a methylated form. In addition to their natural release during bacterial infections, antibiotic treatment can also cause release of the bacterial cell wall components LPS and LTA and probably also bacterial DNA. This can then hinder recovery from infection or even cause sepsis.


Cationic peptides are being increasingly recognized as a form of defense against infection, although the major effects recognized in the scientific and patent literature are the antimicrobial effects (Hancock, R. E. W., and R. Lehrer. 1998. Cationic peptides: a new source of antibiotics. Trends in Biotechnology 16:82-88.). Cationic peptides having antimicrobial activity have been isolated from a wide variety of organisms. In nature, such peptides provide a defense mechanism against microorganisms such as bacteria and yeast. Generally, these cationic peptides are thought to exert their antimicrobial activity on bacteria by interacting with the cytoplasmic membrane, and in most cases, forming channels or lesions. In gram-negative bacteria, they interact with LPS to permeabilize the outer membrane, leading to self promoted uptake across the outer membrane and access to the cytoplasmic membrane. Examples of cationic antimicrobial peptides include indolicidin, defensins, cecropins, and magainins.


Recently it has been increasingly recognized that such peptides are effectors in other aspects of innate immunity (Hancock, R. E. W. and G. Diamond. 2000. The role of cationic peptides in innate host defenses. Trends in Microbiology 8:402-410; Hancock, R. E. W. 2001. Cationic peptides: effectors in innate immunity and novel antimicrobials. Lancet Infectious Diseases 1:156-164) although it was not known if the antimicrobial and effector functions are independent.


Some cationic peptides have an affinity for binding bacterial products such as LPS and LTA. Such cationic peptides can suppress cytokine production in response to LPS, and to varying extents can prevent lethal shock. However it has not been proven as to whether such effects are due to binding of the peptides to LPS and LTA, or due to a direct interaction of the peptides with host cells. Cationic peptides are induced, in response to challenge by microbes or microbial signaling molecules like LPS, by a regulatory pathway similar to that used by the mammalian immune system (involving Toll receptors and the transcription factor; NFκB). Cationic peptides therefore appear to have a key role in innate immunity. Mutations that affect the induction of antibacterial peptides can reduce survival in response to bacterial challenge. As well, mutations of the Toll pathway of Drosophila that lead to decreased antifungal peptide expression result in increased susceptibility to lethal fungal infections. In humans, patients with specific granule deficiency syndrome, completely lacking in α-defensins, suffer from frequent and severe bacterial infections. Other evidence includes the inducibility of some peptides by infectious agents, and the very high concentrations that have been recorded at sites of inflammation. Cationic peptides may also regulate cell migration, to promote the ability of leukocytes to combat bacterial infections. For example, two human β-defensin peptides, HNP-1 and HNP-2, have been indicated to have direct chemotactic activity for murine and human T cells and monocytes, and human β-defensins appear to act as chemoattractants for immature dendritic cells and memory T cells through interaction with CCR6. Similarly, the porcine cationic peptide, PR-39 was found to be chemotactic for neutrophils. It is unclear however as to whether peptides of different structures and compositions share these properties.


The single known cathelicidin from humans, LL-37, is produced by myeloid precursors, testis, human keratinocytes during inflammatory disorders and airway epithelium. The characteristic feature of cathelicidin peptides is a high level of sequence identity at the N-terminus prepro regions termed the cathelin domain. Cathelicidin peptides are stored as inactive propeptide precursors that, upon stimulation, are processed into active peptides.


SUMMARY OF THE INVENTION

The present invention is based on the seminal discovery that based on patterns of polynucleotide expression regulated by endotoxic lipopolysaccharide, lipoteichoic acid, CpG DNA, or other cellular components (e.g., microbe or their cellular components), and affected by cationic peptides, one can screen for novel compounds that block or reduce sepsis and/or inflammation in a subject. Further, based on the use of cationic peptides as a tool, one can identify selective enhancers of innate immunity that do not trigger the sepsis reaction and that can block/dampen inflammatory and/or septic responses.


Thus, in one embodiment, a method of identifying a polynucleotide or pattern of polynucleotides regulated by one or more sepsis or inflammatory inducing agents and inhibited by a cationic peptide, is provided. The method of the invention includes contacting the polynucleotide or polynucleotides with one or more sepsis or inflammatory inducing agents and contacting the polynucleotide or polynucleotides with a cationic peptide either simultaneously or immediately thereafter. Differences in expression are detected in the presence and absence of the cationic peptide, and a change in expression, either up- or down-regulation, is indicative of a polynucleotide or pattern of polynucleotides that is regulated by a sepsis or inflammatory inducing agent and inhibited by a cationic peptide. In another aspect the invention provides a polynucleotide or polynucleotides identified by the above method. Examples of sepsis or inflammatory regulatory agents include LPS, LTA or CpG DNA or microbial components (or any combination thereof), or related agents.


In another embodiment, the invention provides a method of identifying an agent that blocks sepsis or inflammation including combining a polynucleotide identified by the method set forth above with an agent wherein expression of the polynucleotide in the presence of the agent is modulated as compared with expression in the absence of the agent and wherein the modulation in expression affects an inflammatory or septic response.


In another embodiment, the invention provides a method of identifying a pattern of polynucleotide expression for inhibition of an inflammatory or septic response by 1) contacting cells with LPS, LTA and/or CpG DNA in the presence or absence of a cationic peptide and 2) detecting a pattern of polynucleotide expression for the cells in the presence and absence of the peptide. The pattern obtained in the presence of the peptide represents inhibition of an inflammatory or septic response. In another aspect the pattern obtained in the presence of the peptide is compared to the pattern of a test compound to identify a compound that provides a similar pattern. In another aspect the invention provides a compound identified by the foregoing method.


In another embodiment, the invention provides a method of identifying an agent that enhances innate immunity by contacting a polynucleotide or polynucleotides that encode a polypeptide involved in innate immunity, with an agent of interest, wherein expression of the polynucleotide in the presence of the agent is modulated as compared with expression of the polynucleotide in the absence of the agent and wherein the modulated expression results in enhancement of innate immunity. Preferably, the agent does not stimulate a sepsis reaction in a subject. In one aspect, the agent increases the expression of an anti-inflammatory polynucleotide. Exemplary, but non-limiting anti-inflammatory polynucleotides encode proteins such as IL-1 R antagonist homolog 1 (AI167887), IL-10 R beta (AA486393), IL-10 R alpha (U00672) TNF Receptor member 1B (AA150416), TNF receptor member 5 (H98636), TNF receptor member 11 b (AA194983), IK cytokine down-regulator of HLA II (R39227), TGF-B inducible early growth response 2 (AI473938), CD2 (AA927710), IL-19 (NM013371) or IL-10 (M57627). In one aspect, the agent decreases the expression of polynucleotides encoding proteasome subunits involved in NF-κB activation such as proteasome subunit 26S (NM013371). In one aspect, the agent may act as an antagonist of protein kinases. In one aspect, the agent is a peptide selected from SEQ ID NO:4-54.


In another embodiment, the invention provides a method of identifying a pattern of polynucleotide expression for identification of a compound that selectively enhances innate immunity. The invention includes detecting a pattern of polynucleotide expression for cells contacted in the presence and absence of a cationic peptide, wherein the pattern in the presence of the peptide represents stimulation of innate immunity; detecting a pattern of polynucleotide expression for cells contacted in the presence of a test compound, wherein a pattern with the test compound that is similar to the pattern observed in the presence of the cationic peptide, is indicative of a compound that enhances innate immunity. It is preferred that the compound does not stimulate a septic reaction in a subject.


In another embodiment, the invention provides a method for inferring a state of infection in a mammalian subject from a nucleic acid sample of the subject by identifying in the nucleic acid sample a polynucleotide expression pattern exemplified by an increase in polynucleotide expression of at least 2 polynucleotides in Table 50, 51 and or 52, as compared to a non-infected subject. Also included is a polynucleotide expression pattern obtained by any of the methods described above.


In another aspect a cationic peptide that is an antagonist of CXCR-4 is provided. In still another aspect, a method of identifying a cationic peptide that is an antagonist of CXCR-4 by contacting T cells with SDF-1 in the presence of absence of a test peptide and measuring chemotaxis is provided. A decrease in chemotaxis in the presence of the test peptide is indicative of a peptide that is an antagonist of CXCR-4. Cationic peptide also acts to reduce the expression of the SDF-1 receptor polynucleotide (NM013371).


In all of the above described methods, the compounds or agents of the invention include but are not limited to peptides, cationic peptides, peptidomimetics, chemical compounds, polypeptides, nucleic acid molecules and the like.


In still another aspect the invention provides an isolated cationic peptide. An isolated cationic peptide of the invention is represented by one of the following general formulas and the single letter amino acid code:


X1X2X3IX4PX4IPX5X2X1 (SEQ ID NO: 4), where X1 is one or two of R, L or K, X2 is one of C, S or A, X3 is one of R or P, X4 is one of A or V and X5 is one of V or W;


X1LX2X3KX4X2X5X3PX3X1 (SEQ ID NO: 11), where X1 is one or two of D, E, S, T or N, X2 is one or two of P, G or D, X3 is one of G, A, V, L, I or Y, X4 is one of R, K or H and X5 is one of S, T, C, M or R;


X1X2X3X4WX4WX4X5K (SEQ ID NO: 18), where X1 is one to four chosen from A, P or R, X2 is one or two aromatic amino acids (F, Y and W), X3 is one of P or K, X4 is one, two or none chosen from A, P, Y or W and X5 is one to three chosen from R or P;


X1X2X3X4X1VX3X4RGX4X3X4X1X3X1 (SEQ ID NO: 25) where X1 is one or two of R or K, X2 is a polar or charged amino acid (S, T, M, N, Q, D, E, K, R and H), X3 is C, S, M, D or A and X4 is F, I, V, M or R;


X1X2X3X4X1VX5X4RGX4X5X4X1X3X1 (SEQ ID NO: 32), where X1 is one or two of R or K, X2 is a polar or charged amino acid (S, T, M, N, Q, D, E, K, R and H), X3 is one of C, S, M, D or A, X4 is one of F, I, V, M or R and X5 is one of A, I, S, M, D or R; and


KX1KX2FX2KMLMX2ALKKX3 (SEQ ID NO: 39), where X1 is a polar amino acid (C, S, T, M, N and Q); X2 is one of A, L, S or K and X3 is 1-17 amino acids chosen from G, A, V, L, I, P, F, S, T, K and H;


KWKX2X1X1X2X2X1X2X2X1X1X2X21FHTALKPISS (SEQ ID NO: 46), where X1 is a hydrophobic amino acid and X2 is a hydrophilic amino acid.


Additionally, in another aspect the invention provides isolated cationic peptides KWKSFLRTFKSPVRTVFHTALKPISS (SEQ ID NO: 53) and KWKSYAHTIMSPVRLVFHTALKPISS (SEQ ID NO: 54).


Also provided are nucleic acid sequences encoding the cationic peptides of the invention, vectors including such polynucleotides and host cells containing the vectors.


In another embodiment, the invention provides methods for stimulating or enhancing innate immunity in a subject comprising administering to the subject a peptide of the invention, for example, peptides set forth in SEQ ID NO: 1-4, 11, 18, 25, 32, 39, 46, 53 or 54. As shown in the Examples herein, innate immunity can be evidenced by monocyte activation, proliferation, differentiation or MAP kinase pathway activation just by way of example. In one aspect, the method includes further administering a serum factor such as GM-CSF to the subject. The subject is preferably any mammal and more particularly a human subject.


In another embodiment, the invention provides a method of stimulating innate immunity in a subject having or at risk of having an infection including administering to the subject a sub-optimal concentration of an antibiotic in combination with a peptide of the invention. In one aspect, the peptide is SEQ ID NO:1 or SEQ ID NO:7.





BRIEF DESCRIPTION OF THE FIGURES


FIG. 1 demonstrates the synergy of Seq ID No: 7 with cefepime in curing S. aureus infections. CD-1 mice (8/group) were given 1×107 S. aureus in 5% porcine mucin via IP injection. Test compound (50 μg-2.5 mg/kg) was given via a separate IP injection 6 hours after S. aureus. At this time Cefepime was also given at a dose of 0.1 mg/kg. Mice were euthanized 24 hr later, blood removed and plated for viable counts. The average±standard error is shown. This experiment was repeated twice.



FIG. 2 shows exposure to SEQ ID NO: 1 induces phosphorylation of ERK1/2 and p38. Lysates from human peripheral blood derived monocytes were exposed to 50 μg/ml of SEQ ID NO: 1 for 15 minutes. A) Antibodies specific for the phosphorylated forms of ERK and p38 were used to detect activation of ERK1/2 and p38. All donors tested showed increased phosphorylation of ERK1/2 and p38 in response to SEQ ID NO: 1 treatment. One representative donor of eight. Relative amounts of phosphorylation of ERK (B) and p38(C) were determined by dividing the intensities of the phosphorylated bands by the intensity of the corresponding control band as described in the Materials and Methods.



FIG. 3 shows LL-37 induced phosphorylation of ERK1/2 does not occur in the absence of serum and the magnitude of phosphorylation is dependent upon the type of serum present. Human blood derived monocytes were treated with 50 μg/ml of LL-37 for 15 minutes. Lysates were run on a 12% acrylamide gel then transferred to nitrocellulose membrane and probed with antibodies specific for the phosphorylated (active) form of the kinase. To normalize for protein loading, the blots were reprobed with β-actin. Quantification was done with ImageJ software. The FIG. 3 inset demonstrates that LL-37 is unable to induce MAPK activation in human monocytes under serum free conditions. Cells were exposed to 50 mg/ml of LL-37 (+), or endotoxin free water (−) as a vehicle control, for 15 minutes. (A) After exposure to LL-37 in media containing 10% fetal calf serum, phosphorylated ERK1/2 was detectable, however, no phosphorylation of ERK1/2 was detected in the absence of serum (n=3). (B) Elk-1, a transcription factor downstream of ERK1/2, was activated (phosphorylated) upon exposure to 50 μg/ml of LL-37 in media containing 10% fetal calf serum, but not in the absence of serum (n=2).



FIG. 4 shows LL-37 induced activation of ERK1/2 occurs at lower concentrations and is amplified in the presence of certain cytokines. When freshly isolated monocytes were stimulated in media containing both GM-CSF (100 ng/ml) and IL-4 (10 ng/ml) LL-37 induced phosphorylation of ERK1/2 was apparent at concentrations as low as 5 μg/ml. This synergistic activation of ERK1/2 seems to be due primarily to GM-CSF.



FIG. 5 shows peptide affects both transcription of various cytokine genes and release of IL-8 in the 16HBE4o-human bronchial epithelial cell line. Cells were grown to confluency on a semi-permeable membrane and stimulated on the apical surface with 50 μg/ml of SEQ ID NO: 1 for four hours. A) SEQ ID NO: 1 treated cells produced significantly more IL-8 than controls, as detected by ELISA in the supernatant collected from the apical surface, but not from the basolateral surface. Mean±SE of three independent experiments shown, asterisk indicates p=0.002. B) RNA was collected from the above experiments and RT-PCR was performed. A number of cytokine genes known to be regulated by either ERK1/2 or p38 were up-regulated upon stimulation with peptide. The average of two independent experiments is shown.





DETAILED DESCRIPTION OF THE INVENTION

The present invention provides novel cationic peptides, characterized by a group of generic formulas, which have ability to modulate (e.g., up- and/or down regulate) polynucleotide expression, thereby regulating sepsis and inflammatory responses and/or innate immunity.


“Innate immunity” as used herein refers to the natural ability of an organism to defend itself against invasions by pathogens. Pathogens or microbes as used herein, may include, but are not limited to bacteria, fungi, parasite, and viruses. Innate immunity is contrasted with acquired/adaptive immunity in which the organism develops a defensive mechanism based substantially on antibodies and/or immune lymphocytes that is characterized by specificity, amplifiability and self vs. non-self dsicrimination. With innate immunity, broad, nonspecific immunity is provided and there is no immunologic memory of prior exposure. The hallmarks of innate immunity are effectiveness against a broad variety of potential pathogens, independence of prior exposure to a pathogen, and immediate effectiveness (in contrast to the specific immune response which takes days to weeks to be elicited). In addition, innate immunity includes immune responses that affect other diseases, such as cancer, inflammatory diseases, multiple sclerosis, various viral infections, and the like.


As used herein, the term “cationic peptide” refers to a sequence of amino acids from about 5 to about 50 amino acids in length. In one aspect, the cationic peptide of the invention is from about 10 to about 35 amino acids in length. A peptide is “cationic” if it possesses sufficient positively charged amino acids to have a pKa greater than 9.0. Typically, at least two of the amino acid residues of the cationic peptide will be positively charged, for example, lysine or arginine. “Positively charged” refers to the side chains of the amino acid residues which have a net positive charge at pH 7.0. Examples of naturally occurring cationic antimicrobial peptides which can be recombinantly produced according to the invention include defensins, cathelicidins, magainins, melittin, and cecropins, bactenecins, indolicidins, polyphemusins, tachyplesins, and analogs thereof. A variety of organisms make cationic peptides, molecules used as part of a non-specific defense mechanism against microorganisms. When isolated, these peptides are toxic to a wide variety of microorganisms, including bacteria, fungi, and certain enveloped viruses. While cationic peptides act against many pathogens, notable exceptions and varying degrees of toxicity exist. However this patent reveals additional cationic peptides with no toxicity towards microorganisms but an ability to protect against infections through stimulation of innate immunity, and this invention is not limited to cationic peptides with antimicrobial activity. In fact, many peptides useful in the present invention do not have antimicrobial activity.


Cationic peptides known in the art include for example, the human cathelicidin LL-37, and the bovine neutrophil peptide indolicidin and the bovine variant of bactenecin, Bac2A.












LL-37
LLGDFFRKSKEKIGKEFKRIVQRI
(SEQ ID NO: 1)




KDFLRNLVPRTES





Indolicidin
ILPWKWPWWPWRR-NH2
(SEQ ID NO: 2)





Bac2A
RLARIVVIRVAR-NH2
(SEQ ID NO: 3)






In innate immunity, the immune response is not dependent upon antigens. The innate immunity process may include the production of secretory molecules and cellular components as set forth above. In innate immunity, the pathogens are recognized by receptors encoded in the germline. These Toll-like receptors have broad specificity and are capable of recognizing many pathogens. When cationic peptides are present in the immune response, they aid in the host response to pathogens. This change in the immune response induces the release of chemokines, which promote the recruitment of immune cells to the site of infection.


Chemokines, or chemoattractant cytokines, are a subgroup of immune factors that mediate chemotactic and other pro-inflammatory phenomena (See, Schall, 1991, Cytokine 3:165-183). Chemokines are small molecules of approximately 70-80 residues in length and can generally be divided into two subgroups, α which have two N-terminal cysteines separated by a single amino acid (CxC) and β which have two adjacent cysteines at the N terminus (CC). RANTES, MIP-1α and MIP-1β are members of the β subgroup (reviewed by Horuk, R., 1994, Trends Pharmacol. Sci, 15:159-165; Murphy, P. M., 1994, Annu. Rev. Immunol., 12:593-633). The amino terminus of the β chemokines RANTES, MCP-1, and MCP-3 have been implicated in the mediation of cell migration and inflammation induced by these chemokines. This involvement is suggested by the observation that the deletion of the amino terminal 8 residues of MCP-1, amino terminal 9 residues of MCP-3, and amino terminal 8 residues of RANTES and the addition of a methionine to the amino terminus of RANTES, antagonize the chemotaxis, calcium mobilization and/or enzyme release stimulated by their native counterparts (Gong et al., 1996 J. Biol. Chem. 271:10521-10527; Proudfoot et al., 1996 J. Biol. Chem. 271:2599-2603). Additionally, α chemokine-like chemotactic activity has been introduced into MCP-1 via a double mutation of Tyr 28 and Arg 30 to leucine and valine, respectively, indicating that internal regions of this protein also play a role in regulating chemotactic activity (Beall et al., 1992, J. Biol. Chem. 267:3455-3459).


The monomeric forms of all chemokines characterized thus far share significant structural homology, although the quaternary structures of α and β groups are distinct. While the monomeric structures of the β and α chemokines are very similar, the dimeric structures of the two groups are completely different. An additional chemokine, lymphotactin, which has only one N terminal cysteine has also been identified and may represent an additional subgroup (γ) of chemokines (Yoshida et al., 1995, FEBS Lett. 360:155-159; and Kelner et al., 1994, Science 266:1395-1399).


Receptors for chemokines belong to the large family of G-protein coupled, 7 transmembrane domain receptors (GCR's) (See, reviews by Horuk, R., 1994, Trends Pharmacol. Sci. 15:159-165; and Murphy, P. M., 1994, Annu. Rev. Immunol. 12:593-633). Competition binding and cross-desensitization studies have shown that chemokine receptors exhibit considerable promiscuity in ligand binding. Examples demonstrating the promiscuity among β chemokine receptors include: CC CKR-1, which binds RANTES and MIP-1α (Neote et al., 1993, Cell 72:415-425), CC CKR-4, which binds RANTES, MIP-1α, and MCP-1 (Power et al., 1995, J. Biol. Chem. 270:19495-19500), and CC CKR-5, which binds RANTES, MIP-1α, and MIP-1β (Alkhatib et al., 1996, Science, in press and Dragic et al., 1996, Nature 381:667-674). Erythrocytes possess a receptor (known as the Duffy antigen) which binds both a and P chemokines (Horuk et al., 1994, J. Biol. Chem. 269:17730-17733; Neote et al., 1994, Blood 84:44-52; and Neote et al., 1993, J. Biol. Chem. 268:12247-12249). Thus the sequence and structural homologies evident among chemokines and their receptors allows some overlap in receptor-ligand interactions.


In one aspect, the present invention provides the use of compounds including peptides of the invention to reduce sepsis and inflammatory responses by acting directly on host cells. In this aspect, a method of identification of a polynucleotide or polynucleotides that are regulated by one or more sepsis or inflammatory inducing agents is provided, where the regulation is altered by a cationic peptide. Such sepsis or inflammatory inducing agents include, but are not limited to endotoxic lipopolysaccharide (LPS), lipoteichoic acid (LTA) and/or CpG DNA or intact bacteria or other bacterial components. The identification is performed by contacting the polynucleotide or polynucleotides with the sepsis or inflammatory inducing agents and further contacting with a cationic peptide either simultaneously or immediately after. The expression of the polynucleotide in the presence and absence of the cationic peptide is observed and a change in expression is indicative of a polynucleotide or pattern of polynucleotides that is regulated by a sepsis or inflammatory inducing agent and inhibited by a cationic peptide. In another aspect, the invention provides a polynucleotide identified by the method.


Once identified, such polynucleotides will be useful in methods of screening for compounds that can block sepsis or inflammation by affecting the expression of the polynucleotide. Such an effect on expression may be either up regulation or down regulation of expression. By identifying compounds that do not trigger the sepsis reaction and that can block or dampen inflammatory or septic responses, the present invention also presents a method of identifying enhancers of innate immunity. Additionally, the present invention provides compounds that are used or identified in the above methods.


Candidate compounds are obtained from a wide variety of sources including libraries of synthetic or natural compounds. For example, numerous means are available for random and directed synthesis of a wide variety of organic compounds and biomolecules, including expression of randomized oligonucleotides and oligopeptides. Alternatively, libraries of natural compounds in the form of bacterial, fungal, plant and animal extracts are available or readily produced. Additionally, natural or synthetically produced libraries and compounds are readily modified through conventional chemical, physical and biochemical means, and may be used to produce combinatorial libraries. Known pharmacological agents may be subjected to directed or random chemical modifications, such as acylation, alkylation, esterification, amidification, and the like to produce structural analogs. Candidate agents are also found among biomolecules including, but not limited to: peptides, peptidiomimetics, saccharides, fatty acids, steroids, purines, pyrimidines, polypeptides, polynucleotides, chemical compounds, derivatives, structural analogs or combinations thereof.


Incubating components of a screening assay includes conditions which allow contact between the test compound and the polynucleotides of interest. Contacting includes in solution and in solid phase, or in a cell. The test compound may optionally be a combinatorial library for screening a plurality of compounds. Compounds identified in the method of the invention can be further evaluated, detected, cloned, sequenced, and the like, either in solution or after binding to a solid support, by any method usually applied to the detection of a compound.


Generally, in the methods of the invention, a cationic peptide is utilized to detect and locate a polynucleotide that is essential in the process of sepsis or inflammation. Once identified, a pattern of polynucleotide expression may be obtained by observing the expression in the presence and absence of the cationic peptide. The pattern obtained in the presence of the cationic peptide is then useful in identifying additional compounds that can inhibit expression of the polynucleotide and therefore block sepsis or inflammation. It is well known to one of skill in the art that non-peptidic chemicals and peptidomimetics can mimic the ability of peptides to bind to receptors and enzyme binding sites and thus can be used to block or stimulate biological reactions. Where an additional compound of interest provides a pattern of polynucleotide expression similar to that of the expression in the presence of a cationic peptide, that compound is also useful in the modulation of sepsis or an innate immune response. In this manner, the cationic peptides of the invention, which are known inhibitors of sepsis and inflammation and enhancers of innate immunity are useful as tools in the identification of additional compounds that inhibit sepsis and inflammation and enhance innate immunity.


As can be seen in the Examples below, peptides of the invention have a widespread ability to reduce the expression of polynucleotides regulated by LPS. High levels of endotoxin in the blood are responsible for many of the symptoms seen during a serious infection or inflammation such as fever and an elevated white blood cell count. Endotoxin is a component of the cell wall of Gram-negative bacteria and is a potent trigger of the pathophysiology of sepsis. The basic mechanisms of inflammation and sepsis are related. In Example 1, polynucleotide arrays were utilized to determine the effect of cationic peptides on the transcriptional response of epithelial cells. Specifically, the effects on over 14,000 different specific polynucleotide probes induced by LPS were observed. The tables show the changes seen with cells treated with peptide compared to control cells. The resulting data indicated that the peptides have the ability to reduce the expression of polynucleotides induced by LPS.


Example 2, similarly, shows that peptides of the invention are capable of neutralizing the stimulation of immune cells by Gram positive and Gram negative bacterial products. Additionally, it is noted that certain pro-inflammatory polynucleotides are down-regulated by cationic peptides, as set forth in table 24 such as TLR1 (AI339155), TLR2 (T57791), TLR5 (N41021), TNF receptor-associated factor 2 (T55353), TNF receptor-associated factor 3 (AA504259), TNF receptor superfamily, member 12 (W71984), TNF receptor superfamily, member 17 (AA987627), small inducible cytokine subfamily B, member 6 (AI889554), IL-12R beta 2 (AA977194), IL-18 receptor 1 (AA482489), while anti-inflammatory polynucleotides are up-regulated by cationic peptides, as seen in table 25 such as IL-1 R antagonist homolog 1 (AI167887), IL-10 R beta (AA486393), TNF Receptor member 1B (AA150416), TNF receptor member 5 (H98636), TNF receptor member 11b (AA194983), IK cytokine down-regulator of HLA II (R39227), TGF-B inducible early growth response 2 (AI473938), or CD2 (AA927710). The relevance and application of these results are confirmed by an in vivo application to mice.


In another aspect, the invention provides a method of identifying an agent that enhances innate immunity. In the method, a polynucleotide or polynucleotides that encode a polypeptide involved in innate immunity is contacted with an agent of interest. Expression of the polynucleotide is determined, both in the presence and absence of the agent. The expression is compared and of the specific modulation of expression was indicative of an enhancement of innate immunity. In another aspect, the agent does not stimulate a septic reaction as revealed by the lack of upregulation of the pro-inflammatory cytokine TNF-α. In still another aspect the agent reduces or blocks the inflammatory or septic response. In yet another aspect, the agent reduces the expression of TNF-α and/or interleukins including, but not limited to, IL-1β, IL-6, IL-12 p40, IL-12 p70, and IL-8.


In another aspect, the invention provides methods of direct polynucleotide regulation by cationic peptides and the use of compounds including cationic peptides to stimulate elements of innate immunity. In this aspect, the invention provides a method of identification of a pattern of polynucleotide expression for identification of a compound that enhances innate immunity. In the method of the invention, an initial detection of a pattern of polynucleotide expression for cells contacted in the presence and absence of a cationic peptide is made. The pattern resulting from polynucleotide expression in the presence of the peptide represents stimulation of innate immunity. A pattern of polynucleotide expression is then detected in the presence of a test compound, where a resulting pattern with the test compound that is similar to the pattern observed in the presence of the cationic peptide is indicative of a compound that enhances innate immunity. In another aspect, the invention provides compounds that are identified in the above methods. In another aspect, the compound of the invention stimulates chemokine or chemokine receptor expression. Chemokine or chemokine receptors may include, but are not limited to CXCR4, CXCR1, CXCR2, CCR2, CCR4, CCR5, CCR6, MIP-1 alpha, MDC, MIP-3 alpha, MCP-1, MCP-2, MCP-3, MCP-4, MCP-5, and RANTES. In still another aspect, the compound is a peptide, peptidomimetic, chemical compound, or a nucleic acid molecule.


In still another aspect the polynucleotide expression pattern includes expression of pro-inflammatory polynucleotides. Such pro-inflammatory polynucleotides may include, but are not limited to, ring finger protein 10 (D87451), serine/threonine protein kinase MASK (AB040057), KIAA0912 protein (AB020719), KIAA0239 protein (D87076), RAP1, GTPase activating protein 1 (M64788), FEM-1-like death receptor binding protein (AB007856), cathepsin S (M90696), hypothetical protein FLJ20308 (AK000315), pim-1 oncogene (M54915), proteasome subunit beta type 5 (D29011), KIAA0239 protein (D87076), mucin 5 subtype B tracheobronchial (AJ001403), cAMP response element-binding protein CREBPa, integrin alpha M (J03925), Rho-associated kinase 2 (NM 004850), PTD017 protein (AL050361) unknown genes (AK00143, AK034348, AL049250, AL16199, AL031983) and any combination thereof. In still another aspect the polynucleotide expression pattern includes expression of cell surface receptors that may include but is not limited to retinoic acid receptor (X06614), G protein-coupled receptors (Z94155, X81892, U52219, U22491, AF015257, U66579) chemokine (C-C motif) receptor 7 (L31584), tumor necrosis factor receptor superfamily member 17 (Z29575), interferon gamma receptor 2 (U05875), cytokine receptor-like factor 1 (AF059293), class I cytokine receptor (AF053004), coagulation factor II (thrombin) receptor-like 2 (U92971), leukemia inhibitory factor receptor (NM002310), interferon gamma receptor 1 (AL050337).


In Example 4 it can be seen that the cationic peptides of the invention alter polynucleotide expression in macrophage and epithelial cells. The results of this example show that pro-inflammatory polynucleotides are down-regulated by cationic peptides (Table 24) whereas anti-inflammatory polynucleotides are up-regulated by cationic peptides (Table 25).


It is shown below, for example, in tables 1-15, that cationic peptides can neutralize the host response to the signaling molecules of infectious agents as well as modify the transcriptional responses of host cells, mainly by down-regulating the pro-inflammatory response and/or up-regulating the anti-inflammatory response. Example 5 shows that the cationic peptides can aid in the host response to pathogens by inducing the release of chemokines, which promote the recruitment of immune cells to the site of infection. The results are confirmed by an in vivo application to mice.


It is seen from the examples below that cationic peptides have a substantial influence on the host response to pathogens in that they assist in regulation of the host immune response by inducing selective pro-inflammatory responses that for example promote the recruitment of immune cells to the site of infection but not inducing potentially harmful pro-inflammatory cytokines. Sepsis appears to be caused in part by an overwhelming pro-inflammatory response to infectious agents. Cationic peptides aid the host in a “balanced” response to pathogens by inducing an anti-inflammatory response and suppressing certain potentially harmful pro-inflammatory responses.


In Example 7, the activation of selected MAP kinases was examined, to study the basic mechanisms behind the effects of interaction of cationic peptides with cells. Macrophages activate MEK/ERK kinases in response to bacterial infection. MEK is a MAP kinase kinase that when activated, phosphorylates the downstream kinase ERK (extracellular regulated kinase), which then dimerizes and translocates to the nucleus where it activates transcription factors such as Elk-1 to modify polynucleotide expression. MEK/ERK kinases have been shown to impair replication of Salmonella within macrophages. Signal transduction by MEK kinase and NADPH oxidase may play an important role in innate host defense against intracellular pathogens. By affecting the MAP kinases as shown below the cationic peptides have an effect on bacterial infection. The cationic peptides can directly affect kinases. Table 21 demonstrates but is not limited to MAP kinase polynucleotide expression changes in response to peptide. The kinases include MAP kinase kinase 6 (H070920), MAP kinase kinase 5 (W69649), MAP kinase 7 (H39192), MAP kinase 12 (AI936909) and MAP kinase-activated protein kinase 3 (W68281).


In another method, the methods of the invention may be used in combination, to identify an agent with multiple characteristics, i.e. a peptide with anti-inflammatory/anti-sepsis activity, and the ability to enhance innate immunity, in part by inducing chemokines in vivo.


In another aspect, the invention provides a method for inferring a state of infection in a mammalian subject from a nucleic acid sample of the subject by identifying in the nucleic acid sample a polynucleotide expression pattern exemplified by an increase in polynucleotide expression of at least 2 polynucleotides in Table 55 as compared to a non-infected subject. In another aspect the invention provides a method for inferring a state of infection in a mammalian subject from a nucleic acid sample of the subject by identifying in the nucleic acid sample a polynucleotide expression pattern exemplified by a polynucleotide expression of at least 2 polynucleotides in Table 56 or Table 57 as compared to a non-infected subject. In one aspect of the invention, the state of infection is due to infectious agents or signaling molecules derived therefrom, such as, but not limited to, Gram negative bacteria and Gram positive bacteria, viral, fungal or parasitic agents. In still another aspect the invention provides a polynucleotide expression pattern of a subject having a state of infection identified by the above method. Once identified, such polynucleotides will be useful in methods of diagnosis of a condition associated with the activity or presence of such infectious agents or signaling molecules.


Example 10 below demonstrates this aspect of the invention. Specifically, table 61 demonstrates that both MEK and the NADPH oxidase inhibitors can limit bacterial replication (infection of IFN-γ-primed macrophages by S. typhimurium triggers a MEK kinase). This is an example of how bacterial survival can be impacted by changing host cell signaling molecules.


In still another aspect of the invention, compounds are presented that inhibit stromal derived factor-I (SDF-1) induced chemotaxis of T cells. Compounds are also presented which decrease expression of SDF-1 receptor. Such compounds also may act as an antagonist or inhibitor of CXCR-4. In one aspect the invention provides a cationic peptide that is an antagonist of CXCR-4. In another aspect the invention provides a method of identifying a cationic peptide that is an antagonist of CXCR-4. The method includes contacting T cells with SDF-1 in the presence of absence of a test peptide and measuring chemotaxis. A decrease in chemotaxis in the presence of the test peptide is then indicative of a peptide that is an antagonist of CXCR-4. Such compounds and methods are useful in therapeutic applications in HIV patients. These types of compounds and the utility thereof is demonstrated, for example, in Example 11 (see also Tables 62, 63). In that example, cationic peptides are shown to inhibit cell migration and therefore antiviral activity.


In one embodiment, the invention provides an isolated cationic peptides having an amino acid sequence of the general formula (Formula A): X1X2X3IX4PX4IPX5X2X1 (SEQ ID NO: 4), wherein X1 is one or two of R, L or K, X2 is one of C, S or A, X3 is one of R or P, X4 is one of A or V and X5 is one of V or W. Examples of the peptides of the invention include, but are not limited to: LLCRIVPVIPWCK (SEQ ID NO: 5), LRCPIAPVIPVCKK (SEQ ID NO: 6), KSRIVPAIPVSLL (SEQ ID NO: 7), KKSPIAPAIPWSR (SEQ ID NO: 8), RRARIVPAIPVARR (SEQ ID NO: 9) and LSRIAPAIPWAKL (SEQ ID NO: 10).


In another embodiment, the invention provides an isolated linear cationic peptide having an amino acid sequence of the general formula (Formula B): X1LX2X3KX4X2X5X3PX3X1 (SEQ ID NO: 11), wherein X1 is one or two of D, E, S, T or N, X2 is one or two of P, G or D, X3 is one of G, A, V, L, I or Y, X4 is one of R, K or H and X5 is one of S, T, C, M or R. Examples of the peptides of the invention include, but are not limited to: DLPAKRGSAPGST (SEQ ID NO: 12), SELPGLKHPCVPGS (SEQ ID NO: 13), TTLGPVKRDSIPGE (SEQ ID NO: 14), SLPIKHDRLPATS (SEQ ID NO: 15), ELPLKRGRVPVE (SEQ ID NO: 16) and NLPDLKKPRVPATS (SEQ ID NO: 17).


In another embodiment, the invention provides an isolated linear cationic peptide having an amino acid sequence of the general formula (Formula C): X1X2X3X4WX4WX4X5K (SEQ ID NO: 18) (this formula includes CP12a and CP12d), wherein X1 is one to four chosen from A, P or R, X2 is one or two aromatic amino acids (F, Y and W), X3 is one of P or K, X4 is one, two or none chosen from A, P, Y or W and X5 is one to three chosen from R or P. Examples of the peptides of the invention include, but are not limited to: RPRYPWWPWWPYRPRK (SEQ ID NO: 19), RRAWWKAWWARRK (SEQ ID NO: 20), RAPYWPWAWARPRK (SEQ ID NO: 21), RPAWKYWWPWPWPRRK (SEQ ID NO: 22), RAAFKWAWAWWRRK (SEQ ID NO: 23) and RRRWKWAWPRRK (SEQ ID NO: 24).


In another embodiment, the invention provides an isolated hexadecameric cationic peptide having an amino acid sequence of the general formula (Formula D): X1X2X3X4X1VX3X4RGX4X3X4X1X3X1 (SEQ ID NO: 25) wherein X1 is one or two of R or K, X2 is a polar or charged amino acid (S, T, M, N, Q, D, E, K, R and H), X3 is C, S, M, D or A and X4 is F, I, V, M or R. Examples of the peptides of the invention include, but are not limited to: RRMCIKVCVRGVCRRKCRK (SEQ ID NO: 26), KRSCFKVSMRGVSRRRCK (SEQ ID NO: 27), KKDAIKKVDIRGMDMRRAR (SEQ ID NO: 28), RKMVKVDVRGIMIRKDRR (SEQ ID NO: 29), KQCVKVAMRGMALRRCK (SEQ ID NO: 30) and RREAIRRVAMRGRDMKRMRR (SEQ ID NO: 31).


In still another embodiment, the invention provides an isolated hexadecameric cationic peptide having an amino acid sequence of the general formula (Formula E): X1X2X3X4X1VX5X4RGX4X5X4X1X3X1 (SEQ ID NO: 32), wherein X1 is one or two of R or K, X2 is a polar or charged amino acid (S, T, M, N, Q, D, E, K, R and H), X3 is one of C, S, M, D or A, X4 is one of F, I, V, M or R and X5 is one of A, I, S, M, D or R. Examples of the peptides of the invention include, but are not limited to: RTCVKRVAMRGIIRKRCR (SEQ ID NO: 33), KKQMMKRVDVRGISVKRKR (SEQ ID NO: 34), KESIKVIIRGMMVRMKK (SEQ ID NO: 35), RRDCRRVMVRGIDIKAK (SEQ ID NO: 36), KRTAIKKVSRRGMSVKARR (SEQ ID NO: 37) and RHClRRVSMRGIIMRRCK (SEQ ID NO: 38).


In another embodiment, the invention provides an isolated longer cationic peptide having an amino acid sequence of the general formula (Formula F): KX1KX2FX2KMLMX2ALKKX3 (SEQ ID NO: 39), wherein X1 is a polar amino acid (C, S, T, M, N and Q); X2 is one of A, L, S or K and X3 is 1-17 amino acids chosen from G, A, V, L, I, P, F, S, T, K and H. Examples of the peptides of the invention include, but are not limited to: KCKLFKKMLMLALKKVLTTGLPALKLTK (SEQ ID NO: 40), KSKSFLKMLMKALKKVLTTGLPALIS (SEQ ID NO: 41), KTKKFAKMLMMALKKVVSTAKPLAILS (SEQ ID NO: 42), KMKSFAKMLMLALKKVLKVLTTALTLKAGLPS (SEQ ID NO: 43), KNKAFAKMLMKALKKVTTAAKPLTG (SEQ ID NO: 44) and KQKLFAKMLMSALKKKTLVTTPLAGK (SEQ ID NO: 45).


In yet another embodiment, the invention provides an isolated longer cationic peptide having an amino acid sequence of the general formula (Formula G): KWKX2X1X1X2X2X1X2X2X1X1X2X21FHTALKPISS (SEQ ID NO: 46), wherein X1 is a hydrophobic amino acid and X2 is a hydrophilic amino acid. Examples of the peptides of the invention include, but are not limited to: KWKSFLRTFKSPVRTIFHTALKPISS (SEQ ID NO: 47), KWKSYAHTIMSPVRLIFHTALKPISS (SEQ ID NO: 48), KWKRGAHRFMKFLSTIFHTALKPISS (SEQ ID NO: 49), KWKKWAHSPRKVLTRIFHTALKPISS (SEQ ID NO: 50), KWKSLVMMFKKPARRIFHTALKPISS (SEQ ID NO: 51) and KWKHALMKAHMLWHMIFHTALKPISS (SEQ ID NO: 52).


In still another embodiment, the invention provides an isolated cationic peptide having an amino acid sequence of the formula: KWKSFLRTFKSPVRTVFHTALKPISS (SEQ ID NO: 53) or KWKSYAHTIMSPVRLVFHTALKPISS (SEQ ID NO: 54).


The term “isolated” as used herein refers to a peptide that is substantially free of other proteins, lipids, and nucleic acids (e.g., cellular components with which an in vivo-produced peptide would naturally be associated). Preferably, the peptide is at least 70%, 80%, or most preferably 90% pure by weight.


The invention also includes analogs, derivatives, conservative variations, and cationic peptide variants of the enumerated polypeptides, provided that the analog, derivative, conservative variation, or variant has a detectable activity in which it enhances innate immunity or has anti-inflammatory activity. It is not necessary that the analog, derivative, variation, or variant have activity identical to the activity of the peptide from which the analog, derivative, conservative variation, or variant is derived.


A cationic peptide “variant” is an peptide that is an altered form of a referenced cationic peptide. For example, the term “variant” includes a cationic peptide in which at least one amino acid of a reference peptide is substituted in an expression library. The term “reference” peptide means any of the cationic peptides of the invention (e.g., as defined in the above formulas), from which a variant, derivative, analog, or conservative variation is derived. Included within the term “derivative” is a hybrid peptide that includes at least a portion of each of two cationic peptides (e.g., 30-80% of each of two cationic peptides). Also included are peptides in which one or more amino acids are deleted from the sequence of a peptide enumerated herein, provided that the derivative has activity in which it enhances innate immunity or has anti-inflammatory activity. This can lead to the development of a smaller active molecule which would also have utility. For example, amino or carboxy terminal amino acids which may not be required for enhancing innate immunity or anti-inflammatory activity of a peptide can be removed. Likewise, additional derivatives can be produced by adding one or a few (e.g., less than 5) amino acids to a cationic peptide without completely inhibiting the activity of the peptide. In addition, C-terminal derivatives, e.g., C-terminal methyl esters, and N-terminal derivatives can be produced and are encompassed by the invention. Peptides of the invention include any analog, homolog, mutant, isomer or derivative of the peptides disclosed in the present invention, so long as the bioactivity as described herein remains. Also included is the reverse sequence of a peptide encompassed by the general formulas set forth above. Additionally, an amino acid of “D” configuration may be substituted with an amino acid of “L” configuration and vice versa. Alternatively the peptide may be cyclized chemically or by the addition of two or more cysteine residues within the sequence and oxidation to form disulphide bonds.


The invention also includes peptides that are conservative variations of those peptides exemplified herein. The term “conservative variation” as used herein denotes a polypeptide in which at least one amino acid is replaced by another, biologically similar residue. Examples of conservative variations include the substitution of one hydrophobic residue, such as isoleucine, valine, leucine, alanine, cysteine, glycine, phenylalanine, proline, tryptophan, tyrosine, norleucine or methionine for another, or the substitution of one polar residue for another, such as the substitution of arginine for lysine, glutamic for aspartic acid, or glutamine for asparagine, and the like. Neutral hydrophilic amino acids that can be substituted for one another include asparagine, glutamine, serine and threonine. The term “conservative variation” also encompasses a peptide having a substituted amino acid in place of an unsubstituted parent amino acid. Such substituted amino acids may include amino acids that have been methylated or amidated. Other substitutions will be known to those of skill in the art. In one aspect, antibodies raised to a substituted polypeptide will also specifically bind the unsubstituted polypeptide.


Peptides of the invention can be synthesized by commonly used methods such as those that include t-BOC or FMOC protection of alpha-amino groups. Both methods involve stepwise synthesis in which a single amino acid is added at each step starting from the C-terminus of the peptide (See, Coligan, et al., Current Protocols in Immunology, Wiley Interscience, 1991, Unit 9). Peptides of the invention can also be synthesized by the well known solid phase peptide synthesis methods such as those described by Merrifield, J. Am. Chem. Soc., 85:2149, 1962) and Stewart and Young, Solid Phase Peptides Synthesis, Freeman, San Francisco, 1969, pp.27-62) using a copoly(styrene-divinylbenzene) containing 0.1-1.0 mMol amines/g polymer. On completion of chemical synthesis, the peptides can be deprotected and cleaved from the polymer by treatment with liquid HF-10% anisole for about ¼-1 hours at 0° C. After evaporation of the reagents, the peptides are extracted from the polymer with a 1% acetic acid solution, which is then lyophilized to yield the crude material. The peptides can be purified by such techniques as gel filtration on Sephadex G-15 using 5% acetic acid as a solvent. Lyophilization of appropriate fractions of the column eluate yield homogeneous peptide, which can then be characterized by standard techniques such as amino acid analysis, thin layer chromatography, high performance liquid chromatography, ultraviolet absorption spectroscopy, molar rotation, or measuring solubility. If desired, the peptides can be quantitated by the solid phase Edman degradation.


The invention also includes isolated nucleic acids (e.g., DNA, cDNA, or RNA) encoding the peptides of the invention. Included are nucleic acids that encode analogs, mutants, conservative variations, and variants of the peptides described herein. The term “isolated” as used herein refers to a nucleic acid that is substantially free of proteins, lipids, and other nucleic acids with which an in vivo-produced nucleic acids naturally associated. Preferably, the nucleic acid is at least 70%, 80%, or preferably 90% pure by weight, and conventional methods for synthesizing nucleic acids in vitro can be used in lieu of in vivo methods. As used herein, “nucleic acid” refers to a polymer of deoxyribo-nucleotides or ribonucleotides, in the form of a separate fragment or as a component of a larger genetic construct (e.g., by operably linking a promoter to a nucleic acid encoding a peptide of the invention). Numerous genetic constructs (e.g., plasmids and other expression vectors) are known in the art and can be used to produce the peptides of the invention in cell-free systems or prokaryotic or eukaryotic (e.g., yeast, insect, or mammalian) cells. By taking into account the degeneracy of the genetic code, one of ordinary skill in the art can readily synthesize nucleic acids encoding the polypeptides of the invention. The nucleic acids of the invention can readily be used in conventional molecular biology methods to produce the peptides of the invention.


DNA encoding the cationic peptides of the invention can be inserted into an “expression vector.” The term “expression vector” refers to a genetic construct such as a plasmid, virus or other vehicle known in the art that can be engineered to contain a nucleic acid encoding a polypeptide of the invention. Such expression vectors are preferably plasmids that contain a promoter sequence that facilitates transcription of the inserted genetic sequence in a host cell. The expression vector typically contains an origin of replication, and a promoter, as well as polynucleotides that allow phenotypic selection of the transformed cells (e.g., an antibiotic resistance polynucleotide). Various promoters, including inducible and constitutive promoters, can be utilized in the invention. Typically, the expression vector contains a replicon site and control sequences that are derived from a species compatible with the host cell.


Transformation or transfection of a recipient with a nucleic acid of the invention can be carried out using conventional techniques well known to those skilled in the art. For example, where the host cell is E. coli, competent cells that are capable of DNA uptake can be prepared using the CaCl2, MgCl2 or RbCl methods known in the art. Alternatively, physical means, such as electroporation or microinjection can be used. Electroporation allows transfer of a nucleic acid into a cell by high voltage electric impulse. Additionally, nucleic acids can be introduced into host cells by protoplast fusion, using methods well known in the art. Suitable methods for transforming eukaryotic cells, such as electroporation and lipofection, also are known.


“Host cells” or “Recipient cells” encompassed by of the invention are any cells in which the nucleic acids of the invention can be used to express the polypeptides of the invention. The term also includes any progeny of a recipient or host cell. Preferred recipient or host cells of the invention include E. coli, S. aureus and P. aeruginosa, although other Gram-negative and Gram-positive bacterial, fungal and mammalian cells and organisms known in the art can be utilized as long as the expression vectors contain an origin of replication to permit expression in the host.


The cationic peptide polynucleotide sequence used according to the method of the invention can be isolated from an organism or synthesized in the laboratory. Specific DNA sequences encoding the cationic peptide of interest can be obtained by: 1) isolation of a double-stranded DNA sequence from the genomic DNA; 2) chemical manufacture of a DNA sequence to provide the necessary codons for the cationic peptide of interest; and 3) in vitro synthesis of a double-stranded DNA sequence by reverse transcription of mRNA isolated from a donor cell. In the latter case, a double-stranded DNA complement of mRNA is eventually formed which is generally referred to as cDNA.


The synthesis of DNA sequences is frequently the method of choice when the entire sequence of amino acid residues of the desired peptide product is known. In the present invention, the synthesis of a DNA sequence has the advantage of allowing the incorporation of codons which are more likely to be recognized by a bacterial host, thereby permitting high level expression without difficulties in translation. In addition, virtually any peptide can be synthesized, including those encoding natural cationic peptides, variants of the same, or synthetic peptides.


When the entire sequence of the desired peptide is not known, the direct synthesis of DNA sequences is not possible and the method of choice is the formation of cDNA sequences. Among the standard procedures for isolating cDNA sequences of interest is the formation of plasmid or phage containing cDNA libraries which are derived from reverse transcription of mRNA which is abundant in donor cells that have a high level of genetic expression. When used in combination with polymerase chain reaction technology, even rare expression products can be cloned. In those cases where significant portions of the amino acid sequence of the cationic peptide are known, the production of labeled single or double-stranded DNA or RNA probe sequences duplicating a sequence putatively present in the target cDNA may be employed in DNA/DNA hybridization procedures which are carried out on cloned copies of the cDNA which have been denatured into a single stranded form (Jay, et al., Nuc. Acid Res., 11:2325, 1983).


The peptide of the invention can be administered parenterally by injection or by gradual infusion over time. Preferably the peptide is administered in a therapeutically effective amount to enhance or to stimulate an innate immune response. Innate immunity has been described herein, however examples of indicators of stimulation of innate immunity include but are not limited to monocyte activation, proliferation, differentiation or MAP kinase pathway activation.


The peptide can be administered intravenously, intraperitoneally, intramuscularly, subcutaneously, intracavity, or transdermally. Preferred methods for delivery of the peptide include orally, by encapsulation in microspheres or proteinoids, by aerosol delivery to the lungs, or transdermally by iontophoresis or transdermal electroporation. Other methods of administration will be known to those skilled in the art.


Preparations for parenteral administration of a peptide of the invention include sterile aqueous or non-aqueous solutions, suspensions, and emulsions. Examples of non-aqueous solvents are propylene glycol, polyethylene glycol, vegetable oils such as olive oil, and injectable organic esters such as ethyl oleate. Aqueous carriers include water, alcoholic/aqueous solutions, emulsions or suspensions, including saline and buffered media Parenteral vehicles include sodium chloride solution, Ringer's dextrose, dextrose and sodium chloride, lactated Ringer's, or fixed oils. Intravenous vehicles include fluid and nutrient replenishers, electrolyte replenishers (such as those based on Ringer's dextrose), and the like. Preservatives and other additives may also be present such as, for example, antimicrobials, anti-oxidants, chelating agents, and inert gases and the like.


In one embodiment, the invention provides a method for synergistic therapy. For example, peptides as described herein can be used in synergistic combination with sub-inhibitory concentrations of antibiotics. Examples of particular classes of antibiotics useful for synergistic therapy with the peptides of the invention include aminoglycosides (e.g., tobramycin), penicillins (e.g., piperacillin), cephalosporins (e.g., ceftazidime), fluoroquinolones (e.g., ciprofloxacin), carbapenems (e.g., imipenem), tetracyclines and macrolides (e.g., erythromycin and clarithromycin). Further to the antibiotics listed above, typical antibiotics include aminoglycosides (amikacin, gentamicin, kanamycin, netilmicin, tobramycin, streptomycin, azithromycin, clarithromycin, erythromycin, erythromycin estolate/ethylsuccinate/gluceptate/lactobionate/stearate), beta-lactams such as penicillins (e.g., penicillin G, penicillin V, methicillin, nafcillin, oxacillin, cloxacillin, dicloxacillin, ampicillin, amoxicillin, ticarcillin, carbenicillin, mezlocillin, azlocillin and piperacillin), or cephalosporins (e.g., cephalothin, cefazolin, cefaclor, cefamandole, cefoxitin, cefuroxime, cefonicid, ceftmetazole, cefotetan, cefprozil, loracarbef, cefetamet, cefoperazone, cefotaxime, ceftizoxime, ceftriaxone, ceftazidime, cefepime, cefixime, cefpodoxime, and cefsulodin). Other classes of antibiotics include carbapenems (e.g., imipenem), monobactams (e.g., aztreonam), quinolones (e.g., fleroxacin, nalidixic acid, norfloxacin, ciprofloxacin, ofloxacin, enoxacin, lomefloxacin and cinoxacin), tetracyclines (e.g., doxycycline, minocycline, tetracycline), and glycopeptides (e.g., vancomycin, teicoplanin), for example. Other antibiotics include chloramphenicol, clindamycin, trimethoprim, sulfamethoxazole, nitrofurantoin, rifampin, mupirocin and the cationic peptides.


The efficacy of peptides was evaluated therapeutically alone and in combination with sub-optimal concentrations of antibiotics in models of infection. S. aureus is an important Gram positive pathogen and a leading cause of antibiotic resistant infections. Briefly, peptides were tested for therapeutic efficacy in the S. aureus infection model by injecting them alone and in combination with sub-optimal doses of antibiotics 6 hours after the onset of infection. This would simulate the circumstances of antibiotic resistance developing during an infection, such that the MIC of the resistant bacterium was too high to permit successful therapy (i.e the antibiotic dose applied was sub-optimal). It was demonstrated that the combination of antibiotic and peptide resulted in improved efficacy and suggests the potential for combination therapy (see Example 12).


The invention will now be described in greater detail by reference to the following non-limiting examples. While the invention has been described in detail with reference to certain preferred embodiments thereof, it will be understood that modifications and variations are within the spirit and scope of that which is described and claimed.


EXAMPLE 1
Anti-Sepsis/Anti-Inflammatory Activity

Polynucleotide arrays were utilized to determine the effect of cationic peptides on the transcriptional response of epithelial cells. The A549 human epithelial cell line was maintained in DMEM (Gibco) supplemented with 10% fetal bovine serum (FBS, Medicorp). The A549 cells were plated in 100 mm tissue culture dishes at 2.5×106 cells/dish, cultured overnight and then incubated with 100 ng/ml E. coli O111:B4 LPS (Sigma), without (control) or with 50 μg/ml peptide or medium alone for 4 h. After stimulation, the cells were washed once with diethyl pyrocarbonate-treated phosphate buffered saline (PBS), and detached from the dish using a cell scraper. Total RNA was isolated using RNAqueous (Ambion, Austin, Tex.). The RNA pellet was resuspended in RNase-free water containing Superase-In (RNase inhibitor; Ambion). DNA contamination was removed with DNA-free kit, Ambion). The quality of the RNA was assessed by gel electrophoresis on a 1% agarose gel.


The polynucleotide arrays used were the Human Operon arrays (identification number for the genome is PRHU04-S1), which consist of about 14,000 human oligos spotted in duplicate. Probes were prepared from 10 μg of total RNA and labeled with Cy3 or Cy5 labeled dUTP. The probes were purified and hybridized to printed glass slides overnight at 42° C. and washed. After washing, the image was captured using a Perkin Elmer array scanner. The image processing software (Imapolynucleotide 5.0, Marina Del Rey, Calif.) determines the spot mean intensity, median intensities, and background intensities. A “homemade” program was used to remove background. The program calculates the bottom 10% intensity for each subgrid and subtracts this for each grid. Analysis was performed with Genespring software (Redwood City, Calif.). The intensities for each spot were normalized by taking the median spot intensity value from the population of spot values within a slide and comparing this value to the values of all slides in the experiment. The relative changes seen with cells treated with peptide compared to control cells can be found in Tables 1 and 2. These tables 2 reflect only those polynucleotides that demonstrated significant changes in expression of the 14,000 polynucleotides that were tested for altered expression. The data indicate that the peptides have a widespread ability to reduce the expression of polynucleotides that were induced by LPS.


In Table 1, the peptide, SEQ ID NO: 27 is shown to potently reduce the expression of many of the polynucleotides up-regulated by E. coli O111:B4 LPS as studied by polynucleotide microarrays. Peptide (50 μg/ml) and LPS (0.1 μg/ml) or LPS alone was incubated with the A549 cells for 4 h and the RNA was isolated. Five μg total RNA was used to make Cy3/Cy5 labeled cDNA probes and hybridized onto Human Operon arrays (PRHU04). The intensity of unstimulated cells is shown in the third column of Table 1. The “Ratio: LPS/control” column refers to the intensity of polynucleotide expression in LPS simulated cells divided by in the intensity of unstimulated cells. The “Ratio: LPS+ID 27/control” column refers to the intensity of polynucleotide expression in cells stimulated with LPS and peptide divided by unstimulated cells.









TABLE 1







Reduction, by peptide SEQ ID 27, of A549 human epithelial cell


polynucleotide expression up-regulated by E. coli O111:B4 LPS











Accession
Polynucleotide
Control: Media
Ratio:
Ratio: LPS + ID


Numbera
Gene Function
only Intensity
LPS/control
27/control














AL031983
Unknown
0.032
302.8
5.1


L04510
ADP-
0.655
213.6
1.4



ribosylation



factor


D87451
ring finger
3.896
183.7
2.1



protein 10


AK000869
hypothetical
0.138
120.1
2.3



protein


U78166
Ric-like
0.051
91.7
0.2



expressed in



neurons


AJ001403
mucin 5
0.203
53.4
15.9



subtype B



tracheobronchial


AB040057
serine/threonine
0.95
44.3
15.8



protein



kinase MASK


Z99756
Unknown
0.141
35.9
14.0


L42243
interferon
0.163
27.6
5.2



receptor 2


NM_016216
RNA lariat
6.151
22.3
10.9



debranching



enzyme


AK001589
hypothetical
0.646
19.2
1.3



protein


AL137376
Unknown
1.881
17.3
0.6


AB007856
FEM-1-like
2.627
15.7
0.6



death receptor



binding protein


AB007854
growth arrest-
0.845
14.8
2.2



specific 7


AK000353
cytosolic
0.453
13.5
1.0



ovarian



carcinoma



antigen 1


D14539
myeloid/lymphoid
2.033
11.6
3.1



or mixed-



lineage



leukemia



translocated to 1


X76785
integration site
0.728
11.6
1.9



for Epstein-Barr



virus


M54915
pim-1
1.404
11.4
0.6



oncogene


NM_006092
caspase
0.369
11.0
0.5



recruitment



domain 4


J03925
integrin_alpha M
0.272
9.9
4.2


NM_001663
ADP-
0.439
9.7
1.7



ribosylation



factor 6


M23379
RAS p21
0.567
9.3
2.8



protein



activator


K02581
thymidine
3.099
8.6
3.5



kinase 1



soluble


U94831
transmembrane
3.265
7.1
1.5



9 superfamily



member 1


X70394
zinc finger
1.463
6.9
1.7



protein 146


AL137614
hypothetical
0.705
6.8
1.0



protein


U43083
guanine
0.841
6.6
1.6



nucleotide



binding protein


AL137648
DKFZp434J181
1.276
6.5
0.8



3 protein


AF085692
ATP-binding
3.175
6.5
2.4



cassette sub-



family C



(CFTR/MRP)



member 3


AK001239
hypothetical
2.204
6.4
1.3



protein



FLJ10377


NM_001679
ATPase
2.402
6.3
0.9



Na+/K+



transporting



beta 3



polypeptide


L24804
unactive
3.403
6.1
1.1



progesterone



receptor


U15932
dual specificity
0.854
6.1
2.1



phosphatase 5


M36067
ligase I DNA
1.354
6.1
2.2



ATP-dependent


AL161951
Unknown
0.728
5.8
1.9


M59820
colony
0.38
5.7
2.0



stimulating



factor 3



receptor


AL050290
spermidine/
2.724
5.6
1.4



spermine N1-



acetyltransferase


NM_002291
laminin_beta 1
1.278
5.6
1.8


X06614
retinoic acid
1.924
5.5
0.8



receptor_alpha


AB007896
putative L-type
0.94
5.3
1.8



neutral amino



acid transporter


AL050333
DKFZP564B11
1.272
5.3
0.6



6 protein


AK001093
hypothetical
1.729
5.3
2.0



protein


NM_016406
hypothetical
1.314
5.2
1.2



protein


M86546
pre-B-cell
1.113
5.2
2.2



leukemia tran-



scription factor 1


X56777
zona pellucida
1.414
5.0
1.4



glycoprotein 3A


NM_013400
replication
1.241
4.9
2.0



initiation region



protein


NM_002309
leukemia
1.286
4.8
1.9



inhibitory factor


NM_001940
dentatorubral-
2.034
4.7
1.2



pallidoluysian



atrophy


U91316
cytosolic acyl
2.043
4.7
1.4



coenzyme A



thioester



hydrolase


X76104
death-
1.118
4.6
1.8



associated



protein



kinase 1


AF131838
Unknown
1.879
4.6
1.4


AL050348
Unknown
8.502
4.4
1.7


D42085
KIAA0095 gene
1.323
4.4
1.2



product


X92896
Unknown
1.675
4.3
1.5


U26648
syntaxin 5A
1.59
4.3
1.4


X85750
monocyte to
1.01
4.3
1.1



macrophage



differentiation-



associated


D14043
CD 164
1.683
4.2
1.0



antigen



sialomucin


J04513
fibroblast
1.281
4.0
0.9



growth factor 2


U19796
melanoma-
1.618
4.0
0.6



associated



antigen


AK000087
hypothetical
1.459
3.9
1.0



protein


AK001569
hypothetical
1.508
3.9
1.2



protein


AF189009
ubiquilin 2
1.448
3.8
1.3


U60205
sterol-C4-
1.569
3.7
0.8



methyl oxidase-



like


AK000562
hypothetical
1.166
3.7
0.6



protein


AL096739
Unknown
3.66
3.7
0.5


AK000366
hypothetical
15.192
3.5
1.0



protein


NM_006325
RAN member
1.242
3.5
1.4



RAS oncogene



family


X51688
cyclin A2
1.772
3.3
1.0


U34252
aldehyde
1.264
3.3
1.2



dehydrogenase 9


NM_013241
FH1/FH2
1.264
3.3
0.6



domain-



containing



protein


AF112219
esterase
1.839
3.3
1.1



D/formylglutathione



hydrolase


NM_016237
anaphase-
2.71
3.2
0.9



promoting



complex



subunit 5


AB014569
KIAA0669 gene
2.762
3.2
0.2



product


AF151047
hypothetical
3.062
3.1
1.0



protein


X92972
protein
2.615
3.1
1.1



phosphatase 6



catalytic



subunit


AF035309
proteasome
5.628
3.1
1.3



26S subunit



ATPase 5


U52960
SRB7 homolog
1.391
3.1
0.8


J04058
electron-
3.265
3.1
1.2



transfer-



flavoprotein



alpha



polypeptide


M57230
interleukin 6 signal
0.793
3.1
1.0



transducer


U78027
galactosidase
3.519
3.1
1.1



alpha


AK000264
Unknown
2.533
3.0
0.6


X80692
mitogen-
2.463
2.9
1.3



activated



protein kinase 6


L25931
lamin B
2.186
2.7
0.7



receptor


X13334
CD14 antigen
0.393
2.5
1.1


M32315
tumor necrosis
0.639
2.4
0.4



factor receptor



superfamily



member 1B


NM_004862
LPS-induced
6.077
2.3
1.1



TNF-alpha



factor


AL050337
interferon
2.064
2.1
1.0



gamma



receptor 1






aAll Accession Numbers in Table 1 through Table 64 refer to GenBank Accession Numbers.







In Table 2, the cationic peptides at a concentration of 50 μg/ml were shown to potently reduce the expression of many of the polynucleotides up-regulated by 100 ng/ml E. coli O111:B4 LPS as studied by polynucleotide microarrays. Peptide and LPS or LPS alone was incubated with the A549 cells for 4 h and the RNA was isolated. 5 μg total RNA was used to make Cy3/Cy5 labeled cDNA probes and hybridized onto Human Operon arrays (PRHU04). The intensity of unstimulated cells is shown in the third column of Table 2. The “Ratio: LPS/control” column refers to the intensity of polynucleotide expression in LPS-simulated cells divided by in the intensity of unstimulated cells. The other columns refer to the intensity of polynucleotide expression in cells stimulated with LPS and peptide divided by unstimulated cells.









TABLE 2







Human A549 Epithelial Cell Polynucleotide Expression up-regulated


by E.coli O111:B4 LPS and reduced by Cationic Peptides















Control:

Ratio:
Ratio:
Ratio:


Accession

Media only
Ratio:
LPS + ID 27/
LPS + ID 16/
LPS + ID 22/


Number
Gene
Intensity
LPS/control
control
control
control
















AL031983
Unknown
0.03
302.8
5.06
6.91
0.31


L04510
ADP-
0.66
213.6
1.4
2.44
3.79



ribosylation



factor


D87451
ring finger
3.90
183.7
2.1
3.68
4.28



protein


AK000869
hypothetical
0.14
120.1
2.34
2.57
2.58



protein


U78166
Ric like
0.05
91.7
0.20
16.88
21.37


X03066
MHC class II
0.06
36.5
4.90
12.13
0.98



DO beta


AK001904
hypothetical
0.03
32.8
5.93
0.37
0.37



protein


AB037722
Unknown
0.03
21.4
0.30
0.30
2.36


AK001589
hypothetical
0.65
19.2
1.26
0.02
0.43



protein


AL137376
Unknown
1.88
17.3
0.64
1.30
1.35


L19185
thioredoxin-
0.06
16.3
0.18
2.15
0.18



dependent peroxide



reductase 1


J05068
transcobalaminl
0.04
15.9
1.78
4.34
0.83


AB007856
FEM-1-like
2.63
15.7
0.62
3.38
0.96



death receptor



binding protein


AK000353
cytosolic
0.45
13.5
1.02
1.73
2.33



ovarian



carcinoma ag 1


X16940
smooth muscle
0.21
11.8
3.24
0.05
2.26



enteric actin γ2


M54915
pim-1 oncogene
1.40
11.4
0.63
1.25
1.83


AL122111
hypothetical
0.37
10.9
0.21
1.35
0.03



protein


M95678
phospholipase
0.22
7.2
2.38
0.05
1.33



C beta 2


AK001239
hypothetical
2.20
6.4
1.27
1.89
2.25



protein


AC004849
Unknown
0.14
6.3
0.07
2.70
0.07


X06614
retinoic acid
1.92
5.5
0.77
1.43
1.03



receptor_alpha


AB007896
putative L-type
0.94
5.3
1.82
2.15
2.41



neutral amino



acid transporter


AB010894
BAl1-associated
0.69
5.0
1.38
1.03
1.80



protein


U52522
partner of RAC1
1.98
2.9
1.35
0.48
1.38


AK001440
hypothetical
1.02
2.7
0.43
1.20
0.01



protein


NM_001148
ankyrin 2
0.26
2.5
0.82
0.04
0.66



neuronal


X07173
inter-alpha
0.33
2.2
0.44
0.03
0.51



inhibitor H2


AF095687
brain and
0.39
2.1
0.48
0.03
0.98



nasopharyngeal



carcinoma



susceptibility



protein


NM_016382
NK cell
0.27
2.1
0.81
0.59
0.04



activation



inducing ligand



NAIL


AB023198
KIAA0981
0.39
2.0
0.43
0.81
0.92



protein









EXAMPLE 2
Neutralization of the Stimulation of Immune Cells

The ability of compounds to neutralize the stimulation of immune cells by both Gram-negative and Gram-positive bacterial products was tested. Bacterial products stimulate cells of the immune system to produce inflammatory cytokines and when unchecked this can lead to sepsis. Initial experiments utilized the murine macrophage cell line RAW 264.7, which was obtained from the American Type Culture Collection, (Manassas, Va.), the human epithelial cell line, A549, and primary macrophages derived from the bone marrow of BALB/c mice (Charles River Laboratories, Wilmington, Mass.). The cells from mouse bone marrow were cultured in 150-mm plates in Dulbecco's modified Eagle medium (DMEM; Life Technologies, Burlington, ON) supplemented with 20% FBS (Sigma Chemical Co, St. Louis, Mo.) and 20% L cell-conditioned medium as a source of M-CSF. Once macrophages were 60-80% confluent, they were deprived of L cell-conditioned medium for 14-16 h to render the cells quiescent and then were subjected to treatments with 100 ng/ml LPS or 100 ng/ml LPS+20 μg/ml peptide for 24 hours. The release of cytokines into the culture supernatant was determined by ELISA (R&D Systems, Minneapolis, Minn.). The cell lines, RAW 264.7 and A549, were maintained in DMEM supplemented with 10% fetal calf serum. RAW 264.7 cells were seeded in 24 well plates at a density of 106 cells per well in DMEM and A549 cells were seeded in 24 well plates at a density of 1 cells per well in DMEM and both were incubated at 37° C. in 5% CO2 overnight. DMEM was aspirated from cells grown overnight and replaced with fresh medium. In some experiments, blood from volunteer human donors was collected (according to procedures accepted by UBC Clinical Research Ethics Board, certificate C00-0537) by venipuncture into tubes (Becton Dickinson, Franklin Lakes, N.J.) containing 14.3 USP units heparin/ml blood. The blood was mixed with LPS with or without peptide in polypropylene tubes at 37° C. for 6 h. The samples were centrifuged for 5 min at 2000×g, the plasma was collected and then stored at −20° C. until being analyzed for IL-8 by ELISA (R&D Systems). In the experiments with cells, LPS or other bacterial products were incubated with the cells for 6-24 hr at 37° C. in 5% CO2. S. typhimurium LPS and E. coli 0111:B4 LPS were purchased from Sigma. Lipoteichoic acid (LTA) from S. aureus (Sigma) was resuspended in endotoxin free water (Sigma). The Limulus amoebocyte lysate assay (Sigma) was performed on LTA preparations to confirm that lots were not significantly contaminated by endotoxin. Endotoxin contamination was less than 1 ng/ml, a concentration that did not cause significant cytokine production in the RAW 264.7 cells. Non-capped lipoarabinomannan (AraLAM) was a gift from Dr. John T. Belisle of Colorado State University. The AraLAM from Mycobacterium was filter sterilized and the endotoxin contamination was found to be 3.75 ng per 1.0 mg of LAM as determined by Limulus Amebocyte assay. At the same time as LPS addition (or later where specifically described), cationic peptides were added at a range of concentrations. The supernatants were removed and tested for cytokine production by ELISA (R&D Systems). All assays were performed at least three times with similar results. To confirm the anti-sepsis activity in vivo, sepsis was induced by intraperitoneal injection of 2 or 3 μg of E. coli O111:B4 LPS in phosphate-buffered saline (PBS; pH 7.2) into galactosamine-sensitized 8- to 10-week-old female CD-1 or BALB/c mice. In experiments involving peptides, 200 μg in 100 μl of sterile water was injected at separate intraperitoneal sites within 10 min of LPS injection. In other experiments, CD-1 mice were injected with 400 μg E. coli O111:B4 LPS and 10 min later peptide (200 μg) was introduced by intraperitoneal injection. Survival was monitored for 48 hours post injection.


Hyperproduction of TNF-α has been classically linked to development of sepsis. The three types of LPS, LTA or AraLAM used in this example represented products released by both Gram-negative and Gram-positive bacteria. Peptide, SEQ ID NO: 1, was able to significantly reduce TNF-α production stimulated by S. typhimurium, B. cepacia, and E. coli O111:B4 LPS, with the former being affected to a somewhat lesser extent (Table 3). At concentrations as low as 1 μg/ml of peptide (0.25 nM) substantial reduction of TNF-α production was observed in the latter two cases. A different peptide, SEQ ID NO: 3 did not reduce LPS-induced production of TNF-α in RAW macrophage cells, demonstrating that this is not a uniform and predictable property of cationic peptides. Representative peptides from each Formula were also tested for their ability to affect TNF-α production stimulated by E. coli O111:B4 LPS (Table 4). The peptides had a varied ability to reduce TNF-α production although many of them lowered TNF-α by at least 60%.


At certain concentrations peptides SEQ ID NO: 1 and SEQ ID NO: 2, could also reduce the ability of bacterial products to stimulate the production of IL-8 by an epithelial cell line. LPS is a known potent stimulus of IL-8 production by epithelial cells. Peptides, at low concentrations (1-20 μg/ml), neutralized the IL-8 induction responses of epithelial cells to LPS (Table 5-7). Peptide SEQ ID 2 also inhibited LPS-induced production of IL-8 in whole human blood (Table 4). Conversely, high concentrations of peptide SEQ ID NO: 1 (50 to 100 μg/ml) actually resulted in increased levels of IL-8 (Table 5). This suggests that the peptides have different effects at different concentrations.


The effect of peptides on inflammatory stimuli was also demonstrated in primary murine cells, in that peptide SEQ ID NO: 1 significantly reduced TNF-α production (>90%) by bone marrow-derived macrophages from BALB/c mice that had been stimulated with 100 ng/ml E. coli 0111:B4 LPS (Table 8). These experiments were performed in the presence of serum, which contains LPS-binding protein (LBP), a protein that can mediate the rapid binding of LPS to CD14. Delayed addition of SEQ ID NO: 1 to the supernatants of macrophages one hour after stimulation with 100 ng/ml E. coli LPS still resulted in substantial reduction (70%) of TNF-α production (Table 9).


Consistent with the ability of SEQ ID NO: 1 to prevent LPS-induced production of TNF-α in vitro, certain peptides also protected mice against lethal shock induced by high concentrations of LPS. In some experiments, CD-1 mice were sensitized to LPS with a prior injection of galactosamine. Galactosamine-sensitized mice that were injected with 3 μg of E. coli 0111:B4 LPS were all killed within 4-6 hours. When 200 μg of SEQ ID NO: 1 was injected 15 min after the LPS, 50% of the mice survived (Table 10). In other experiments when a higher concentration of LPS was injected into BALB/c mice with no D-galactosamine, peptide protected 100% compared to the control group in which there was no survival (Table 13). Selected other peptides were also found to be protective in these models (Tables 11, 12).


Cationic peptides were also able to lower the stimulation of macrophages by Gram-positive bacterial products such as Mycobacterium non-capped lipoarabinomannan (AraLAM) and S. aureus LTA. For example, SEQ ID NO: 1 inhibited induction of TNF-α in RAW 264.7 cells by the Gram-positive bacterial products, LTA (Table 14) and to a lesser extent AraLAM (Table 15). Another peptide, SEQ ID NO: 2, was also found to reduce LTA-induced TNF-α production by RAW 264.7 cells. At a concentration of 1 μg/ml SEQ ID NO: 1 was able to substantially reduce (>75%) the induction of TNF-α production by 1 μg/ml S. aureus LTA. At 20 μg/ml SEQ ID NO: 1, there was >60% inhibition of AraLAM induced TNF-α. Polymyxin B (PMB) was included as a control to demonstrate that contaminating endotoxin was not a significant factor in the inhibition by SEQ ID NO: 1 of AraLAM induced TNF-α. These results demonstrate that cationic peptides can reduce the pro-inflammatory cytokine response of the immune system to bacterial products.









TABLE 3







Reduction by SEQ ID 1 of LPS induced TNF-α production


in RAW 264.7 cells. RAW 264.7 mouse macrophage cells were


stimulated with 100 ng/ml S. typhimurium LPS, 100 ng/ml



B. cepacia LPS and 100 ng/ml E. coli 0111:B4 LPS in the



presence of the indicated concentrations of SEQ ID 1


for 6 hr. The concentrations of TNF-α released into


the culture supernatants were determined by ELISA.


100% represents the amount of TNF-α resulting from


RAW 264.7 cells incubated with LPS alone for 6 hours


(S. typhimurium LPS = 34.5 ± 3.2 ng/ml, B. cepacia


LPS = 11.6 ± 2.9 ng/ml, and E. coli 0111:B4


LPS = 30.8 ± 2.4 ng/ml). Background levels of


TNF-α production by the RAW 264.7 cells cultured


with no stimuli for 6 hours resulted in TNF-α


levels ranging from 0.037-0.192 ng/ml. The data is from


duplicate samples and presented as the mean of three


experiments + standard error.








Amount of SEQ ID
Inhibition of TNF-α (%)*










1 (μ/ml)

B. cepacia LPS


E. coli LPS


S. typhimurium LPS














0.1
 8.5 ± 2.9
 0.0 ± 0.6
 0.0 ± 0


1
23.0 ± 11.4
36.6 ± 7.5
 9.8 ± 6.6


5
55.4 ± 8
65.0 ± 3.6
31.1 ± 7.0


10
63.1 ± 8
75.0 ± 3.4
37.4 ± 7.5


20
71.7 ± 5.8
81.0 ± 3.5
58.5 ± 10.5


50
86.7 ± 4.3
92.6 ± 2.5
73.1 ± 9.1
















TABLE 4







Reduction by Cationic Peptides of E. coli LPS induced TNF-α


production in RAW 264.7 cells. RAW 264.7 mouse macrophage cells


were stimulated with 100 ng/ml E. coli 0111:B4 LPS in the presence


of the indicated concentrations of cationic peptides for 6 h.


The concentrations of TNF-α released into the culture


supernatants were determined by ELISA. Background levels of


TNF-α production by the RAW 264.7 cells cultured with no


stimuli for 6 hours resulted in TNF-α levels ranging from


0.037-0.192 ng/ml. The data is from duplicate samples and


presented as the mean of three experiments + standard deviation.










Peptide (20 μ/ml)
Inhibition of TNF-α (%)















SEQ ID 5
65.6 ±
1.6



SEQ ID 6
59.8 ±
1.2



SEQ ID 7
50.6 ±
0.6



SEQ ID 8
39.3 ±
1.9



SEQ ID 9
58.7 ±
0.8



SEQ ID 10
55.5 ±
0.52



SEQ ID 12
52.1 ±
0.38



SEQ ID 13
62.4 ±
0.85



SEQ ID 14
50.8 ±
1.67



SEQ ID 15
69.4 ±
0.84



SEQ ID 16
37.5 ±
0.66



SEQ ID 17
28.3 ±
3.71



SEQ ID 19
69.9 ±
0.09



SEQ ID 20
66.1 ±
0.78



SEQ ID 21
67.8 ±
0.6



SEQ ID 22
73.3 ±
0.36



SEQ ID 23
83.6 ±
0.32



SEQ ID 24
60.5 ±
0.17



SEQ ID 26
54.9 ±
1.6



SEQ ID 27
51.1 ±
2.8



SEQ ID 28
56 ±
1.1



SEQ ID 29
58.9 ±
0.005



SEQ ID 31
60.3 ±
0.6



SEQ ID 33
62.1 ±
0.08



SEQ ID 34
53.3 ±
0.9



SEQ ID 35
60.7 ±
0.76



SEQ ID 36
63 ±
0.24



SEQ ID 37
58.9 ±
0.67



SEQ ID 38
54 ±
1



SEQ ID 40
75 ±
0.45



SEQ ID 41
86 ±
0.37



SEQ ID 42
80.5 ±
0.76



SEQ ID 43
88.2 ±
0.65



SEQ ID 44
44.9 ±
1.5



SEQ ID 45
44.7 ±
0.39



SEQ ID 47
36.9 ±
2.2



SEQ ID 48
64 ±
0.67



SEQ ID 49
86.9 ±
0.69



SEQ ID 53
46.5 ±
1.3



SEQ ID 54
64 ±
0.73

















TABLE 5







Reduction by SEQ ID 1 of LPS induced IL-8 production in A549


cells. A549 cells were stimulated with increasing concentrations


of SEQ ID 1 in the presence of LPS (100 ng/ml E. coli O111:B4)


for 24 hours. The concentration of IL-8 in the culture


supernatants was determined by ELISA. The background levels


of IL-8 from cells alone was 0.172 ± 0.029 ng/ml. The data


is presented as the mean of three experiments + standard error.










SEQ ID 1 (μ/ml)
Inhibition of IL-8 (%)














0.1
  1 ± 0.3



1
32 ± 10



10
60 ± 9 



20
47 ± 12



50
40 ± 13



100
0

















TABLE 6







Reduction by SEQ ID 2 of E. coli LPS induced IL-8 production


in A549 cells. Human A549 epithelial cells were stimulated


with increasing concentrations of SEQ ID 2 in the presence


of LPS (100 ng/ml E. coli O111:B4) for 24 hours. The


concentration of IL-8 in the culture supernatants was


determined by ELISA. The data is presented as the mean of


three experiments + standard error.










Concentration of
Inhibition of



SEQ ID 2 (μ/ml)
IL-8 (%)














0.1
 6.8 ± 9.6



1
 12.8 ± 24.5



10
 29.0 ± 26.0



50
39.8 ± 1.6



100
45.0 ± 3.5

















TABLE 7







Reduction by SEQ ID 2 of E. coli LPS induced IL-8 in human


blood. Whole human blood was stimulated with increasing


concentrations of peptide and E.coli O111:B4 LPS for 4 hr.


The human blood samples were centrifuged and the serum was


removed and tested for IL-8 by ELISA. The data is presented


as the average of 2 donors.










SEQ ID 2 (μ/ml)
IL-8 (pg/ml)














0
3205



10
1912



50
1458

















TABLE 8







Reduction by SEQ ID 1 of E. coli LPS induced TNF-α


production in murine bone marrow macrophages. BALB/c


Mouse bone marrow-derived macrophages were cultured


for either 6 h or 24 h with 100 ng/ml E. coli 0111:B4


LPS in the presence or absence of 20 μ/ml of peptide.


The supernatant was collected and tested for levels of


TNF-α by ELISA. The data represents the amount of


TNF-α resulting from duplicate wells of bone


marrow-derived macrophages incubated with LPS alone for 6 h


(1.1 ± 0.09 ng/ml) or 24 h (1.7 ± 0.2 ng/ml).


Background levels of TNF-α were 0.038 ± 0.008 ng/ml


for 6 h and 0.06 ± 0.012 ng/ml for 24 h.










Production of TNF-α (ng/ml)












SEQ ID 1 (μ/ml)
6 hours
24 hours







LPS alone
1.1
1.7



 1
0.02
0.048



 10
0.036
0.08



100
0.033
0.044



No LPS control
0.038
0.06

















TABLE 9







Inhibition of E. coli LPS-induced TNF-α production by


delayed addition of SEQ ID 1 to A549 cells. Peptide


(20 μg/ml) was added at increasing time points to wells


already containing A549 human epithelial cells and


100 ng/ml E. coli 0111:B4 LPS. The supernatant was collected


after 6 hours and tested for levels of TNF-α by ELISA.


The data is presented as the mean of three


experiments + standard error.










Time of addition of SEQ ID 1
Inhibition of



after LPS (min)
TNF-α (%)














0
98.3 + 0.3



15
89.3 + 3.8



30
  83 + 4.6



60
 68 + 8 



90
 53 + 8 

















TABLE 10







Protection against lethal endotoxaemia in galactosamine-


sensitized CD-1 mice by SEQ ID 1. CD-1 mice (9 weeks-old)


were sensitized to endotoxin by three intraperitoneal


injections of galactosamine (20 mg in 0.1 ml sterile PBS).


Then endotoxic shock was induced by intraperitoneal


injection of E. coli 0111:B4 LPS (3 μg in 0.1 ml PBS).


Peptide, SEQ ID 1, (200 μg/mouse = 8 mg/kg) was


injected at a separate intraperitoneal site 15 min after


injection of LPS. The mice were monitored for 48 hours


and the results were recorded.











D-Galactosamine

E. coli

Peptide or
Total
Survival post


treatment
0111:B4 LPS
buffer
mice
endotoxin shock















 0
3 μg
PBS
5
5
(100%)


20 mg
3 μg
PBS
12
0
(0%)


20 mg
3 μg
SEQ ID 1
12
6
(50%)
















TABLE 11







Protection against lethal endotoxaemia in galactosamine-


sensitized CD-1 mice by Cationic Peptides. CD-1 mice


(9 weeks-old) were sensitized to endotoxin by


intraperitoneal injection of galactosamine


(20 mg in 0.1 ml sterile PBS). Then endotoxic shock


was induced by intraperitoneal injection of E. coli


0111:B4 LPS (2 μg in 0.1 ml PBS). Peptide


(200 μg/mouse = 8 mg/kg) was injected at a


separate intraperitoneal site 15 min after injection


of LPS. The mice were monitored for 48 hours and the


results were recorded.












Peptide

E. coli 0111:B4

Number
Survival



Treatment
LPS added
of Mice
(%)
















Control (no peptide)
2 μg
5
0



SEQ ID 6
2 μg
5
40



SEQ ID 13
2 μg
5
20



SEQ ID 17
2 μg
5
40



SEQ ID 24
2 μg
5
0



SEQ ID 27
2 μg
5
20

















TABLE 12







Protection against lethal endotoxaemia in galactosamine-sensitized


BALB/c mice by Cationic Peptides. BALB/c mice (8 weeks-old) were


sensitized to endotoxin by intraperitoneal injection of galactosamine


(20 mg in 0.1 ml sterile PBS). Then endotoxic shock was induced by


intraperitoneal injection of E. coli 0111:B4 LPS (2 μg in 0.1 ml PBS).


Peptide (200 μg/mouse = 8 mg/kg) was injected at a separate


intraperitoneal site 15 min after injection of LPS. The mice were


monitored for 48 hours and the results were recorded.












Peptide

E. coli

Number
Survival



Treatment
0111:B4 LPS added
of Mice
(%)
















No peptide
2 μg
10
10



SEQ ID 1
2 μg
6
17



SEQ ID 3
2 μg
6
0



SEQ ID 5
2 μg
6
17



SEQ ID 6
2 μg
6
17



SEQ ID 12
2 μg
6
17



SEQ ID 13
2 μg
6
33



SEQ ID 15
2 μg
6
0



SEQ ID 16
2 μg
6
0



SEQ ID 17
2 μg
6
17



SEQ ID 23
2 μg
6
0



SEQ ID 24
2 μg
6
17



SEQ ID 26
2 μg
6
0



SEQ ID 27
2 μg
6
50



SEQ ID 29
2 μg
6
0



SEQ ID 37
2 μg
6
0



SEQ ID 38
2 μg
6
0



SEQ ID 41
2 μg
6
0



SEQ ID 44
2 μg
6
0



SEQ ID 45
2 μg
6
0

















TABLE 13







Protection against lethal endotoxaemia in BALB/c mice by SEQ ID 1.


BALB/c mice were injected intraperitoneal with 400 μg E. coli


0111:B4 LPS. Peptide (200 μg/mouse = 8 mg/kg) was injected at a


separate intraperitoneal site and the mice were monitored for 48


hours and the results were recorded.












Peptide

E. coli

Number
Survival



Treatment
0111:B4 LPS
of Mice
(%)
















No peptide
400 μg
5
0



SEQ ID 1
400 μg
5
100

















TABLE 14







Peptide inhibition of TNF-α production induced by S. aureus LTA.


RAW 264.7 mouse macrophage cells were stimulated with 1 μg/ml



S. aureus LTA in the absence and presence of increasing concentrations



of peptide. The supernatant was collected and tested for levels of


TNF-α by ELISA. Background levels of TNF-α production by the


RAW 264.7 cells cultured with no stimuli for 6 hours resulted in


TNF-α levels ranging from 0.037-0.192 ng/ml. The data is


presented as the mean of three or more experiments + standard error.










SEQ ID 1 added (μg/ml)
Inhibition of TNF-α (%)














0.1
 44.5 ± 12.5



1
76.7 ± 6.4



5
91 ± 1



10
94.5 ± 1.5



20
96 ± 1

















TABLE 15







Peptide inhibition of TNF-α production induced by


Mycobacterium non-capped lipoarabinomannan. RAW 264.7 mouse


macrophage cells were stimulated with 1 μg/ml AraLAM in


the absence and presence of 20 μg/ml peptide or


Polymyxin B. The supernatant was collected and tested for


levels of TNF-α by ELISA. Background levels of TNF-α


production by the RAW 264.7 cells cultured with no stimuli


for 6 hours resulted in TNF-α levels ranging from


0.037-0.192 ng/ml. The data is presented as the mean


inhibition of three or more experiments + standard error.










Peptide (20 μg/ml)
Inhibition of TNF-α (%)







No peptide
0



SEQ ID 1
 64 ± 5.9



Polymyxin B
15 ± 2 










EXAMPLE 3
Assessment of Toxicity of the Cationic Peptides

The potential toxicity of the peptides was measured in two ways. First, the Cytotoxicity Detection Kit (Roche) (Lactate dehydrogenase-LDH) Assay was used. It is a colorimetric assay for the quantification of cell death and cell lysis, based on the measurement of LDH activity released from the cytosol of damaged cells into the supernatant. LDH is a stable cytoplasmic enzyme present in all cells and it is released into the cell culture supernatant upon damage of the plasma membrane. An increase in the amount of dead or plasma membrane-damaged cells results in an increase of the LDH enzyme activity in the culture supernatant as measured with an ELISA plate reader, OD490 nm (the amount of color formed in the assay is proportional to the number of lysed cells). In this assay, human bronchial epithelial cells (16HBEo14, HBE) cells were incubated with 100 μg of peptide for 24 hours, the supernatant removed and tested for LDH. The other assay used to measure toxicity of the cationic peptides was the WST-1 assay (Roche). This assay is a colorimetric assay for the quantification of cell proliferation and cell viability, based on the cleavage of the tetrazolium salt WST-1 by mitochondrial dehydrogenases in viable cells (a non-radioactive alternative to the [3H]-thymidine incorporation assay). In this assay, HBE cells were incubated with 100 μg of peptide for 24 hours, and then 10 μl/well Cell Proliferation Reagent WST-1 was added. The cells are incubated with the reagent and the plate is then measured with an ELISA plate reader, OD490 nm.


The results shown below in Tables 16 and 17 demonstrate that most of the peptides are not toxic to the cells tested. However, four of the peptides from Formula F (SEQ ID NOS: 40, 41, 42 and 43) did induce membrane damage as measured by both assays.









TABLE 16







Toxicity of the Cationic Peptides as Measured by the LDH Release Assay.


Human HBE bronchial epithelial cells were incubated with 100 μg/ml


peptide or Polymyxin B for 24 hours. LDH activity was assayed in the


supernatant of the cell cultures. As a control for 100% LDH release,


Triton X-100 was added. The data is presented as the mean ± standard


deviation. Only peptides SEQ ID 40, 41, 42 and 43 showed any


significant toxicity.










Treatment
LDH Release (OD490 nm)







No cells Control
0.6 ± 0.1



Triton X-100 Control
4.6 ± 0.1



No peptide control
 1.0 ± 0.05



SEQ ID 1
1.18 ± 0.05



SEQ ID 3
1.05 ± 0.04



SEQ ID 6
0.97 ± 0.02



SEQ ID 7
1.01 ± 0.04



SEQ ID 9
 1.6 ± 0.03



SEQ ID 10
1.04 ± 0.04



SEQ ID 13
0.93 ± 0.06



SEQ ID 14
0.99 ± 0.05



SEQ ID 16
0.91 ± 0.04



SEQ ID 17
0.94 ± 0.04



SEQ ID 19
1.08 ± 0.02



SEQ ID 20
1.05 ± 0.03



SEQ ID 21
1.06 ± 0.04



SEQ ID 22
1.29 ± 0.12



SEQ ID 23
1.26 ± 0.46



SEQ ID 24
1.05 ± 0.01



SEQ ID 26
0.93 ± 0.04



SEQ ID 27
0.91 ± 0.04



SEQ ID 28
0.96 ± 0.06



SEQ ID 29
0.99 ± 0.02



SEQ ID 31
0.98 ± 0.03



SEQ ID 33
1.03 ± 0.05



SEQ ID 34
1.02 ± 0.03



SEQ ID 35
0.88 ± 0.03



SEQ ID 36
0.85 ± 0.04



SEQ ID 37
0.96 ± 0.04



SEQ ID 38
0.95 ± 0.02



SEQ ID 40
2.8 ± 0.5



SEQ ID 41
3.3 ± 0.2



SEQ ID 42
3.4 ± 0.2



SEQ ID 43
4.3 ± 0.2



SEQ ID 44
0.97 ± 0.03



SEQ ID 45
0.98 ± 0.04



SEQ ID 47
1.05 ± 0.05



SEQ ID 48
0.95 ± 0.05



SEQ ID 53
1.03 ± 0.06



Polymyxin B
1.21 ± 0.03

















TABLE 17







Toxicity of the Cationic Peptides as Measured by the WST-1 Assay. HBE


cells were incubated with 100 μg/ml peptide or Polymyxin B for 24 hours


and cell viability was tested. The data is presented as the mean ±


standard deviation. As a control for 100% LDH release, Triton X-100 was


added. Only peptides SEQ ID 40, 41, 42 and 43 showed


any significant toxicity.










Treatment
OD490 nm







No cells Control
0.24 ± 0.01



Triton X-100 Control
0.26 ± 0.01



No peptide control
1.63 ± 0.16



SEQ ID 1
1.62 ± 0.34



SEQ ID 3
1.35 ± 0.12



SEQ ID 10
1.22 ± 0.05



SEQ ID 6
1.81 ± 0.05



SEQ ID 7
1.78 ± 0.10



SEQ ID 9
1.69 ± 0.29



SEQ ID 13
1.23 ± 0.11



SEQ ID 14
1.25 ± 0.02



SEQ ID 16
1.39 ± 0.26



SEQ ID 17
1.60 ± 0.46



SEQ ID 19
1.42 ± 0.15



SEQ ID 20
1.61 ± 0.21



SEQ ID 21
1.28 ± 0.07



SEQ ID 22
1.33 ± 0.07



SEQ ID 23
1.14 ± 0.24



SEQ ID 24
1.27 ± 0.16



SEQ ID 26
1.42 ± 0.11



SEQ ID 27
1.63 ± 0.03



SEQ ID 28
1.69 ± 0.03



SEQ ID 29
1.75 ± 0.09



SEQ ID 31
1.84 ± 0.06



SEQ ID 33
1.75 ± 0.21



SEQ ID 34
0.96 ± 0.05



SEQ ID 35
1.00 ± 0.08



SEQ ID 36
1.58 ± 0.05



SEQ ID 37
1.67 ± 0.02



SEQ ID 38
1.83 ± 0.03



SEQ ID 40
0.46 ± 0.06



SEQ ID 41
0.40 ± 0.01



SEQ ID 42
0.39 ± 0.08



SEQ ID 43
0.46 ± 0.10



SEQ ID 44
1.49 ± 0.39



SEQ ID 45
1.54 ± 0.35



SEQ ID 47
1.14 ± 0.23



SEQ ID 48
0.93 ± 0.08



SEQ ID 53
1.51 ± 0.37



Polymyxin B
1.30 ± 0.13










EXAMPLE 4
Polynucleotide Regulation by Cationic Peptides

Polynucleotide arrays were utilized to determine the effect of cationic peptides by themselves on the transcriptional response of macrophages and epithelial cells. Mouse macrophage RAW 264.7, Human Bronchial cells (HBE), or A549 human epithelial cells were plated in 150 mm tissue culture dishes at 5.6×106 cells/dish, cultured overnight and then incubated with 50 μg/ml peptide or medium alone for 4 h. After stimulation, the cells were washed once with diethyl pyrocarbonate-treated PBS, and detached from the dish using a cell scraper. Total RNA was isolated using Trizol (Gibco Life Technologies). The RNA pellet was resuspended in RNase-free water containing RNase inhibitor (Ambion, Austin, Tex.). The RNA was treated with DNaseI (Clontech, Palo Alto, Calif.) for 1 h at 37° C. After adding termination mix (0.1 M EDTA [pH 8.0], 1 mg/ml glycogen), the samples were extracted once with phenol: chloroform: isoamyl alcohol (25:24:1), and once with chloroform. The RNA was then precipitated by adding 2.5 volumes of 100% ethanol and 1/10th volume sodium acetate, pH 5.2. The RNA was resuspended in RNase-free water with RNase inhibitor (Ambion) and stored at −70° C. The quality of the RNA was assessed by gel electrophoresis on a 1% agarose gel. Lack of genomic DNA contamination was assessed by using the isolated RNA as a template for PCR amplification with β-actin-specific primers (5′-GTCCCTGTATGCCTCTGGTC-3′ (SEQ ID NO: 55) and 5′-GATGTCACGCACGATTTCC-3′ (SEQ ID NO: 56)). Agarose gel electrophoresis and ethidium bromide staining confirmed the absence of an amplicon after 35 cycles.


Atlas cDNA Expression Arrays (Clontech, Palo Alto, Calif.), which consist of 588 selected mouse cDNAs spotted in duplicate on positively charged membranes were used for early polynucleotide array studies (Tables 18, 19). 32P-radiolabeled cDNA probes prepared from 5 μg total RNA were incubated with the arrays overnight at 71° C. The filters were washed extensively and then exposed to a phosphoimager screen (Molecular Dynamics, Sunnyvale, Calif.) for 3 days at 4° C. The image was captured using a Molecular Dynamics PSI phosphoimager. The hybridization signals were analyzed using AtlasImage 1.0 Image Analysis software (Clontech) and Excel (Microsoft, Redmond, Wash.). The intensities for each spot were corrected for background levels and normalized for differences in probe labeling using the average values for 5 polynucleotides observed to vary little between the stimulation conditions: β-actin, ubiquitin, ribosomal protein S29, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and Ca2+ binding protein. When the normalized hybridization intensity for a given cDNA was less than 20, it was assigned a value of 20 to calculate the ratios and relative expression.


The next polynucleotide arrays used (Tables 21-26) were the Resgen Human cDNA arrays (identification number for the genome is PRHU03-S3), which consist of 7,458 human cDNAs spotted in duplicate. Probes were prepared from 15-20 μg of total RNA and labeled with Cy3 labeled dUTP. The probes were purified and hybridized to printed glass slides overnight at 42° C. and washed. After washing, the image was captured using a Virtek slide reader. The image processing software (Imagene 4.1, Marina Del Rey, Calif.) determines the spot mean intensity, median intensities, and background intensities. Normalization and analysis was performed with Genespring software (Redwood City, Calif.). Intensity values were calculated by subtracting the mean background intensity from the mean intensity value determined by Imagene. The intensities for each spot were normalized by taking the median spot intensity value from the population of spot values within a slide and comparing this value to the values of all slides in the experiment. The relative changes seen with cells treated with peptide compared to control cells can be found in the Tables below.


The other polynucleotide arrays used (Tables 27-35) were the Human Operon arrays (identification number for the genome is PRHU04-S1), which consist of about 14,000 human oligos spotted in duplicate. Probes were prepared from 10 μg of total RNA and labeled with Cy3 or Cy5 labeled dUTP. In these experiments, A549 epithelial cells were plated in 100 mm tissue culture dishes at 2.5×106 cells/dish. Total RNA was isolated using RNAqueous (Ambion). DNA contamination was removed with DNA-free kit (Ambion). The probes prepared from total RNA were purified and hybridized to printed glass slides overnight at 42° C. and washed. After washing, the image was captured using a Perkin Elmer array scanner. The image processing software (Imagene 5.0, Marina Del Rey, Calif.) determines the spot mean intensity, median intensities, and background intensities. An “in house” program was used to remove background. The program calculates the bottom 10% intensity for each subgrid and subtracts this for each grid. Analysis was performed with Genespring software (Redwood City, Calif.). The intensities for each spot were normalized by taking the median spot intensity value from the population of spot values within a slide and comparing this value to the values of all slides in the experiment. The relative changes seen with cells treated with peptide compared to control cells can be found in the Tables below.


Semi-quantitative RT-PCR was performed to confirm polynucleotide array results. 1 μg RNA samples were incubated with 1 μl oligodT (500 μg/ml) and 1 μl mixed dNTP stock at 1 mM, in a 12 μl volume with DEPC treated water at 65° C. for 5 min in a thermocycler. 4 μl 5× First Strand buffer, 2 μl 0.1M DTT, and 1 μl RNaseOUT recombinant ribonuclease inhibitor (40 units/μl) were added and incubated at 42° C. for 2 min, followed by the addition of 1 μl (200 units) of Superscript II (Invitrogen, Burlington, ON). Negative controls for each RNA source were generated using parallel reactions in the absence of Superscript II. cDNAs were amplified in the presence of 5′ and 3′ primers (1.0 μM), 0.2 mM dNTP mixture, 1.5 mM MgCl, 1 U of Taq DNA polymerase (New England Biolabs, Missisauga, ON), and 1×PCR buffer. Each PCR was performed with a thermal cycler by using 30-40 cycles consisting of 30 s of denaturation at 94° C., 30 s of annealing at either 52° C. or 55° C. and 40 s of extension at 72° C. The number of cycles of PCR was optimized to lie in the linear phase of the reaction for each primer and set of RNA samples. A housekeeping polynucleotide β-actin was amplified in each experiment to evaluate extraction procedure and to estimate the amount of RNA. The reaction product was visualized by electrophoresis and analyzed by densitometry, with relative starting RNA concentrations calculated with reference to β-actin amplification.


Table 18 demonstrates that SEQ ID NO: 1 treatment of RAW 264.7 cells up-regulated the expression of more than 30 different polynucleotides on small Atlas microarrays with selected known polynucleotides. The polynucleotides up-regulated by peptide, SEQ ID NO: 1, were mainly from two categories: one that includes receptors (growth, chemokine, interleukin, interferon, hormone, neurotransmitter), cell surface antigens and cell adhesion and another one that includes cell-cell communication (growth factors, cytokines, chemokines, interleukin, interferons, hormones), cytoskeleton, motility, and protein turnover. The specific polynucleotides up-regulated included those encoding chemokine MCP-3, the anti-inflammatory cytokine IL-10, macrophage colony stimulating factor, and receptors such as IL-1R-2 (a putative antagonist of productive IL-1 binding to IL-1R1), PDGF receptor B, NOTCH4, LIF receptor, LFA-1, TGFβ receptor 1, G-CSF receptor, and IFNγ receptor. The peptide also up-regulated polynucleotides encoding several metalloproteinases, and inhibitors thereof, including the bone morphogenetic proteins BMP-1, BMP-2, BMP-8a, TIMP2 and TIMP3. As well, the peptide up-regulated specific transcription factors, including JunD, and the YY and LIM-1 transcription factors, and kinases such as Etk1 and Csk demonstrating its widespread effects. It was also discovered from the polynucleotide array studies that SEQ ID NO: 1 down-regulated at least 20 polynucleotides in RAW 264.7 macrophage cells (Table 19). The polynucleotides down-regulated by peptide included DNA repair proteins and several inflammatory mediators such as MIP-1α, oncostatin M and IL-12. A number of the effects of peptide on polynucleotide expression were confirmed by RT-PCR (Table 20). The peptides, SEQ ID NO: 2, SEQ ID NO: 3, SEQ ID NO: 19, and SEQ ID NO: 1, and representative peptides from each of the formulas also altered the transcriptional responses in a human epithelial cell line using mid-sized microarrays (7835 polynucleotides). The effect of SEQ ID NO: 1 on polynucleotide expression was compared in 2 human epithelial cell lines, A549 and HBE. Polynucleotides related to the host immune response that were up-regulated by 2 peptides or more by a ratio of 2-fold more than unstimulated cells are described in Table 21. Polynucleotides that were down-regulated by 2 peptides or more by a ratio of 2-fold more than unstimulated cells are described in Table 22. In Table 23 and Table 24, the human epithelial pro-inflammatory polynucleotides that are up- and down-regulated respectively are shown. In Table 25 and Table 26 the anti-inflammatory polynucleotides affected by cationic peptides are shown. The trend becomes clear that the cationic peptides up-regulate the anti-inflammatory response and down-regulate the pro-inflammatory response. It was very difficult to find a polynucleotide related to the anti-inflammatory response that was down-regulated (Table 26). The pro-inflammatory polynucleotides upregulated by cationic peptides were mainly polynucleotides related to migration and adhesion. Of the down-regulated pro-inflammatory polynucleotides, it should be noted that all the cationic peptides affected several toll-like receptor (TLR) polynucleotides, which are very important in signaling the host response to infectious agents. An important anti-inflammatory polynucleotide that was up-regulated by all the peptides is the IL-10 receptor. IL-10 is an important cytokine involved in regulating the pro-inflammatory cytokines. These polynucleotide expression effects were also observed using primary human macrophages as observed for peptide SEQ ID NO: 6 in Tables 27 and 28. The effect of representative peptides from each of the formulas on human epithelial cell expression of selected polynucleotides (out of 14,000 examined) is shown in Tables 31-37 below. At least 6 peptides from each formula were tested for their ability to alter human epithelial polynucleotide expression and indeed they had a wide range of stimulatory effects. In each of the formulas there were at least 50 polynucleotides commonly up-regulated by each of the peptides in the group.









TABLE 18







Polynucleotides up-regulated by peptide, SEQ ID NO: 1, treatment


of RAW macrophage cellsa.


The cationic peptides at a concentration of 50 μg/ml were shown


to potently induce the expression of several polynucleotides.


Peptide was incubated with the RAW cells for 4 h and the RNA


was isolated, converted into labeled cDNA probes and hybridized


to Atlas arrays. The intensity of unstimulated cells is shown in


the third column. The “Ratio Peptide: Unstimulated” column refers


to the intensity of polynucleotide expression in peptide-simulated


cells divided by the intensity of unstimulated cells.


The changes in the normalized intensities of the housekeeping


polynucleotides ranged from 0.8-1.2 fold, validating the


use of these polynucleotides for normalization. When the normalized


hybridization intensity for a given cDNA was less than 20, it


was assigned a value of 20 to calculate the ratios and relative


expression. The array experiments were repeated 3 times with


different RNA preparations and the average fold change is shown


above. Polynucleotides with a two fold or greater change in relative


expression levels are presented.











Polynucleo-
Polynucleo-

Ratio



tide/
tide
Unstimulated
peptide:
Accession


Protein
Function
Intensity
Unstimulatedb
Number














Etk1
Tyrosine-protein kinase
20
43
M68513



receptor


PDGFRB
Growth factor receptor
24
25
X04367



Corticotropin releasing
20
23
X72305



factor receptor


NOTCH4
proto-oncopolynucleotide
48
18
M80456


IL-1R2
Interleukin receptor
20
16
X59769


MCP-3
Chemokine
56
14
S71251


BMP-1
Bone
20
14
L24755



morphopolynucleotidetic



protein


Endothelin
Receptor
20
14
U32329


b receptor


c-ret
Oncopolynucleotide
20
13
X67812



precursor


LIFR
Cytokine receptor
20
12
D26177


BMP-8a
Bone
20
12
M97017



morphopolynucleotidetic



protein


Zfp92
Zinc finger protein 92
87
11
U47104


MCSF
Macrophage colony
85
11
X05010



stimulating factor 1


GCSFR
Granulocyte colony-
20
11
M58288



stimulating factor receptor


IL-8RB
Chemokine receptor
112
10
D17630


IL-9R
Interleukin receptor
112
6
M84746


Cas
Crk-associated substrate
31
6
U48853


p58/GTA
Kinase
254
5
M58633


CASP2
Caspase precursor
129
5
D28492


IL-1β
Interleukin precursor
91
5
M15131


precursor


SPI2-2
Serine protease inhibitor
62
5
M64086


C5AR
Chemokine receptor
300
4
S46665


L-myc
Oncopolynucleotide
208
4
X13945


IL-10
Interleukin
168
4
M37897


p19ink4
cdk4 and cdk6 inhibitor
147
4
U19597


ATOH2
Atonal homolog 2
113
4
U29086


DNAse1
DNase
87
4
U00478


CXCR-4
Chemokine receptor
36
4
D87747


Cyclin D3
Cyclin
327
3
U43844


IL-7Rα
Interleukin receptor
317
3
M29697


POLA
DNA polymeraseα
241
3
D17384


Tie-2
Oncopolynucleotide
193
3
S67051


DNL1
DNA ligase I
140
3
U04674


BAD
Apoptosis protein
122
3
L37296


GADD45
DNA-damage-inducible
88
3
L28177



protein


Sik
Src-related kinase
82
3
U16805


integrinα4
Integrin
2324
2
X53176


TGFβR1
Growth factor receptor
1038
2
D25540


LAMR1
Receptor
1001
2
J02870


Crk
Crk adaptor protein
853
2
S72408


ZFX
Chromosomal protein
679
2
M32309


Cyclin E1
Cylcin
671
2
X75888


POLD1
DNA polymerase subunit
649
2
Z21848


Vav
proto-oncopolynucleotide
613
2
X64361


YY(NF-E1)
Transcription factor
593
2
L13968


JunD
Transcription factor
534
2
J050205


Csk
c-src kinase
489
2
U05247


Cdk7
Cyclin-dependent kinase
475
2
U11822


MLC1A
Myosin light subunit
453
2
M19436



isoform


ERBB-3
Receptor
435
2
L47240


UBF
Transcription factor
405
2
X60831


TRAIL
Apoptosis ligand
364
2
U37522


LFA-1
Cell adhesion receptor
340
2
X14951


SLAP
Src-like adaptor protein
315
2
U29056


IFNGR
Interferon gamma receptor
308
2
M28233


LIM-1
Transcription factor
295
2
Z27410


ATF2
Transcription factor
287
2
S76657


FST
Follistatin precursor
275
2
Z29532


TIMP3
Protease inhibitor
259
2
L19622


RU49
Transcription factor
253
2
U41671


IGF-1Rα
Insulin-like growth
218
2
U00182



factor receptor


Cyclin G2
Cyclin
214
2
U95826


fyn
Tyrosine-protein kinase
191
2
U70324


BMP-2
Bone
186
2
L25602



morphopolynucleotidetic



protein


Brn-3.2
Transcription factor
174
2
S68377


POU


KIF1A
Kinesin family protein
169
2
D29951


MRC1
Mannose receptor
167
2
Z11974


PAI2
Protease inhibitor
154
2
X19622


BKLF
CACCC Box-binding protein
138
2
U36340


TIMP2
Protease inhibitor
136
2
X62622


Mas
Proto-oncopolynucleotide
131
2
X67735


NURR-1
Transcription factor
129
2
S53744
















TABLE 19







Polynucleotides down-regulated by SEQ ID NO: 1 treatment of RAW


macrophage cellsa.


The cationic peptides at a concentration of 50 μg/ml were shown


to reduce the expression of several polynucleotides. Peptide


was incubated with the RAW cells for 4 h and the RNA was isolated,


converted into labeled cDNA probes and hybridized to Atlas arrays.


The intensity of unstimulated cells is shown in the third column.


The “Ratio Peptide: Unstimulated” column refers to the intensity


of polynucleotide expression in peptide-simulated cells divided


by the intensity of unstimulated cells. The array experiments


were repeated 3 times with different cells and the average fold


change is shown below. Polynucleotides with an approximately


two fold or greater change in relative expression levels are


presented.














Ratio



Polynucleotide/
Polynucleotide
Unstimulated
peptide:
Accession


Protein
Function
Intensity
Unstimulated
Number














sodium channel
Voltage-gated ion channel
257
0.08
L36179


XRCC1
DNA repair protein
227
0.09
U02887


ets-2
Oncopolynucleotide
189
0.11
J04103


XPAC
DNA repair protein
485
0.12
X74351


EPOR
Receptor precursor
160
0.13
J04843


PEA 3
Ets-related protein
158
0.13
X63190


orphan receptor
Nuclear receptor
224
0.2
U11688


N-cadherin
Cell adhesion receptor
238
0.23
M31131


OCT3
Transcription factor
583
0.24
M34381


PLCβ
phospholipase
194
0.26
U43144


KRT18
Intermediate filament
318
0.28
M11686



proteins


THAM
Enzyme
342
0.32
X58384


CD40L
CD40 ligand
66
0.32
X65453


CD86
T-lymphocyte antigen
195
0.36
L25606


oncostatin M
Cytokine
1127
0.39
D31942


PMS2 DNA
DNA repair protein
200
0.4
U28724


IGFBP6
Growth factor
1291
0.41
X81584


MIP-1β
Cytokine
327
0.42
M23503


ATBF1
AT motif-binding factor
83
0.43
D26046


nucleobindin
Golgi resident protein
367
0.43
M96823


bcl-x
Apoptosis protein
142
0.43
L35049


uromodulin
glycoprotein
363
0.47
L33406


IL-12 p40
Interleukin
601
0.48
M86671


MmRad52
DNA repair protein
371
0.54
Z32767


Tob1
Antiproliferative factor
956
0.5
D78382


Ung1
DNA repair protein
535
0.51
X99018


KRT19
Intermediate filament
622
0.52
M28698



proteins


PLCγ
phospholipase
251
0.52
X95346


Integrin α6
Cell adhesion receptor
287
0.54
X69902


GLUT1
Glucose transporter
524
0.56
M23384


CTLA4
immunoglobin
468
0.57
X05719



superfamily


FRA2
Fos-related antigen
446
0.57
X83971


MTRP
Lysosome-associated
498
0.58
U34259



protein
















TABLE 20







Polynucleotide Expression changes in response to peptide, SEQ ID NO: 1,


could be confirmed by RT-PCR.


RAW 264.7 macrophage cells were incubated with 50 μg/ml of


peptide or media only for 4 hours and total RNA isolated and


subjected to semi-quantitative RT-PCR. Specific primer pairs


for each polynucleotide were used for amplification of RNA.


Amplification of β-actin was used as a positive control


and for standardization. Densitometric analysis of RT-PCR


products was used. The results refer to the relative fold


change in polynucleotide expression of peptide treated cells


compared to cells incubated with media alone. The data is


presented as the mean ± standard error of three experiments.











Polynucleotide
Array Ratio-*
RT-PCR Ratio -*







CXCR-4
4.0 ± 1.7
4.1 ± 0.9



IL-8RB
9.5 ± 7.6
7.1 ± 1.4



MCP-3
13.5 ± 4.4 
 4.8 ± 0.88



IL-10
4.2 ± 2.1
16.6 ± 6.1 



CD14
0.9 ± 0.1
0.8 ± 0.3



MIP-1B
0.42 ± 0.09
0.11 ± 0.04



XRCC1
0.12 ± 0.01
 0.25 ± 0.093



MCP-1
Not on array
3.5 ± 1.4

















TABLE 21







Polynucleotides up-regulated by peptide treatment of A549 epithelial


cellsa.


The cationic peptides at concentrations of 50 μg/ml were shown to increase the


expression of several polynucleotides. Peptide was incubated with the human A549


epithelial cells for 4 h and the RNA was isolated, converted into labeled cDNA probes


and hybridized to Human cDNA arrays ID#PRHU03-S3. The intensity of


polynucleotides in unstimulated cells is shown in the second column. The “Ratio Peptide:


Unstimulated” columns refers to the intensity of polynucleotide expression in peptide-


simulated cells divided by the intensity of unstimulated cells.











Unstimulated
Ratio Peptide: Unstimulated
Accession













Polynucleotide/Protein
Intensity
ID 2
ID 3
ID 19
ID 1
Number
















IL-1 R antagonist homolog 1
0.00
3086
1856
870

AI167887


IL-10 R beta
0.53
2.5
1.6
1.9
3.1
AA486393


IL-11 R alpha
0.55
2.4
1.0
4.9
1.8
AA454657


IL-17 R
0.54
2.1
2.0
1.5
1.9
AW029299


TNF R superfamily, member 1B
0.28
18
3.0
15
3.6
AA150416


TNF R superfamily, member 5
33.71
3.0
0.02


H98636


(CD40LR)


TNF R superfamily, member 11b
1.00
5.3
4.50
0.8

AA194983


IL-8
0.55
3.6
17
1.8
1.1
AA102526


interleukin enhancer binding factor 2
0.75
1.3
2.3
0.8
4.6
AA894687


interleukin enhancer binding factor 1
0.41
2.7

5.3
2.5
R56553


cytokine inducible SH2-containing
0.03
33
44
39
46
AA427521


protein


IK cytokine, down-regulator of
0.50
3.1
2.0
1.7
3.3
R39227


HLA II


cytokine inducible SH2-containing
0.03
33
44
39
46
AA427521


protein


IK cytokine, down-regulator of
0.50
3.1
2.0
1.7
3.3
R39227


HLA II


small inducible cytokine subfamily
1.00
3.9


2.4
AI922341


A (Cys-Cys), member 21


TGFB inducible early growth
0.90
2.4
2.1
0.9
1.1
AI473938


response 2


NK cell R
1.02
2.5
0.7
0.3
1.0
AA463248


CCR6
0.14
4.5
7.8
6.9
7.8
N57964


cell adhesion molecule
0.25
4.0
3.9
3.9
5.1
R40400


melanoma adhesion molecule
0.05
7.9
20
43
29.1
AA497002


CD31
0.59
2.7
3.1
1.0
1.7
R22412


integrin, alpha 2 (CD49B, alpha 2
1.00
0.9
2.4
3.6
0.9
AA463257


subunit of VLA-2 receptor


integrin, alpha 3 (antigen CD49C,
0.94
0.8
2.5
1.9
1.1
AA424695


alpha 3 subunit of VLA-3 receptor)


integrin, alpha E
0.01
180
120
28
81
AA425451


integrin, beta 1
0.47
2.1
2.1
7.0
2.6
W67174


integrin, beta 3
0.55
2.7
2.8
1.8
1.0
AA037229


integrin, beta 3
0.57
2.6
1.4
1.8
2.0
AA666269


integrin, beta 4
0.65
0.8
2.2
4.9
1.5
AA485668


integrin beta 4 binding protein
0.20
1.7
5.0
6.6
5.3
AI017019


calcium and integrin binding protein
0.21
2.8
4.7
9.7
6.7
AA487575


disintegrin and metalloproteinase
0.46
3.1

2.2
3.8
AA279188


domain 8


disintegrin and metalloproteinase
0.94
1.1
2.3
3.6
0.5
H59231


domain 9


disintegrin and metalloproteinase
0.49
1.5
2.1
3.3
2.2
AA043347


domain 10


disintegrin and metalloproteinase
0.44
1.9
2.3
2.5
4.6
H11006


domain 23


cadherin 1, type 1, E-cadherin
0.42
8.1
2.2
2.4
7.3
H97778


(epithelial)


cadherin 12, type 2 (N-cadherin 2)
0.11
13
26
9.5

AI740827


protocadherin 12
0.09
14.8
11.5
2.6
12.4
AI652584


protocadherin gamma subfamily C, 3
0.34
3.0
2.5
4.5
9.9
R89615


catenin (cadherin-associated
0.86
1.2
2.2
2.4

AA025276


protein), delta 1


laminin R 1 (67 kD, ribosomal
0.50
0.4
2.0
4.4
3.0
AA629897


protein SA)


killer cell lectin-like receptor
0.11
9.7
9.0
4.1
13.4
AA190627


subfamily C, member 2


killer cell lectin-like receptor
1.00
3.2
1.0
0.9
1.3
W93370


subfamily C, member 3


killer cell lectin-like receptor
0.95
2.3
1.7
0.7
1.1
AI433079


subfamily G, member 1


C-type lectin-like receptor-2
0.45
2.1
8.0
2.2
5.3
H70491


CSF 3 R
0.40
1.9
2.5
3.5
4.0
AA458507


macrophage stimulating 1 R
1.00
1.7
2.3
0.4
0.7
AA173454


BMP R type IA
0.72
1.9
2.8
0.3
1.4
W15390


formyl peptide receptor 1
1.00
3.1
1.4
0.4

AA425767


CD2
1.00
2.6
0.9
1.2
0.9
AA927710


CD36
0.18
8.2
5.5
6.2
2.5
N39161


vitamin D R
0.78
2.5
1.3
1.1
1.4
AA485226


Human proteinase activated R-2
0.54
6.1
1.9
2.2

AA454652


prostaglandin E receptor 3 (subtype
0.25
4.1
4.9
3.8
4.9
AA406362


EP3)


PDGF R beta polypeptide
1.03
2.5
1.0
0.5
0.8
R56211


VIP R 2
1.00
3.1


2.0
AI057229


growth factor receptor-bound
0.51
2.2
2.0
2.4
0.3
AA449831


protein 2


Mouse Mammary Turmor Virus
1.00
6.9

16

W93891


Receptor homolog


adenosine A2a R
0.41
3.1
1.8
4.0
2.5
N57553


adenosine A3 R
0.83
2.0
2.3
1.0
1.2
AA863086


T cell R delta locus
0.77
2.7
1.3

1.8
AA670107


prostaglandin E receptor 1 (subtype
0.65
7.2

6.0
1.5
AA972293


EP1)


growth factor receptor-bound
0.34

3.0
6.3
2.9
R24266


protein 14


Epstein-Barr virus induced
0.61
1.6
2.4

8.3
AA037376


polynucleotide 2


complement component receptor 2
0.22
26
4.5
2.6
18.1
AA521362


endothelin receptor type A
0.07
12
14
14
16
AA450009


v-SNARE R
0.56
11
12
1.8

AA704511


tyrosine kinase, non-receptor, 1
0.12
7.8
8.5
10
8.7
AI936324


receptor tyrosine kinase-like orphan
0.40
7.3
5.0
1.6
2.5
N94921


receptor 2


protein tyrosine phosphatase, non-
1.02
1.0
13.2
0.5
0.8
AA682684


receptor type 3


protein tyrosine phosphatase, non-
0.28
3.5
4.0
0.9
5.3
AA434420


receptor type 9


protein tyrosine phosphatase, non-
0.42
2.9
2.4
2.2
3.0
AA995560


receptor type 11


protein tyrosine phosphatase, non-
1.00
2.3
2.2
0.8
0.5
AA446259


receptor type 12


protein tyrosine phosphatase, non-
0.58
1.7
2.4
3.6
1.7
AA679180


receptor type 13


protein tyrosine phosphatase, non-
0.52
3.2
0.9
1.9
6.5
AI668897


receptor type 18


protein tyrosine phosphatase,
0.25
4.0
2.4
16.8
12.8
H82419


receptor type, A


protein tyrosine phosphatase,
0.60
3.6
3.2
1.6
1.0
AA045326


receptor type, J


protein tyrosine phosphatase,
0.73
1.2
2.8
3.0
1.4
R52794


receptor type, T


protein tyrosine phosphatase,
0.20
6.1
1.2
5.6
5.0
AA644448


receptor type, U


protein tyrosine phosphatase,
1.00
5.1


2.4
AA481547


receptor type, C-associated protein


phospholipase A2 receptor 1
0.45
2.8
2.2
1.9
2.2
AA086038


MAP kinase-activated protein
0.52
2.1
2.7
1.1
1.9
W68281


kinase 3


MAP kinase kinase 6
0.10
18
9.6

32
H07920


MAP kinase kinase 5
1.00
3.0
5.2
0.8
0.2
W69649


MAP kinase 7
0.09

11.5
12
33
H39192


MAP kinase 12
0.49
2.1
1.7
2.2
2.0
AI936909


G protein-coupled receptor 4
0.40
3.7
3.0
2.4
2.5
AI719098


G protein-coupled receptor 49
0.05

19
19
27
AA460530


G protein-coupled receptor 55
0.08
19
15
12

N58443


G protein-coupled receptor 75
0.26
5.2
3.1
7.1
3.9
H84878


G protein-coupled receptor 85
0.20
6.8
5.4
4.9
5.0
N62306


regulator of G-protein signalling 20
0.02
48
137
82

AI264190


regulator of G-protein signalling 6
0.27

3.7
8.9
10.6
R39932


BCL2-interacting killer (apoptosis-
1.00
1.9

5.2

AA291323


inducing)


apoptosis inhibitor 5
0.56
2.8
1.6
2.4
1.8
AI972925


caspase 6, apoptosis-related
0.79
0.7
2.6
1.3
2.8
W45688


cysteine protease


apoptosis-related protein PNAS-1
0.46
2.2
1.4
2.3
2.9
AA521316


caspase 8, apoptosis-related
0.95
2.2
1.0
0.6
2.0
AA448468


cysteine protease
















TABLE 22







Polynucleotides down-regulated by peptide treatment of A549 epithelial cellsa.


The cationic peptides at concentrations of 50 μg/ml were shown to decrease


the expression of several polynucleotides. Peptide was incubated with the human A549


epithelial cells for 4 h and the RNA was isolated, converted into labeled cDNA probes


and hybridized to Human cDNA arrays ID#PRHU03-S3. The intensity of


polynucleotides in unstimulated cells is shown in the second column. The “Ratio Peptide:


Unstimulated” columns refers to the intensity of polynucleotide expression in peptide-


simulated cells divided by the intensity of unstimulated cells.











Unstimulated
Ratio Peptide: Unstimulated
Accession













Polynucleotide/Protein
Intensity
ID 2
ID 3
ID 19
ID 1
Number
















TLR 1
3.22
0.35
0.31
0.14
0.19
AI339155


TLR 2
2.09
0.52
0.31
0.48
0.24
T57791


TLR 5
8.01
0.12
0.39


N41021


TLR 7
5.03
0.13
0.11
0.20
0.40
N30597


TNF receptor-associated factor 2
0.82
1.22
0.45
2.50
2.64
T55353


TNF receptor-associated factor 3
3.15
0.15

0.72
0.32
AA504259


TNF receptor superfamily, member 12
4.17
0.59
0.24

0.02
W71984


TNF R superfamily, member 17
2.62

0.38
0.55
0.34
AA987627


TRAF and TNF receptor-associated
1.33
0.75
0.22
0.67
0.80
AA488650


protein


IL-1 receptor, type I
1.39
0.34
0.72
1.19
0.34
AA464526


IL-2 receptor, alpha
2.46
0.41
0.33
0.58

AA903183


IL-2 receptor, gamma (severe combined
3.34
0.30
0.24

0.48
N54821


immunodeficiency)


IL-12 receptor, beta 2
4.58
0.67
0.22


AA977194


IL-18 receptor 1
1.78
0.50
0.42
0.92
0.56
AA482489


TGF beta receptor III
2.42
0.91
0.24
0.41
0.41
H62473


leukotriene b4 receptor (chemokine
1.00

1.38
4.13
0.88
AI982606


receptor-like 1)


small inducible cytokine subfamily A
2.26
0.32

0.44
1.26
AA495985


(Cys-Cys), member 18


small inducible cytokine subfamily A
2.22
0.19
0.38
0.45
0.90
AI285199


(Cys-Cys), member 20


small inducible cytokine subfamily A
2.64
0.38
0.31
1.53

AA916836


(Cys-Cys), member 23


small inducible cytokine subfamily B
3.57
0.11
0.06
0.28
0.38
AI889554


(Cys-X-Cys), member 6 (granulocyte


chemotactic protein 2)


small inducible cytokine subfamily B
2.02
0.50
1.07
0.29
0.40
AA878880


(Cys-X-Cys), member 10


small inducible cytokine A3
2.84
1.79
0.32
0.35

AA677522


(homologous to mouse Mip-1a)


cytokine-inducible kinase
2.70
0.41
0.37
0.37
0.34
AA489234


complement component C1q receptor
1.94
0.46
0.58
0.51
0.13
AI761788


cadherin 11, type 2, OB-cadherin
2.00
0.23
0.57
0.30
0.50
AA136983


(osteoblast)


cadherin 3, type 1, P-cadherin
2.11
0.43
0.53
0.10
0.47
AA425217


(placental)


cadherin, EGF LAG seven-pass G-type
1.67
0.42
0.41
1.21
0.60
H39187


receptor 2, flamingo (Drosophila)


homolog


cadherin 13, H-cadherin (heart)
1.78
0.37
0.40
0.56
0.68
R41787


selectin L (lymphocyte adhesion
4.43
0.03
0.23
0.61

H00662


molecule 1)


vascular cell adhesion molecule 1
1.40
0.20
0.72
0.77
0.40
H16591


intercellular adhesion molecule 3
1.00
0.12
0.31
2.04
1.57
AA479188


integrin, alpha 1
2.42
0.41
0.26

0.56
AA450324


integrin, alpha 7
2.53
0.57
0.39
0.22
0.31
AA055979


integrin, alpha 9
1.16
0.86
0.05
0.01
2.55
AA865557


integrin, alpha 10
1.00
0.33
0.18
1.33
2.25
AA460959


integrin, beta 5
1.00
0.32
1.52
1.90
0.06
AA434397


integrin, beta 8
3.27
0.10
1.14
0.31
0.24
W56754


disintegrin and metalloproteinase
2.50
0.40
0.29
0.57
0.17
AI205675


domain 18


disintegrin-like and metalloprotease
2.11
0.32
0.63
0.47
0.35
AA398492


with thrombospondin type 1 motif, 3


disintegrin-like and metalloprotease
1.62
0.39
0.42
1.02
0.62
AI375048


with thrombospondin type 1 motif, 5


T-cell receptor interacting molecule
1.00
0.41
1.24
1.41
0.45
AI453185


diphtheria toxin receptor (heparin-
1.62
0.49
0.85
0.62
0.15
R45640


binding epidermal growth factor-like


growth factor)


vasoactive intestinal peptide receptor 1
2.31
0.43
0.31
0.23
0.54
H73241


Fc fragment of IgG, low affinity IIIb,
3.85
−0.20
0.26
0.76
0.02
H20822


receptor for (CD16)


Fc fragment of IgG, low affinity IIb,
1.63
0.27
0.06
1.21
0.62
R68106


receptor for (CD32)


Fc fragment of IgE, high affinity I,
1.78
0.43
0.00
0.56
0.84
AI676097


receptor for; alpha polypeptide


leukocyte immunoglobulin-like
2.25
0.44
0.05
0.38
0.99
N63398


receptor, subfamily A


leukocyte immunoglobulin-like
14.21


1.10
0.07
AI815229


receptor, subfamily B (with TM and


ITIM domains), member 3


leukocyte immunoglobulin-like
2.31
0.75
0.43
0.19
0.40
AA076350


receptor, subfamily B (with TM and


ITIM domains), member 4


leukocyte immunoglobulin-like
1.67
0.35
0.60
0.18
0.90
H54023


receptor, subfamily B


peroxisome proliferative activated
1.18
0.38
0.85
0.87
0.26
AI739498


receptor, alpha


protein tyrosine phosphatase, receptor
2.19
0.43

1.06
0.46
N49751


type, f polypeptide (PTPRF), interacting


protein (liprin), α1


protein tyrosine phosphatase, receptor
1.55
0.44
0.64
0.30
0.81
H74265


type, C


protein tyrosine phosphatase, receptor
2.08
0.23
0.37
0.56
0.48
AA464542


type, E


protein tyrosine phosphatase, receptor
2.27
0.02
0.44

0.64
AA464590


type, N polypeptide 2


protein tyrosine phosphatase, receptor
2.34
0.11
0.43
0.24
0.89
AI924306


type, H


protein tyrosine phosphatase, receptor-
1.59
0.63
0.34
0.72
0.35
AA476461


type, Z polypeptide 1


protein tyrosine phosphatase, non-
1.07
0.94
0.43
0.25
1.13
H03504


receptor type 21


MAP kinase 8 interacting protein 2
1.70
0.07
0.85
0.47
0.59
AA418293


MAP kinase kinase kinase 4
1.27
0.37
0.79
1.59
−5.28
AA402447


MAP kinase kinase kinase 14
1.00
0.34
0.66
2.10
1.49
W61116


MAP kinase 8 interacting protein 2
2.90
0.16
0.35
0.24
0.55
AI202738


MAP kinase kinase kinase 12
1.48
0.20
0.91
0.58
0.68
AA053674


MAP kinase kinase kinase kinase 3
2.21
0.45
0.20
1.03
0.41
AA043537


MAP kinase kinase kinase 6
2.62
0.37
0.38

0.70
AW084649


MAP kinase kinase kinase kinase 4
1.04
0.96
0.09
0.29
2.79
AA417711


MAP kinase kinase kinase 11
1.53
0.65
0.41
0.99
0.44
R80779


MAP kinase kinase kinase 10
1.32
1.23
0.27
0.50
0.76
H01340


MAP kinase 9
2.54
0.57
0.39
0.16
0.38
AA157286


MAP kinase kinase kinase 1
1.23
0.61
0.42
0.81
1.07
AI538525


MAP kinase kinase kinase 8
0.66
1.52
1.82
9.50
0.59
W56266


MAP kinase-activated protein kinase 3
0.52
2.13
2.68
1.13
1.93
W68281


MAP kinase kinase 2
0.84
1.20
3.35
0.02
1.31
AA425826


MAP kinase kinase kinase 7
1.00
0.97

1.62
7.46
AA460969


MAP kinase 7
0.09

11.45
11.80
33.43
H39192


MAP kinase kinase 6
0.10
17.83
9.61

32.30
H07920


regulator of G-protein signalling 5
3.7397
0.27
0.06
0.68
0.18
AA668470


regulator of G-protein signalling 13
1.8564
0.54
0.45
0.07
1.09
H70047


G protein-coupled receptor
1.04
1.84
0.16
0.09
0.96
R91916


G protein-coupled receptor 17
1.78
0.32
0.56
0.39
0.77
AI953187


G protein-coupled receptor kinase 7
2.62

0.34
0.91
0.38
AA488413


orphan seven-transmembrane receptor,
7.16
1.06
0.10
0.11
0.14
AI131555


chemokine related


apoptosis antagonizing transcription
1.00
0.28
2.50
1.28
0.19
AI439571


factor


caspase 1, apoptosis-related cysteine
2.83
0.44

0.33
0.35
T95052


protease (interleukin 1, beta,


convertase)


programmed cell death 8 (apoptosis-
1.00
1.07
0.35
1.94
0.08
AA496348


inducing factor)
















TABLE 23







Pro-inflammatory polynucleotides up-regulated by peptide treatment of A549 cells.


The cationic peptides at concentrations of 50 μg/ml were shown to increase the


expression of certain pro-inflammatory polynucleotides (data is a subset of Table 21).


Peptide was incubated with the human A549 epithelial cells for 4 h and the RNA was


isolated, converted into labeled cDNA probes and hybridized to Human cDNA arrays


ID#PRHU03-S3. The intensity of polynucleotides in unstimulated cells is shown in the


second column. The “Ratio Peptide: Unstimulated” columns refers to the intensity of


polynucleotide expression in peptide-simulated cells divided by the intensity of


unstimulated cells.











Unstim.
Ratio Peptide: Unstimulated
Accession













Polynucleotide/Protein and function
Intensity
ID 2
ID 3
ID 19
ID 1
Number
















IL-11 Rα; Receptor for pro-
0.55
2.39
0.98
4.85
1.82
AA454657


inflammatory cytokine, inflammation


IL-17 R; Receptor for IL-17, an inducer
0.54
2.05
1.97
1.52
1.86
AW029299


of cytokine production in epithelial cells


small inducible cytokine subfamily A,
1.00
3.88


2.41
AI922341


member 21; a chemokine


CD31; Leukocyte and cell to cell
0.59
2.71
3.13
1.01
1.68
R22412


adhesion (PECAM)


CCR6; Receptor for chemokine MIP-3α
0.14
4.51
7.75
6.92
7.79
N57964


integrin, alpha 2 (CD49B, alpha 2
1.00
0.89
2.44
3.62
0.88
AA463257


subunit of VLA-2 receptor; Adhesion to


leukocytes


integrin, alpha 3 (antigen CD49C, alpha
0.94
0.79
2.51
1.88
1.07
AA424695


3 subunit of VLA-3 receptor);


Leukocyte Adhesion


integrin, alpha E; Adhesion
0.01
179.33
120.12
28.48
81.37
AA425451


integrin, beta 4; Leukocyte adhesion
0.65
0.79
2.17
4.94
1.55
AA485668


C-type lectin-like receptor-2; Leukocyte
0.45
2.09
7.92
2.24
5.29
H70491


adhesion
















TABLE 24







Pro-inflammatory polynucleotides down-regulated by peptide treatment of A549 cells.


The cationic peptides at concentrations of 50 μg/ml were shown to decrease


the expression of certain pro-inflammatory polynucleotides (data is a subset of Table 22).


Peptide was incubated with the human A549 epithelial cells for 4 h and the RNA was


isolated, converted into labeled cDNA probes and hybridized to Human cDNA arrays


ID#PRHU03-S3. The intensity of polynucleotides in unstimulated cells is shown in the


second column. The “Ratio Peptide: Unstimulated” columns refers to the intensity of


polynucleotide expression in peptide-simulated cells divided by the intensity of


unstimulated cells.











Unstim
Ratio Peptide: Unstimulated
Accession













Polynucleotide/Protein; Function
Intensity
ID 2
ID 3
ID 19
ID 1
Number
















Toll-like receptor (TLR) 1; Response to gram
3.22
0.35
0.31
0.14
0.19
AI339155


positive bacteria


TLR 2; Response to gram positive bacteria and
2.09
0.52
0.31
0.48
0.24
T57791


yeast


TLR 5; May augment other TLR responses,
8.01
0.12
0.39


N41021


Responsive to flagellin


TLR 7: Putative host defence mechanism
5.03
0.13
0.11
0.20
0.40
N30597


TNF receptor-associated factor 2; Inflammation
0.82
1.22
0.45
2.50
2.64
T55353


TNF receptor-associated factor 3; Inflammation
3.15
0.15

0.72
0.32
AA504259


TNF receptor superfamily, member 12;
4.17
0.59
0.24

0.02
W71984


Inflammation


TNF R superfamily, member 17; Inflammation
2.62

0.38
0.55
0.34
AA987627


TRAF and TNF receptor-associated protein;
1.33
0.75
0.22
0.67
0.80
AA488650


TNF signalling


small inducible cytokine subfamily A, member
2.26
0.32

0.44
1.26
AA495985


18; Chemokine


small inducible cytokine subfamily A, member
2.22
0.19
0.38
0.45
0.90
AI285199


20; Chemokine


small inducible cytokine subfamily A, member
2.64
0.38
0.31
1.53

AA916836


23; Chemokine


small inducible cytokine subfamily B, member
3.57
0.11
0.06
0.28
0.38
AI889554


6 (granulocyte chemotactic protein); Chemokine


small inducible cytokine subfamily B, member
2.02
0.50
1.07
0.29
0.40
AA878880


10; Chemokine


small inducible cytokine A3 (homologous to
2.84
1.79
0.32
0.35

AA677522


mouse Mip-1α); Chemokine


IL-12 receptor, beta 2; Interleukin and
4.58
0.67
0.22


AA977194


Interferon receptor


IL-18 receptor 1; Induces IFN-γ
1.78
0.50
0.42
0.92
0.56
AA482489


selectin L (lymphocyte adhesion molecule 1);
4.43
0.03
0.23
0.61

H00662


Leukocyte adhesion


vascular cell adhesion molecule 1; Leukocyte
1.40
0.20
0.72
0.77
0.40
H16591


adhesion


intercellular adhesion molecule 3; Leukocyte
1.00
0.12
0.31
2.04
1.57
AA479188


adhesion


integrin, alpha 1; Leukocyte adhesion
2.42
0.41
0.26

0.56
AA450324
















TABLE 25







Anti-inflammatory polynucleotides up-regulated by peptide treatment of A549 cells.


The cationic peptides at concentrations of 50 μg/ml were shown to increase the


expression of certain anti-inflammatory polynucleotides (data is a subset of Table 21).


Peptide was incubated with the human A549 epithelial cells for 4 h and the RNA was


isolated, converted into labeled cDNA probes and hybridized to Human cDNA arrays


ID#PRHU03-S3. The intensity of polynucleotides in unstimulated cells is shown in the


second column. The “Ratio Peptide: Unstimulated” columns refers to the intensity of


polynucleotide expression in peptide-simulated cells divided by the intensity of


unstimulated cells.











Unstim
Ratio Peptide: Unstimulated
Accession













Polynucleotide/Protein; Function
Intensity
ID 2
ID 3
ID 19
ID 1
Number
















IL-1 R antagonist homolog 1; Inhibitor of septic
0.00
3085.96
1855.90
869.57

AI167887


shock


IL-10 R beta; Receptor for cytokine synthesis
0.53
2.51
1.56
1.88
3.10
AA486393


inhibitor


TNF R, member 1B; Apoptosis
0.28
17.09
3.01
14.93
3.60
AA150416


TNF R, member 5; Apoptosis (CD40L)
33.71
2.98
0.02


H98636


TNF R, member 11b; Apoptosis
1.00
5.29
4.50
0.78

AA194983


IK cytokine, down-regulator of HLA II; Inhibits
0.50
3.11
2.01
1.74
3.29
R39227


antigen presentation


TGFB inducible early growth response 2; anti-
0.90
2.38
2.08
0.87
1.11
AI473938


inflammatory cytokine


CD2; Adhesion molecule, binds LFAp3
1.00
2.62
0.87
1.15
0.88
AA927710
















TABLE 26







Anti-inflammatory polynucleotides down-regulated by peptide treatment of


A549 cells.


The cationic peptides at concentrations of 50 μg/ml were shown to increase the


expression of certain anti-inflammatory polynucleotides (data is a subset of Table 21).


Peptide was incubated with the human A549 epithelial cells for 4 h and the RNA was


isolated, converted into labeled cDNA probes and hybridized to Human cDNA arrays


ID#PRHU03-S3. The intensity of polynucleotides in unstimulated cells is shown in


the second column. The “Ratio Peptide: Unstimulated” columns refers to the


intensity of polynucleotide expression in peptide-simulated cells divided by the


intensity of unstimulated cells.










Polynucleotide/Protein;
Unstim
Ratio Peptide: Unstimulated
Accession













Function
Intensity
ID 2
ID 3
ID 19
ID 1
Number





MAP kinase 9
2.54
0.57
0.39
0.16
0.38
AA157286
















TABLE 27







Polynucleotides up-regulated by SEQ ID NO: 6, in primary human macrophages.


The peptide SEQ ID NO: 6 at a concentration of 50 μg/ml was


shown to increase the expression of many polynucleotides.


Peptide was incubated with the human macrophages for 4 h and


the RNA was isolated, converted into labeled cDNA probes and


hybridized to Human Operon arrays (PRHU04). The intensity of


polynucleotides in unstimulated cells is shown in the second


column. The “Ratio peptide treated: Control” columns refer


to the intensity of polynucleotide expression in peptide-


simulated cells divided by the intensity of unstimulated cells.









Gene
Control: Unstimulated
Ratio peptide


(Accession Number)
cells
treated: control












proteoglycan 2 (Z26248)
0.69
9.3


Unknown (AK001843)
26.3
8.2


phosphorylase kinase alpha 1 (X73874)
0.65
7.1


actinin, alpha 3 (M86407)
0.93
6.9


DKFZP586B2420 protein (AL050143)
0.84
5.9


Unknown (AL109678)
0.55
5.6


transcription factor 21 (AF047419)
0.55
5.4


Unknown (A433612)
0.62
5.0


chromosome condensation 1-like (AF060219)
0.69
4.8


Unknown (AL137715)
0.66
4.4


apoptosis inhibitor 4 (U75285)
0.55
4.2


TERF1 (TRF1)-interacting nuclear factor 2
0.73
4.2


(NM_012461)


LINE retrotransposable element 1 (M22333)
6.21
4.0


1-acylglycerol-3-phosphate O-acyltransferase 1
0.89
4.0


(U56417)


Vacuolar proton-ATPase, subunit D; V-
1.74
4.0


ATPase, subunit D (X71490)


KIAA0592 protein (AB011164)
0.70
4.0


potassium voltage-gated channel KQT-like
0.59
3.9


subfamily member 4 (AF105202)


CDC14 homolog A (AF000367)
0.87
3.8


histone fold proteinCHRAC17 (AF070640)
0.63
3.8


Cryptochrome 1 (D83702)
0.69
3.8


pancreatic zymogen granule membrane
0.71
3.7


associated protein (AB035541)


Sp3 transcription factor (X68560)
0.67
3.6


hypothetical protein FLJ20495 (AK000502)
0.67
3.5


E2F transcription factor 5, p130-binding
0.56
3.5


(U31556)


hypothetical protein FLJ20070 (AK000077)
1.35
3.4


glycoprotein IX (X52997)
0.68
3.4


KIAA1013 protein (AB023230)
0.80
3.4


eukaryotic translation initiation factor 4A,
2.02
3.4


isoform 2 (AL137681)


FYN-binding protein (AF198052)
1.04
3.3


guanine nucleotide binding protein, gamma
0.80
3.3


transducing activity polypeptide 1 (U41492)


glypican 1 (X54232)
0.74
3.2


mucosal vascular addressin cell adhesion
0.65
3.2


molecule 1 (U43628)


lymphocyte antigen (M38056)
0.70
3.2


H1 histone family, member 4 (M60748)
0.81
3.0


translational inhibitor protein p14.5 (X95384)
0.78
3.0


hypothetical protein FLJ20689 (AB032978)
1.03
2.9


KIAA1278 protein (AB03104)
0.80
2.9


unknown (AL031864)
0.95
2.9


chymotrypsin-like protease (X71877)
3.39
2.9


calumenin (NM_001219)
2.08
2.9


protein kinase, cAMP-dependent, regulatory,
7.16
2.9


type I, beta (M65066)


POU domain, class 4, transcription factor 2
0.79
2.8


(U06233)


POU domain, class 2, associating factor 1
1.09
2.8


(Z49194)


KIAA0532 protein (AB011104)
0.84
2.8


unknown (AF068289)
1.01
2.8


unknown (AL117643)
0.86
2.7


cathepsin E (M84424)
15.33
2.7


matrix metalloproteinase 23A (AF056200)
0.73
2.7


interferon receptor 2 (L42243)
0.70
2.5


MAP kinase kinase 1 (L11284)
0.61
2.4


protein kinase C, alpha (X52479)
0.76
2.4


c-Cbl-interacting protein (AF230904)
0.95
2.4


c-fos induced growth factor (Y12864)
0.67
2.3


cyclin-dependent kinase inhibitor 1B (S76988)
0.89
2.2


zinc finger protein 266 (X78924)
1.67
2.2


MAP kinase 14 (L35263)
1.21
2.2


KIAA0922 protein (AB023139)
0.96
2.1


bone morphogenetic protein 1 (NM_006129)
1.10
2.1


NADH dehydrogenase 1 alpha subcomplex, 10
1.47
2.1


(AF087661)


bone morphogenetic protein receptor, type IB
0.50
2.1


(U89326)


interferon regulatory factor 2 (NM 002199)
1.46
2.0


protease, serine, 21 (AB031331)
0.89
2.0
















TABLE 28







Polynucleotides down-regulated by SEQ ID NO: 6,


in primary human macrophages.


The peptide SEQ ID NO: 6 at a concentration of 50


μg/ml was shown to increase the expression of


many polynucleotides. Peptide was incubated with


the human macrophages for 4 h and the RNA was


isolated, converted into labeled cDNA probes and


hybridized to Human Operon arrays (PRHU04). The


intensity of polynucleotides in ustimulated cells


is shown in the second column. The “Ratio of


Peptide:Control” columns refers to the


intensity of polynucleotides expressions in peptide-


stimulated cells divided by the intensity of


unstimulated cells.










Control:




Unstimulated
Ratio peptide


Gene (Accession Number)
cells
treated:control












Unknown (AL049263)
17
0.06


integrin-linked kinase (U40282)
2.0
0.13


KIAA0842 protein (AB020649)
1.1
0.13


Unknown (AB037838)
13
0.14


Granulin (AF055008)
8.6
0.14


glutathione peroxidase 3 (NM_002084)
1.2
0.15


KIAA0152 gene product (D63486)
0.9
0.17


TGFB1-induced anti-apoptotic
0.9
0.19


factor 1 (D86970)


disintegrin protease (Y13323)
1.5
0.21


proteasome subunit
0.7
0.22


beta type 7 (D38048)


cofactor required for Sp1
0.9
0.23


transcriptional activation


subunit 3 (AB033042)


TNF receptor superfamily,
0.8
0.26


member 14 (U81232)


proteasome 26S subunit
1.1
0.28


non-ATPase 8 (D38047)


proteasome subunit
0.7
0.29


beta type, 4 (D26600)


TNF receptor superfamily
1.7
0.29


member 1B (M32315)


cytochrome c oxidase
3.3
0.30


subunit Vic (X13238)


S100 calcium-binding
3.8
0.31


protein A4 (M80563)


proteasome subunit alpha
2.9
0.31


type, 6 (X59417)


proteasome 26S subunit
1.0
0.32


non-ATPase, 10 (AL031177)


MAP kinase kinase
0.8
0.32


kinase 2 (NM_006609)


ribosomal protein
5.5
0.32


L11 (X79234)


matrix metalloproteinase
1.0
0.32


14 (Z48481)


proteasome subunit beta type,
1.5
0.33


5 (D29011)


MAP kinase-activated protein
1.5
0.34


kinase 2 (U12779)


caspase 3 (U13737)
0.5
0.35


jun D proto-oncogene (X56681)
3.0
0.35


proteasome 26S subunit,
1.3
0.35


ATPase, 3 (M34079)


IL-1 receptor-like
0.7
0.35


1 (AB012701)


interferon alpha-inducible
13
0.35


protein (AB019565)


SDF receptor 1 (NM_012428)
1.6
0.35


Cathepsin D (M63138)
46
0.36


MAP kinase kinase 3 (D87116)
7.4
0.37


TGF, beta-induced, (M77349)
1.8
0.37


TNF receptor superfamily,
1.1
0.37


member 10b (AF016266)


proteasome subunit beta type,
1.3
0.38


6 (M34079)


nuclear receptor binding
5.2
0.38


protein (NM_013392)


Unknown (AL050370)
1.3
0.38


protease inhibitor 1
0.7
0.40


alpha-1-antitrypsin (X01683)


proteasome subunit alpha type,
5.6
0.40


7 (AF054185)


LPS-induced TNF-alpha
5.3
0.41


factor (NM_004862)


transferrin receptor (X01060)
14
0.42


proteasome 26S subunit
1.8
0.44


non-ATPase 13 (AB009398)


MAP kinase kinase 5 (U25265)
1.3
0.44


Cathepsin L(X12451)
15
0.44


IL-1 receptor-associated
1.7
0.45


kinase 1 (L76191)


MAP kinase kinase kinase
1.1
0.46


kinase 2 (U07349)


peroxisome proliferative
2.2
0.46


activated receptor delta (AL022721)


TNF superfamily,
16
0.46


member 15 (AF039390)


defender against cell
3.9
0.46


death 1 (D15057)


TNF superfamily member
287
0.46


10 (U37518)


cathepsin H (X16832)
14
0.47


protease inhibitor 12 (Z81326)
0.6
0.48


proteasome subunit alpha type,
2.6
0.49


4 (D00763)


proteasome 26S subunit ATPase,
1.8
0.49


1 (L02426)


proteasome 26S subunit ATPase,
2.1
0.49


2 (D11094)


caspase 7 (U67319)
2.4
0.49


matrix metalloproteinase
2.5
0.49


7 (Z11887)
















TABLE 29







Polynucleotides up-regulated by SEQ ID NO: 1, in HBE cells.


The Peptide SEQ ID NO: 1 at a concentration of 50 μg/ml


was shown to increase the expression of many polynucleotides.


Peptide was incubated with the human HBE epithelial cells for


4 h and the RNA was isolated, converted into labeled cDNA probes


and hybridized to Human Operon arrays (PRHU04). The intensity of


polynucleotides in unstimulated cells is shown in the second column.


The “Ratio Peptide:Control” columns refer to the intensity


of polynucleotide expression in peptide-simulated cells divided by the


intensity of unstimulated cells.












Control:



Accession

Unstimulated
Ratio peptide


Number
Gene
cells
treated:control













AL110161
Unknown
0.22
5218.3


AF131842
Unknown
0.01
573.1


AJ000730
solute carrier family
0.01
282.0


Z25884
chloride channel 1
0.01
256.2


M93426
protein tyrosine phosphatase
0.01
248.7



receptor-type, zeta


X65857
olfactory receptor, family 1,
0.01
228.7



subfamily D, member 2


M55654
TATA box binding protein
0.21
81.9


AK001411
hypothetical protein
0.19
56.1


D29643
dolichyl-diphosphooligosaccharide-
1.56
55.4



protein glycosyltransferase


AF006822
myelin transcription factor 2
0.07
55.3


AL117601
Unknown
0.05
53.8


AL117629
DKFZP434C245 protein
0.38
45.8


M59465
tumor necrosis factor,
0.50
45.1



alpha-induced protein 3


AB013456
aquaporin 8
0.06
41.3


AJ131244
SEC24 related gene family,
0.56
25.1



member A


AL110179
Unknown
0.87
24.8


AB037844
Unknwon
1.47
20.6


Z47727
polymerase II polypeptide K
0.11
20.5


AL035694
Unknown
0.81
20.4


X68994
H.sapiens CREB gene
0.13
19.3


AJ238379
hypothetical protein
1.39
18.5


NM_003519
H2B histone family member
0.13
18.3


U16126
glutamate receptor, ionotropic
0.13
17.9



kainate 2


U29926
adenosine monophosphate
0.16
16.3



deaminase


AK001160
hypothetical protein
0.39
14.4


U18018
ets variant gene 4
0.21
12.9


D80006
KIAA0184 protein
0.21
12.6


AK000768
hypothetical protein
0.30
12.3


X99894
insulin promoter factor 1,
0.26
12.0


AL031177
Unknown
1.09
11.2


AF052091
unknown
0.28
10.9


L38928
5, 10-methenyltetrahydrofolate
0.22
10.6



synthetase


AL117421
unknown
0.89
10.1


AL133606
hypothetical protein
0.89
9.8


NM_016227
membrane protein CH1
0.28
9.6


NM_006594
adaptor-related protein
0.39
9.3



complex 4


U54996
ZW10 homolog, protein
0.59
9.3


AJ007557
potassium channel,
0.28
9.0


AF043938
muscle RAS oncogene
1.24
8.8


AK001607
unknown
2.74
8.7


AL031320
peroxisomal biogenesis
0.31
8.4



factor 3


D38024
unknown
0.31
8.3


AF059575
LIM homeobox TF
2.08
8.2


AF043724
hepatitis A virus cellular
0.39
8.1



receptor 1


AK002062
hypothetical protein
2.03
8.0


L13436
natriuretic peptide receptor
0.53
7.8


U33749
thyroid transcription factor 1
0.36
7.6


AF011792
cell cycle progression 2 protein
0.31
7.6


AK000193
hypothetical protein
1.18
6.8


AF039022
exportin, tRNA
0.35
6.8


M17017
interleukin 8
0.50
6.7


AF044958
NADH dehydrogenase
0.97
6.5


U35246
vacuolar protein sorting
0.48
6.5


AK001326
tetraspan 3
1.59
6.5


M55422
Krueppel-related zinc
0.34
6.4



finger protein


U44772
palmitoyl-protein
1.17
6.3



thioesterase


AL117485
hypothetical protein
0.67
5.9


AB037776
unknown
0.75
5.7


AF131827
unknown
0.69
5.6


AL137560
unknown
0.48
5.2


X05908
annexin A1
0.81
5.1


X68264
melanoma adhesion molecule
0.64
5.0


AL161995
neurturin
0.86
4.9


AF037372
cytochrome c oxidase
0.48
4.8


NM_016187
bridging integrator 2
0.65
4.8


AL137758
unknown
0.57
4.8


U59863
TRAF family member-associated
0.46
4.7



NFKB activator


Z30643
chloride channel Ka
0.70
4.7


D16294
acetyl-Coenzyme A
1.07
4.6



acyltransferase 2


AJ132592
zinc finger protein 281
0.55
4.6


X82324
POU domain TF
1.73
4.5


NM_016047
CGI-110 protein
1.95
4.5


AK001371
hypothetical protein
0.49
4.5


M60746
H3 histone family member D
3.05
4.5


AB033071
hypothetical protein
4.47
4.4


AB002305
KIAA0307 gene product
1.37
4.4


X92689
UDP-N-acetyl-alpha-D-
0.99
4.4



galactosamine: polypeptide N-



acetylgalactosaminyltransferase 3


AL049543
glutathione peroxidase 5
1.62
4.3


U43148
patched homolog
0.96
4.3


M67439
dopamine receptor D5
2.61
4.2


U09850
zinc finger protein 143
0.56
4.2


L20316
glucagon receptor
0.75
4.2


AB037767
a disintegrin-like and
0.69
4.2



metalloprotease


NM_017433
myosin IIIA
99.20
4.2


D26579
a disintegrin and
0.59
4.1



metalloprotease domain 8


L10333
reticulon 1
1.81
4.1


AK000761
unknown
1.87
4.1


U91540
NK homeobox family 3, A
0.80
4.1


Z17227
interleukin 10 receptor, beta
0.75
4.0
















TABLE 30







Polynucleotides down-regulated by Peptide (50 μg/ml), SEQ ID NO: 1, in HBE cells.


The Peptide SEQ ID: 1 at a concentration of 50 μg/ml was shown to


decrease the expression of many polynucleotides. Peptide was incubated


with the human A549 epithelial cells for 4 h and the RNA was isolated,


converted into labeled cDNA probes and hybridized to Human Operon


arrays (PRHU04). The intensity of polynucleotides in unstimulated


cells is shown in the third column. The “Ratio Peptide:Control”


columns refer to the intensity of polynucleotide expression in


peptide-simulated cells divided by the intensity of unstimulated cells.












Control:
Ratio of SEQ


Accession

Unstimulated
ID NO: 1-


Number
Gene
Cells
treated:control













AC004908
Unknown
32.4
0.09


S70622
G1 phase-specific gene
43.1
0.10


Z97056
DEAD/H box polypeptide
12.8
0.11


AK002056
hypothetical protein
11.4
0.12


L33930
CD24 antigen
28.7
0.13


X77584
thioredoxin
11.7
0.13


NM_014106
PRO1914 protein
25.0
0.14


M37583
H2A histone family member
22.2
0.14


U89387
polymerase (RNA) II
10.2
0.14



polypeptide D


D25274
ras-related C3 botulinum
10.3
0.15



toxin substrate 1


J04173
phosphoglycerate mutase 1
11.4
0.15


U19765
zinc finger protein 9
8.9
0.16


X67951
proliferation-associated
14.1
0.16



gene A


AL096719
profilin 2
20.0
0.16


AF165217
tropomodulin 4
14.6
0.16


NM_014341
mitochondrial carrier
11.1
0.16



homolog 1


AL022068
Unknown
73.6
0.17


X69150
ribosomal protein S18
42.8
0.17


AL031577
Unknown
35.0
0.17


AL031281
Unknown
8.9
0.17


AF090094
Human mRNA for ornithine
10.3
0.17



decarboxylase antizyme,


AL022723
HLA-G histocompatibility
20.6
0.18



antigen, class I, G


U09813
ATP synthase, H+
9.8
0.18



transporting mitochondrial



F0 complex


AF000560
Homo sapiens TTF-I
20.2
0.19



interacting peptide 20


NM_016094
HSPC042 protein
67.2
0.19


AF047183
NADH dehydrogenase
7.5
0.19


D14662
anti-oxidant protein 2
8.1
0.19



(non-selenium glutathione



peroxidase, acidic calcium-



independent phospholipas


X16662
annexin A8
8.5
0.19


U14588
paxillin
11.3
0.19


AL117654
DKFZP586D0624 protein
12.6
0.20


AK001962
hypothetical protein
7.7
0.20


L41559
6-pyruvoyl-tetrahydropterin
9.1
0.20



synthase/dimerization



cofactor of hepatocyte



nuclear factor 1 alpha


NM_016139
16.7Kd protein
21.0
0.21


NM_016080
CGI-150 protein
10.7
0.21


U86782
26S proteasome-associated
6.7
0.21



pad1 homolog


AJ400717
tumor protein,
9.8
0.21



translationally-



controlled 1


X07495
homeo box C4
31.0
0.21


AL034410
Unknown
7.3
0.22


X14787
thrombospondin 1
26.2
0.22


AF081192
purine-rich element
6.8
0.22



binding protein B


D49489
protein disulfide isomerase-
11.0
0.22



related protein


NM_014051
PTD011 protein
9.3
0.22


AK001536
Unknown
98.0
0.22


X62534
high-mobility group
9.5
0.22



protein 2


AJ005259
endothelial differentiation-
6.7
0.22



related factor 1


NM_000120
epoxide hydrolase 1,
10.0
0.22



microsomal


M38591
S100 calcium-binding
23.9
0.23



protein A10


AF071596
immediate early response 3
11.5
0.23


X16396
methylene tetrahydrofolate
8.3
0.23



dehydrogenase


AK000934
ATPase inhibitor precursor
7.6
0.23


AL117612
Unknown
10.7
0.23


AP119043
transcriptional intermediary
7.3
0.23



factor 1 gamma


AF037066
solute carrier family 22
7.6
0.23



member 1-like antisense


AF134406
cytochrome c oxidase
13.3
0.23



subunit


AE000661
Unknown
9.2
0.24


AL157424
synaptojanin 2
7.2
0.24


X56468
tyrosine 3-monooxygenase/
7.2
0.24



tryptophan 5-monooxygenase



activation protein,


U39318
ubiquitin-conjugating
10.7
0.24



enzyme E2D 3


AL034348
Unknown
24.4
0.24


D26600
proteasome subunit beta
11.4
0.24



type 4


AB032987
Unknown
16.7
0.24


J04182
lysosomal-associated
7.4
0.24



membrane protein 1


X78925
zinc finger protein 267
16.1
0.25


NM_000805
gastrin
38.1
0.25


U29700
anti-Mullerian hormone
12.0
0.25



receptor, type II


Z98200
Unknown
13.4
0.25


U07857
signal recognition particle
10.3
0.25


L05096
Homo sapiens ribosomal
25.3
0.25



protein L39


AK001443
hypothetical protein
7.5
0.25


K03515
glucose phosphate isomerase
6.2
0.25


X57352
interferon induced
7.5
0.26



transmembrane protein 3


J02883
colipase pancreatic
5.7
0.26


M24069
cold shock domain protein
6.3
0.26


AJ269537
chondroitin-4-
60.5
0.26



sulfotransferase


AL137555
Unknown
8.5
0.26


U89505
RNA binding motif
5.5
0.26



protein 4


U82938
CD27-binding protein
7.5
0.26


X99584
SMT3 homolog 1
12.8
0.26


AK000847
Unknown
35.8
0.27


NM_014463
Lsm3 protein
7.8
0.27


AL133645
Unknown
50.8
0.27


X78924
zinc finger protein 266
13.6
0.27


NM_004304
anaplastic lymphoma kinase
15.0
0.27


X57958
ribosomal protein L7
27.9
0.27


U63542
Unknown
12.3
0.27


AK000086
hypothetical protein
8.3
0.27


X57138
H2A histone family member N
32.0
0.27


AB023206
KIAA0989 protein
6.5
0.27


AB021641
gonadotropin inducible
5.5
0.28



transcriptn represser-1,


AF050639
NADH dehydrogenase
5.5
0.28


M62505
complement component 5
7.5
0.28



receptor 1


X64364
basigin
5.8
0.28


AJ224082
Unknown
22.5
0.28


AF042165
cytochrome c oxidase
20.4
0.28


AK001472
anillin
10.9
0.28


X86428
protein phosphatase
12.7
0.28



2A subunit


AF227132
candidate taste
5.1
0.28



receptor T2R5


Z98751
Unknown
5.3
0.28


D21260
clathrin heavy polypeptide
8.3
0.28


AF041474
actin-like 6
15.1
0.28


NM_005258
GTP cyclohydrolase I protein
7.6
0.28


L20859
solute carrier family 20
9.6
0.29


Z80783
H2B histone family member
9.0
0.29


AB011105
laminin alpha 5
7.1
0.29


AL008726
protective protein for
5.2
0.29



beta-galactosidase


D29012
proteasome subunit
12.6
0.29


X63629
cadherin 3 P-cadherin
6.8
0.29


X02419
plasminogen activator
12.9
0.29



urokinase


X13238
cytochrome c oxidase
8.0
0.29


X59798
cyclin D1
12.7
0.30


D78151
proteasome 26S subunit
7.6
0.31


AF054185
proteasome subunit
18.8
0.31


J03890
surfactant pulmonary-
5.5
0.32



associated protein C


M34079
proteasome 26S subunit,
5.2
0.33
















TABLE 31







Up-regulation of Polynucleotide expression in A549 cells induced by Formula A Peptides.


The peptides at a concentration of 50 μg/ml were shown to increase the


expression of many polynucleotides. Peptide was incubated with the human A549


epithelial cells for 4 h and the RNA was isolated, converted into labeled cDNA probes


and hybridized to Human Operon arrays (PRHU04). The intensity of polynucleotides in


control, unstimulated cells are shown in the second and third columns for labeling of


cDNA with the dyes Cy3 and Cy5 respectively. The “ID#: Control” columns refer to the


intensity of polynucleotide expression in peptide-simulated cells divided by the intensity


of unstimulated cells.
















Accession

control-
control-
ID 5:
ID 6:
ID 7:
ID 8:
ID 9:
ID 10:


Number
Gene
Cy3
Cy5
control
control
control
control
control
control



















U12472
glutathione S-
0.09
0.31
13.0
3.5
4.5
7.0
4.3
16.4



transferase


X66403
cholinergic
0.17
0.19
7.8
9.9
6.0
6.4
5.0
15.7



receptor


AK001932
unknown
0.11
0.25
19.4
4.6
9.9
7.6
8.1
14.5


X58079
S100 calcium-
0.14
0.24
12.2
7.6
8.1
4.3
4.5
13.2



binding protein


U18244
solute carrier
0.19
0.20
6.1
9.7
11.9
5.0
3.7
10.6



family 1


U20648
zinc finger
0.16
0.13
5.3
6.2
5.6
3.1
6.8
9.5



protein


AB037832
unknown
0.10
0.29
9.0
4.2
9.4
3.1
2.6
8.7


AC002542
unknown
0.15
0.07
10.5
15.7
7.8
10.1
11.7
8.2


M89796
membrane-
0.15
0.14
2.6
6.1
7.6
3.5
13.3
8.1



spanning 4-



domains,



subfamily A


AF042163
cytochrome c
0.09
0.19
3.9
3.2
7.6
6.3
4.9
7.9



oxidase


AL032821
Vanin 2
0.41
0.23
2.5
5.2
3.2
2.1
4.0
7.9


U25341
melatonin
0.04
0.24
33.1
5.1
23.3
6.6
4.1
7.6



receptor 1B


U52219
G protein-
0.28
0.20
2.1
6.2
6.9
2.4
3.9
7.1



coupled receptor


X04506
apolipoprotein B
0.29
0.32
7.9
3.4
3.3
4.8
2.6
7.0


AB011138
ATPase type IV
0.12
0.07
3.5
12.9
6.6
6.4
21.3
6.9


AF055018
unknown
0.28
0.22
3.8
6.9
5.0
2.3
3.1
6.8


AK002037
hypothetical
0.08
0.08
2.9
7.9
14.1
7.9
20.1
6.5



protein


AK001024
guanine
0.16
0.11
7.7
11.9
5.0
10.3
6.0
6.3



nucleotide-



binding protein


AF240467
TLR-7
0.11
0.10
20.4
9.0
3.4
9.4
12.9
6.1


AF105367
glucagon-like
0.15
0.35
23.2
2.6
3.0
10.6
2.9
5.7



peptide 2



receptor


AL009183
TNFR
0.46
0.19
10.6
4.7
3.7
2.8
6.5
5.7



superfamily,



member 9


X54380
pregnancy-zone
0.23
0.08
4.7
11.9
7.2
12.7
3.8
5.5



protein


AL137736
unknown
0.22
0.15
2.1
7.2
3.3
7.1
4.6
5.5


X05615
thyroglobulin
0.28
0.42
6.3
2.7
7.7
2.4
3.1
5.4


D28114
myelin-
0.24
0.08
2.5
15.9
13.0
7.1
13.7
5.4



associated



protein


AK000358
microfibrillar-
0.28
0.28
8.7
4.2
7.2
3.2
2.4
5.3



associated



protein 3


AK001351
unknown
0.12
0.22
3.9
7.6
8.7
3.9
2.3
5.2


U79289
unknown
0.14
0.27
2.5
2.7
2.8
2.0
4.3
5.1


AB014546
ring finger
0.12
0.34
6.8
2.4
4.1
2.7
2.0
5.0



protein


AL117428
DKFZP434A236
0.10
0.07
2.8
16.1
12.8
9.7
14.2
4.9



protein


AL050378
unknown
0.41
0.14
3.5
8.7
11.7
3.5
7.0
4.9


AJ250562
transmembrane
0.13
0.10
5.2
5.7
14.2
3.8
10.3
4.8



4 superfamily



member 2


NM_001756
corticosteroid
0.28
0.13
4.0
7.9
6.5
14.9
5.6
4.8



binding globulin


AL137471
hypothetical
0.29
0.05
3.7
18.0
6.2
7.2
16.3
4.7



protein


M19684
protease
0.41
0.14
3.5
4.6
5.4
2.8
9.4
4.7



inhibitor 1


NM_001963
epidermal
0.57
0.05
3.4
6.2
1.8
32.9
14.7
4.4



growth factor


NM_000910
neuropeptide Y
0.62
0.36
3.1
2.7
2.3
2.6
3.1
4.4



receptor


AF022212
Rho GTPase
0.19
0.02
9.0
45.7
25.6
12.4
72.2
4.4



activating



protein 6


AK001674
cofactor required
0.11
0.13
8.4
6.5
7.9
4.5
7.4
4.3



for Sp1


U51920
signal
0.23
0.27
3.4
3.8
2.1
4.1
8.8
4.2



recognition



particle


AK000576
hypothetical
0.27
0.06
4.4
14.7
7.4
14.1
8.6
4.2



protein


AL080073
unknown
0.17
0.20
21.6
3.9
4.3
8.8
2.6
4.1


U59628
paired box gene 9
0.34
0.06
3.4
14.1
5.4
7.9
4.9
4.1


U90548
butyrophilin,
0.41
0.31
2.3
4.7
5.5
6.8
3.4
4.1



subfamily 3,



member A3


M19673
cystatin SA
0.43
0.26
2.3
8.5
4.5
2.5
4.1
3.8


AL161972
ICAM 2
0.44
0.37
2.0
3.6
2.0
2.7
5.5
3.8


X54938
inositol 1,4,5-
0.32
0.22
3.9
3.3
6.2
3.1
4.4
3.7



trisphosphate 3-



kinase A


AB014575
KIAA0675 gene
0.04
0.13
46.2
4.5
10.2
8.0
6.2
3.4



product


M83664
MHC II, DP beta 1
0.57
0.29
2.9
2.1
2.0
3.1
6.6
3.4


AK000043
hypothetical
0.34
0.14
2.7
7.1
3.7
9.4
8.8
3.3



protein


U60666
testis specific
0.21
0.11
9.9
9.0
4.1
5.5
13.0
3.3



leucine rich



repeat protein


AK000337
hypothetical
0.49
0.19
4.3
5.1
4.7
10.6
7.1
3.3



protein


AF050198
putative
0.34
0.15
7.0
6.3
3.6
5.6
11.9
3.3



mitochondrial



space protein


AJ251029
odorant-binding
0.28
0.12
4.4
9.4
7.2
8.8
7.1
3.2



protein 2A


X74142
forkhead box
0.12
0.33
19.5
4.5
8.4
6.4
4.4
3.2



G1B


AB029033
KIAA1110
0.35
0.24
3.1
2.2
5.6
5.2
3.1
3.1



protein


D85606
cholecystokinin
0.51
0.14
4.3
3.9
4.6
3.5
7.2
3.1



A receptor


X84195
acylphosphatase
0.32
0.19
4.8
3.7
5.0
11.2
9.8
3.0



2 muscle type


U57971
ATPase Ca++
0.29
0.13
2.2
7.9
1.8
6.3
4.8
3.0



transporting



plasma



membrane 3


J02611
apolipoprotein D
0.28
0.10
2.8
11.0
3.7
10.3
8.4
3.0


AF071510
lecithin retinol
0.07
0.05
7.9
3.8
11.7
46.0
16.3
3.0



acyltransferase


AF131757
unknown
0.10
0.08
4.8
9.0
44.3
9.3
10.7
3.0


L10717
IL2-inducible T-
0.45
0.21
2.5
4.9
2.8
10.9
4.5
2.9



cell kinase


L32961
4-aminobutyrate
0.64
0.32
3.6
2.9
3.2
5.3
2.3
2.9



aminotransferase


NM_003631
poly (ADP-
0.46
0.41
9.7
3.9
4.1
3.8
2.8
2.7



ribose)



glycohydrolase


AF098484
pronapsin A
0.28
0.14
3.7
3.7
5.6
11.6
3.7
2.5


NM_009589
arylsulfatase D
0.73
0.16
3.2
5.6
6.0
48.6
7.2
2.4


M14764
TNFR
0.49
0.15
2.3
3.5
10.6
13.6
6.8
2.2



superfamily,



member 16


AL035250
endothelin 3
0.52
0.14
2.1
7.3
4.8
4.5
3.7
2.2


M97925
defensin, alpha
0.33
0.07
4.0
14.7
7.8
9.4
3.5
2.1



5, Paneth cell-



specific


D43945
transcription
0.46
0.19
6.6
2.9
8.2
4.0
3.5
2.1



factor EC


D16583
histidine
0.46
0.09
3.2
13.8
4.2
8.8
13.7
2.1



decarboxylase
















TABLE 32







Up-regulation of Polynucleotide expression in A549 cells induced by Formula B Peptides.


The peptides at a concentration of 50 μg/ml were shown to increase the expression


of many polynucleotides. Peptide was incubated with the human A549 epithelial cells


for 4 h and the RNA was isolated, converted into labeled cDNA probes and hybridized to


Human Operon arrays (PRHU04). The intensity of polynucleotides in control, unstimulated


cells are shown in the second and third columns for labeling of cDNA with the dyes Cy3


and Cy5 respectively. The “ID#: Control” columns refer to the intensity


of polynucleotide expression in peptide-simulated cells divided by the intensity of


unstimulated cells.
















Accession

control-
control-
ID 12:
ID 13:
ID 14:
ID 15:
ID 16:
ID 17:


Number
Gene
Cy3
Cy5
control
control
control
control
control
control



















AL157466
unknown
0.05
0.06
18.0
21.4
16.7
5.2
6.8
8.6


AB023215
KIAA0998 protein
0.19
0.07
14.8
10.6
7.9
14.4
6.6
16.1


AL031121
unknown
0.24
0.09
14.1
5.7
3.8
5.5
2.8
4.6


NM_016331
zinc finger protein
0.16
0.08
12.8
7.2
11.0
5.3
11.2
9.7


M14565
cytochrome P450
0.16
0.12
10.6
12.5
5.0
3.6
10.1
6.3


U22492
G protein-coupled receptor 8
0.28
0.07
10.4
8.9
4.8
10.8
6.6
3.6


U76010
solute carrier family 30
0.14
0.07
9.7
18.6
3.7
4.8
5.6
8.9


AK000685
unknown
0.51
0.10
9.0
3.1
2.8
3.9
15.3
3.0


AF013620
Immunoglobulin heavy variable 4-4
0.19
0.18
8.5
2.6
6.2
5.7
8.2
3.8


AL049296
unknown
0.61
0.89
8.1
3.2
2.7
3.2
2.7
2.0


AB006622
KIAA0284 protein
0.47
0.28
7.5
5.0
2.8
11.1
5.5
4.6


X04391
CD5 antigen
0.22
0.13
7.2
16.7
2.7
7.7
6.1
5.9


AK000067
hypothetical protein
0.80
0.35
7.1
4.6
2.1
3.2
8.5
2.2


AF053712
TNF superfamily_member 11
0.17
0.08
6.9
17.7
3.0
6.2
12.3
5.2


X58079
S100 calcium-binding protein A1
0.14
0.24
6.7
6.7
5.9
6.5
5.3
2.5


M91036
hemoglobin_gamma A
0.48
0.36
6.7
14.2
2.1
2.9
2.7
4.8


AF055018
unknown
0.28
0.22
6.3
10.7
2.7
2.6
4.6
6.5


L17325
pre-T/NK cell associated protein
0.19
0.29
6.1
4.4
6.5
4.7
4.0
4.0


D45399
phosphodiesterase
0.21
0.18
6.1
4.6
5.0
2.8
10.8
4.0


AB023188
KIAA0971 protein
0.29
0.13
5.9
10.6
3.6
3.4
10.6
7.2


NM_012177
F-box protein
0.26
0.31
5.9
5.5
3.8
2.8
3.0
6.8


D38550
E2F TF 3
0.43
0.39
5.8
3.4
2.1
4.5
2.5
2.4


AL050219
unknown
0.26
0.04
5.7
17.0
3.1
9.2
30.3
16.1


AL137540
unknown
0.67
0.79
5.5
3.2
3.9
10.9
2.9
2.3


D50926
KIAA0136 protein
0.57
0.21
5,4
5.6
2.0
3.3
4.4
3.2


AL137658
unknown
0.31
0.07
5.4
12.1
2.6
10.8
3.9
8.6


U21931
fructose-bisphosphatase 1
0.48
0.14
5.4
4.1
2.9
3.6
6.0
3.2


AK001230
DKFZP586D211 protein
0.43
0.26
5.0
4.6
2.1
2.2
2.5
2.7


AL137728
unknown
0.67
0.47
5.0
5.9
2.2
6.8
5.9
2.1


AB022847
unknown
0.39
0.24
4.5
2.2
3.5
4.3
3.8
3.7


X75311
mevalonate kinase
0.67
0.22
4.3
4.0
2.0
8.3
4.0
5.1


AK000946
DKFZP566C243 protein
0.36
0.29
4.1
3.8
3.9
5.4
25.8
2.7


AB023197
KIAA0980 protein
0.25
0.30
4.0
8.3
2.1
8.8
2.2
4.9


AB014615
fibroblast growth factor 8
0.19
0.07
3.9
3.3
7.0
3.4
2.2
7.7


X04014
unknown
0.29
0.16
3.8
2.5
2.2
3.0
5.5
3.1


U76368
solute carrier family 7
0.46
0.17
3.8
3.8
2.8
3.2
4.2
3.0


AB032436
unknown
0.14
0.21
3.8
2.7
6.1
3.2
4.5
2.6


AB020683
KIAA0876 protein
0.37
0.21
3.7
4.2
2.2
5.3
2.9
9.4


NM_012126
carbohydrate sulfotransferase 5
0.31
0.20
3.7
5.2
3.2
3.4
3.9
2.5


AK002037
hypothetical protein
0.08
0.08
3.7
17.1
4.6
12.3
11.0
8.7


X78712
glycerol kinase pseudogene 2
0.17
0.19
3.6
2.5
4.5
5.3
2.2
3.3


NM_014178
HSPC156 protein
0.23
0.12
3.5
8.4
2.9
6.9
14.4
5.5


AC004079
homeo box A2
0.31
0.11
3.5
7.0
2.1
2.0
7.3
9.1


AL080182
unknown
0.51
0.21
3.4
3.5
2.2
2.1
2.9
2.4


M91036
hemoglobin gamma G
0.22
0.02
3.4
26.3
5.8
6.8
30.4
21.6


AJ000512
serum/glucocorticoid regulated
0.27
0.43
3.3
2.1
4.9
2.3
3.9
2.7



kinase


AK002140
hypothetical protein
0.28
0.14
3.3
9.9
2.8
2.1
16.6
7.2


AL137284
unknown
0.22
0.04
3.3
7.2
4.1
6.0
12.2
3.7


Z11898
POU domain_class 5 TF 1
0.12
0.29
3.2
3.7
8.2
2.5
6.6
2.2


AB017016
brain-specific protein
0.27
0.29
3.1
2.8
2.5
2.8
3.3
5.5


X54673
Solute-carrier family 6
0.34
0.08
2.9
12.0
2.2
10.4
7.4
5.9


AL033377
unknown
0.40
0.22
2.6
2.6
2.6
2.3
4.5
2.2


X85740
CCR4
0.34
0.05
2.6
2.3
2.6
2.5
12.5
5.2


AB010419
core-binding factor
0.59
0.20
2.5
12.8
2.0
2.8
2.9
5.9


AL109726
uknown
0.14
0.15
2.3
9.0
4.3
4.4
2.6
3.7


NM_012450
sulfate transporter 1
0.15
0.10
2.2
3.1
8.2
9.9
4.7
5.9


J04599
biglycan
0.39
0.30
2.1
3.3
6.6
2.2
2.7
5.4


AK000266
hypothetical protein
0.49
0.35
2.1
3.5
3.5
6.6
4.3
4.0
















TABLE 33







Up-regulation of Polynucleotide expression in A549 cells induced by Formula C Peptides.


The peptides at a concentration of 50 μg/ml were shown to increase the expression of


many polynucleotides. Peptide was incubated with the human A549 epithelial cells for


4 h and the RNA was isolated, converted into labeled cDNA probes and hybridized to


Human Operon arrays (PRHU04). The intensity of polynucleotides in control, unstimulated


cells are shown in the second and third columns for labeling of cDNA with the dyes Cy3


and Cy5 respectively. The “ID#: Control” columns refer to the intensity


of polynucleotide expression in peptide-simulated cells divided by the intensity of


unstimulated cells.
















Accession

control-
control-
ID 19:
ID 20:
ID 21:
ID 22:
ID 23:
ID 24:


Number
Gene
Cy3
Cy5
control
control
control
control
control
control



















NM_014139
sodium channel voltage-gated,
0.04
0.05
31.6
25.2
18.0
9.7
22.2
11.2


X84003
TATA box binding protein
0.47
0.07
31.8
12.7
2.5
2.8
18.0
14.2


AF144412
lens epithelial cell protein
0.25
0.07
23.9
8.0
6.8
3.4
16.2
3.5


AL080107
unknown
0.11
0.06
17.8
34.4
12.4
6.2
5.4
7.9


AF052116
unknown
0.34
0.07
15.5
3.9
9.2
3.0
6.9
2.7


AB033063
unknown
0.46
0.13
15.2
10.3
4.0
2.6
7.2
11.2


AK000258
hypothetical protein
0.27
0.07
13.9
8.0
3.5
3.4
26.5
11.5


NM_006963
zinc finger protein
0.10
0.08
12.8
6.8
6.2
5.9
17.2
1241.2


NM_014099
PRO1768 protein
0.30
0.06
12.3
17.4
5.4
5.4
19.5
3.4


AK000996
hypothetical protein
0.17
0.07
10.0
8.0
9.7
7.4
20.7
16.3


M81933
cell division cycle 25A
0.13
0.21
8.8
7.8
19.6
15.6
4.8
3.8


AF181286
unknown
0.05
0.22
8.8
2.7
12.0
35.6
5.9
2.3


AJ272208
IL-1R accessory protein-like 2
0.22
0.17
8.8
2.9
5.0
3.2
9.8
7.3


AF030555
fatty-acid-Coenzyme A ligase
0.10
0.39
8.7
2.2
11.3
9.9
3.0
2.1


AL050125
unknown
0.23
0.07
8.6
14.3
5.2
2.8
18.7
8.3


AB011096
KIAA0524 protein
0.21
0.08
8.5
24.4
4.7
6.8
10.4
7.5


J03068
N-acylaminoacyl-peptide hydrolase
0.54
0.21
8.3
2.4
2.2
4.1
3.0
6.0


M33906
MHC class II, DQ alpha 1
0.14
0.08
7.6
4.5
15.2
6.1
7.5
7.9


AJ272265
secreted phosphoprotein
0.21
0.09
7.6
9.0
3.3
4.9
18.8
14.5


J00210
interferon alpha 13
0.41
0.07
7.2
15.0
2.8
3.1
11.0
4.3


AK001952
hypothetical protein
0.42
0.21
6.9
4.9
2.5
3.1
7.6
4.5


X54131
protein tyrosine phosphatase,
0.09
0.20
6.4
6.5
7.7
15.0
5.6
4.1



receptor type,


AF064493
LIM binding domain 2
0.46
0.14
5.9
5.6
2.2
2.9
8.5
5.8


AL117567
DKFZP566O084 protein
0.44
0.22
5.8
3.3
2.9
2.3
5.7
14.9


L40933
phosphoglucomutase 5
0.16
0.03
5.6
11.0
4.8
3.5
8.5
76.3


M27190
regenerating islet-derived 1 alpha
0.19
0.28
5.3
3.0
3.8
3.6
5.8
3.6


AL031121
unknown
0.24
0.09
5.3
3.8
3.2
3.9
3.0
27.9


U27655
regulator of G-protein signalling
0.24
0.29
5.0
9.0
4.5
8.3
4.2
4.5


AB037786
unknown
0.12
0.03
4.7
54.1
2.8
2.3
2.2
11.0


X73113
myosin-binding protein C
0.29
0.13
4.7
6.5
6.0
2.4
6.7
6.3


AB010962
matrix metalloproteinase
0.08
0.12
4.7
6.2
2.4
4.7
10.9
4.2


AL096729
unknown
0.36
0.13
4.7
7.7
3.2
2.4
6.3
6.2


AB018320
Arg/Abl-interacting protein
0.16
0.18
4.6
7.1
3.0
3.3
5.8
8.9


AK001024
guanine nucleotide-binding protein
0.16
0.11
4.6
2.0
9.8
2.6
7.6
14.1


AJ275355
unknown
0.15
0.08
4.6
17.3
5.4
9.2
5.1
5.5


U21931
fructose-bisphosphatase 1
0.48
0.14
4.6
4.3
2.6
2.1
8.4
9.6


X66403
cholinergic receptor
0.17
0.19
4.4
9.0
10.9
9.3
5.1
6.7


X67734
contactin 2
0.25
0.09
4.3
6.8
3.1
5.8
7.9
8.4


U92981
unknown
0.20
0.23
4.3
3.2
4.8
5.6
5.4
6.3


X68879
empty spiracles homolog 1
0.05
0.08
4.3
2.0
12.3
2.7
5.6
4.7


AL137362
unknown
0.22
0.22
4.2
4.1
2.7
4.1
9.3
4.2


NM_001756
corticosteroid binding globulin
0.28
0.13
4.1
10.6
3.9
2.7
10.3
5.5


U80770
unknown
0.31
0.14
4.1
4.1
23.3
2.7
7.0
10.1


AL109792
unknown
0.16
0.19
4.0
4.5
4.3
8.8
8.7
3.9


X65962
cytochrome P-450
0.33
0.05
3.8
25.3
5.7
5.1
19.8
12.0


AK001856
unknown
0.40
0.21
3.8
7.0
2.6
3.1
2.9
7.8


AL022723
MHC, class I, F
0.55
0.18
3.7
5.7
4.4
2.3
3.3
5.2


D38449
putative G protein coupled receptor
0.18
0.09
3.5
11.1
13.3
5.8
4.8
5.2


AL137489
unknown
0.74
0.26
3.3
2.9
2.6
3.3
2.5
5.4


AB000887
small inducible cytokine subfamily A
0.76
0.18
3.3
5.0
2.6
2.4
5.9
10.3


NM_012450
sulfate transporter 1
0.15
0.10
3.3
9.0
10.0
10.9
4.6
8.7


U86529
glutathione S-transferase zeta 1
0.55
0.15
3.2
6.8
4.4
2.3
9.3
5.1


AK001244
unknown
0.79
0.31
3.2
5.5
2.3
2.3
3.9
2.8


AL133602
unknown
0.16
0.21
3.1
7.8
8.7
2.6
4.1
5.6


AB033080
cell cycle progression 8 protein
0.31
0.31
3.1
4.6
3.0
3.5
2.2
4.2


AF023466
putative glycine-N-acyltransferase
0.27
0.18
3.1
5.0
4.2
7.4
10.1
3.8


AL117457
cofilin 2
0.68
0.53
3.0
4.6
3.3
2.4
7.4
3.4


AC007059
unknown
0.37
0.35
3.0
5.7
3.1
2.4
2.6
2.4


U60179
growth hormone receptor
0.34
0.21
2.9
3.5
2.3
3.1
8.0
4.7


M37238
phospholipase C, gamma 2
0.60
0.36
2.9
2.0
3.2
2.1
2.9
4.6


L22569
cathepsin B
0.32
0.12
2.9
2.1
6.2
3.0
13.1
16.7


M80359
MAP/microtubule affinity-regulating
0.37
0.76
2.9
3.1
6.1
7.6
2.1
3.3



kinase 3


S70348
Integrin beta 3
0.58
0.31
2.6
4.8
4.1
2.6
2.6
2.6


L13720
growth arrest-specific 6
0.36
0.26
2.4
2.5
6.8
4.8
3.9
3.7


AL049423
unknown
0.33
0.30
2.4
3.7
3.8
2.8
2.9
3.4


AL050201
unknown
0.68
0.29
2.2
3.1
3.7.
3.0
3.0
2.2


AF050078
growth arrest specific 11
0.87
0.33
2.1
8.4
2.5
2.2
2.6
4.4


AK001753
hypothetical protein
0.53
0.28
2.1
5.0
2.2
2.8
3.6
4.6


X05323
unknown
0.39
0.13
2.1
7.8
2.6
2.4
21.5
3.5


AB014548
KIAA0648 protein
0.61
0.30
2.0
2.4
4.8
3.4
4.9
3.9
















TABLE 34







Up-regulation of Polynucleotide expression in A549 cells induced by Formula D Peptides.


The peptides at a concentration of 50 μg/ml were shown to increase the expression


of many polynucleotides. Peptide was incubated with the human A549 epithelial cells


for 4 h and the RNA was isolated, converted into labeled cDNA probes and hybridized to


Human Operon arrays (PRHU04). The intensity of polynucleotides in control, unstimulated


cells are shown in the second and third columns for labeling of cDNA with the dyes Cy3


and Cy5 respectively. The “ID#: Control” columns refer to the intensity


of polynucleotide expression in peptide-simulated cells divided by the intensity of


unstimulated cells.
















Accession

control-
control-
ID 26:
ID 27:
ID 28:
ID 29:
ID 30:
ID 31:


Number
Gene
Cy3
Cy5
control
control
control
control
control
control



















U68018
MAD homolog 2
0.13
0.71
11.2
2.2
8.0
2.3
6.7
25.6


NM_016015
CGI-68 protein
0.92
1.59
2.3
2.3
3.5
3.7
3.4
22.9


AF071510
lecithin retinol acyltransferase
0.07
0.05
15.4
10.3
5.3
44.1
2.1
21.2


AC005154
unkown
0.17
1.13
2.7
7.2
12.6
6.4
3.3
20.6


M81933
cell division cycle 25A
0.13
0.21
4.3
3.1
3.2
4.3
5.6
18.2


AF124735
LIM HOX gene 2
0.17
0.21
2.1
4.4
5.9
5.2
7.6
17.0


AL110125
unknown
0.30
0.08
5.0
2.7
6.8
10.2
2.8
12.0


NM_004732
potassium voltage-gated channel
0.15
0.16
7.6
4.0
3.4
2.2
2.9
11.4


AF030555
fatty-acid-Coenzyme A
0.10
0.39
10.5
2.2
6.4
3.0
5.1
10.7



ligase_long-chain 4


AF000237
1-acylglycerol-3-phosphate
1.80
2.37
3.4
2.5
2.4
2.1
3.7
9.9



O-acyltransferase 2


AL031588
hypothetical protein
0.40
0.26
5.8
20.2
2.8
4.7
5.6
9.1


AL080077
unknown
0.15
0.21
2.4
2.0
11.9
3.8
2.3
8.7


NM_014366
putative nucleotide binding
0.90
2.52
2.4
4.3
2.4
2.6
3.0
8.6



protein_estradiol-induced


AB002359
phosphoribosylformylglycinamidine
0.81
2.12
3.2
2.7
5.5
2.5
2.8
6.9



synthase


U33547
MHC class II antigen HLA-DRB6 mRNA
0.14
0.16
2.5
5.3
4.5
5.0
3.1
6.6


AL133051
unknown
0.09
0.07
7.7
6.3
5.4
23.1
5.4
6.5


AK000576
hypothetical protein
0.27
0.06
7.1
9.3
5.0
6.9
2.9
6.2


AF042378
spindle pole body protein
0.36
0.39
3.3
3.0
9.5
4.5
3.4
6.2


AF093265
Homer neuronal immediate early
0.67
0.53
2.7
13.3
6.5
5.0
2.9
6.2



gene_3


D80000
Segregation of mitotic chromosomes
1.01
1.56
3.6
2.5
4.9
3.2
6.3
6.1



1


AF035309
proteasome 26S subunit ATPase 5
3.61
4.71
2.7
6.6
5.2
4.9
2.7
6.0



adaptor-related protein complex 2


M34175
beta 1 subunit
4.57
5.13
3.2
3.1
4.0
4.6
2.7
6.0


AB020659
KIAA0852 protein
0.18
0.37
4.1
7.6
5.7
4.8
2.5
5.7


NM_004862
LPS-induced TNF-alpha factor
2.61
3.36
3.8
4.8
4.1
4.9
3.2
5.6


U00115
zinc finger protein 51
0.51
0.07
18.9
2.2
3.5
7.2
21.2
5.6


AF088868
fibrousheathin II
0.45
0.20
4.7
10.0
3.2
6.4
6.0
5.6


AK001890
unknown
0.42
0.55
2.4
3.5
3.6
2.3
2.2
5.6


AL137268
KIAA0759 protein
0.49
0.34
3.8
2.3
5.0
3.5
3.3
5.4


X63563
polymerase II polypeptide B
1.25
1.68
2.5
8.1
3.4
4.8
5.2
5.4


D12676
CD36 antigen
0.35
0.39
2.9
3.4
2.6
2.2
3.5
5.3


AK000161
hypothetical protein
1.06
0.55
3.4
8.7
2.1
6.7
2.9
5.1


AF052138
unknown
0.64
0.51
2.9
2.8
2.7
5.2
3.6
5.0


AL096803
unknown
0.36
0.03
20.1
18.3
3.7
19.3
16.1
4.9


S49953
DNA-binding transcriptional activator
0.70
0.15
3.7
4.0
2.1
6.6
4.0
4.8


X89399
RAS p21 protein activator
0.25
0.10
8.5
14.9
4.8
18.6
4.3
4.8


AJ005273
antigenic determinant of recA protein
0.70
0.10
7.6
11.1
2.8
9.9
12.0
4.6


AK001154
hypothetical protein
1.70
0.96
2.4
4.4
2.9
8.9
2.4
4.5


AL133605
unknown
0.26
0.15
12.4
4.2
4.4
3.3
3.3
4.1


U71092
G protein-coupled receptor 24
0.53
0.06
19.0
9.1
2.2
12.0
3.3
4.1


AF074723
RNA polymerase II transcriptional
0.67
0.54
4.0
3.2
3.1
3.4
6.0
4.0



regulation mediator


AL137577
unknown
0.32
0.12
31.4
6.2
5.3
10.1
25.3
3.9


AF151043
hypothetical protein
0.48
0.35
2.6
2.2
2.0
3.3
2.2
3.8


AF131831
unknown
0.67
0.81
2.1
7.0
3.5
3.2
3.9
3.7


D50405
histone deacetylase 1
1.52
2.62
3.1
7.2
2.9
4.1
2.8
3.7


U78305
protein phosphatase 1D
1.21
0.20
4.7
13.0
3.5
5.9
4.2
3.7


AL035562
paired box gene 1
0.24
0.01
30.2
81.9
5.6
82.3
6.2
3.7


U67156
mitogen-activated protein kinase
1.15
0.30
6.6
3.0
2.2
2.3
2.5
3.6



kinase kinase 5


AL031121
unknown
0.24
0.09
5.2
3.7
2.3
6.5
9.1
3.6


U13666
G protein-coupled receptor 1
0.34
0.14
3.8
5.4
3.1
3.3
2.8
3.6


AB018285
KIAA0742 protein
0.53
0.13
14.9
13.9
5.9
18.5
15.2
3.5


D42053
site-1 protease
0.63
0.40
2.6
7.1
5.6
9.2
2.6
3.5


AK001135
Sec23-interacting protein p125
0.29
0.53
5.7
4.5
3.4
2.6
11.3
3.4


AL137461
unknown
0.25
0.02
23.8
9.0
2.7
59.2
12.5
3.3


NM_006963
zinc finger protein 22
0.10
0.08
3.2
7.6
3.7
7.9
11.2
3.2


AL137540
unknown
0.67
0.79
3.9
2.6
5.6
4.2
3.5
3.1


AL137718
unknown
0.95
0.18
4.7
8.0
4.0
13.3
3.0
3.1


AF012086
RAN binding protein 2-like 1
1.20
0.59
4.6
4.0
2.0
4.6
3.6
3.1


S57296
HER2/neureceptor
0.59
0.17
7.3
12.1
2.3
20.0
22.2
3.0


NM_013329
GC-rich sequence DNA-binding factor
0.16
0.08
6.9
14.3
9.7
3.3
7.2
3.0



candidate


AF038664
UDP-Gal:betaGlcN Ac beta 1_4-
0.15
0.03
13.4
22.2
5.4
15.8
1.7.6
3.0



galactosyltransferase


AF080579
Homo sapiens integral membrane protein
0.34
1.03
3.3
3.0
6.7
2.1
2.9
2.9


AK001075
hypothetical protein
0.67
0.10
2.1
2.6
2.6
8.9
2.2
2.9


AB011124
KIAA0552 gene product
0.46
0.04
9.6
72.0
6.0
33.9
13.6
2.9


J03068
N-acylaminoacyl-peptide hydrolase
0.54
0.21
2.2
5.0
2.4
5.2
3.6
2.8


D87120
osteoblast protein
0.87
0.87
2.2
2.0
4.7
2.3
2.0
2.8


AB006537
IL-1R accessory protein
0.17
0.07
2.9
7.0
14.5
5.3
6.6
2.8


L34587
transcription elongation factor B
2.49
1.23
2.2
16.3
5.0
15.8
5.5
2.7


D31891
SET domain_bifurcated_1
1.02
0.29
3.9
6.0
4.3
4.9
6.6
2.7


D00760
proteasome subunit_alpha type_2
4.97
4.94
4.1
2.6
2.0
2.8
2.7
2.7


AC004774
distal-less homeo box 5
0.25
0.12
2.3
6.3
3.8
5.2
5.2
2.6


AL024493
unknown
1.46
0.54
4.8
13.5
2.1
11.6
6.8
2.6


AB014536
copine III
1.80
1.29
3.2
9.5
3.8
6.8
2.6
2.6


X59770
IL-1R type II
0.59
0.16
9.6
4.7
3.9
3.2
4.9
2.5


AF052183
unknown
0.65
0.76
4.0
3.7
2.3
5.0
3.0
2.5


AK000541
hypothetical protein
0.92
0.27
4.5
13.9
3.6
18.1
4.3
2.5


U88528
cAMP responsive element binding
1.37
0.86
3.1
5.4
2.1
2.8
2.1
2.4



protein


M97925
defensin alpha 5_Paneth cell-specific
0.33
0.07
4.6
35.9
2.0
7.8
6.5
2.4


NM_013393
cell division protein FtsJ
1.38
0.94
3.1
5.8
2.1
4.2
2.6
2.3


X62744
MHC class II DM alpha
0.86
0.32
4.0
4.7
2.3
2.9
6.1
2.3


AF251040
putative nuclear protein
0.64
0.30
6.7
3.4
2.9
3.9
5.7
2.2


AK000227
hypothetical protein
1.49
0.43
3.4
7.1
2.3
3.3
9.1
2.1


U88666
SFRS protein kinase 2
1.78
0.37
3.4
5.9
2.6
8.4
6.1
2.0
















TABLE 35







Up-regulation of Polynucleotide expression in A549 cells induced by Formula E Peptides.


The peptides at a concentration of 50 μg/ml were shown to increase the expression


of many polynucleotides. Peptide was incubated with the human A549 epithelial cells


for 4 h and the RNA was isolated, converted into labeled cDNA probes and hybridized to


Human Operon arrays (PRHU04). The intensity of polynucleotides in control, unstimulated


cells are shown in the second and third columns for labeling of cDNA with the dyes Cy3


and Cy5 respectively. The “ID#: Control” columns refer to the intensity


of polynucleotide expression in peptide-simulated cells divided by the intensity of


unstimulated cells.
















Accession

control-
control-
ID 33:
ID 34:
ID 35:
ID 36:
ID 37:
ID 38:


Number
Gene
Cy3
Cy5
control
control
control
control
control
control



















AL049689
Novel human mRNA
0.25
0.05
2.7
26.5
3.3
21.7
5.4
37.9


AK000576
hypothetical protein
0.27
0.06
3.0
19.1
3.9
23.0
3.1
28.3


X74837
mannosidase, alpha class 1A member 1
0.10
0.07
5.6
10.0
10.8
12.3
12.0
19.9


AK000258
hypothetical protein
0.27
0.07
14.0
11.1
7.9
16.1
6.2
18.9


X89067
transient receptor
0.20
0.14
3.7
2.2
2.4
2.6
8.0
18.1


AL137619
unknown
0.16
0.08
6.3
6.7
10.8
10.5
7.9
16.5


NM_003445
zinc finger protein
0.17
0.07
4.0
23.6
2.9
13.6
4.3
14.4


X03084
complement component 1
0.36
0.15
2.4
3.1
2.9
7.7
3.4
13.7


U27330
fucosyltransferase 5
0.39
0.08
2.4
2.5
2.6
12.1
3.5
13.0


AF070549
unknown
0.16
0.09
2.7
4.7
7.9
10.3
4.2
12.6


AB020335
sel-1 -like
0.19
0.24
2.9
2.6
2.0
7.3
4.7
12.4


M26901
renin
0.09
0.12
14.9
2.2
7.3
12.0
20.8
12.0


Y07828
ring finger protein
0.09
0.06
9.0
26.6
8.9
16.0
3.6
11.6


AK001848
hypothetical protein
0.21
0.07
6.2
8.2
2.7
5.2
5.5
10.9


NM_016331
zinc finger protein
0.16
0.08
7.6
5.1
7.0
25.5
5.5
10.9


U75330
neural cell adhesion molecule 2
0.42
0.08
2.5
3.6
2.0
5.8
6.2
9.9


AB037826
unknown
0.16
0.11
3.8
6.0
3.4
13.4
6.0
9.8


M34041
adrenergic alpha-2B-receptor
0.30
0.13
4.5
4.5
3.7
8.6
5.6
9.8


D38449
putative G protein coupled receptor
0.18
0.09
2.3
25.8
11.7
2.3
3.2
9.5


AJ250562
transmembrane 4 superfamily member 2
0.13
0.10
10.0
8.4
2.2
8.1
16.3
9.1


AK001807
hypothetical protein
0.18
0.12
4.2
5.3
4.6
3.2
4.0
8.3


AL133051
unknown
0.09
0.07
5.1
13.6
6.0
9.1
2.2
8.2


U43843
Neuro-d4 homolog
0.61
0.10
2.0
6.4
2.3
16.6
2.2
8.1


NM_013227
aggrecan 1
0.28
0.15
7.5
3.1
2.5
6.9
8.5
7.8


AF226728
somatostatin receptor-interacting
0.23
0.17
7.0
3.6
3.1
5.5
3.5
7.7



protein


AK001024
guanine nucleotide-binding protein
0.16
0.11
3.9
12.3
2.7
7.4
3.3
7.0


AC002302
unknown
0.13
0.14
16.1
5.8
5.8
2.6
9.6
6.2


AB007958
unknown
0.17
0.27
2.0
2.3
11.3
3.3
3.0
6.1


AF059293
cytokine receptor-like factor 1
0.19
0.22
3.6
2.5
10.2
3.8
2.7
5.9


V01512
v-fos
0.27
0.21
6.7
3.7
13.7
9.3
3.7
5.4


U82762
sialyltransferase 8
0.23
0.15
3.2
6.5
2.7
9.2
5.7
5.4


U44059
thyrotrophic embryonic factor
0.05
0.13
22.9
7.1
12.5
7.4
9.7
5.4


X05323
antigen identified by monoclonal
0.39
0.13
4.3
2.5
2.2
7.4
2.8
5.1



antibody


U72671
ICAM 5,
0.25
0.14
5.3
2.7
3.7
10.0
3.2
4.8


AL133626
hypothetical protein
0.26
0.25
2.2
4.2
2.9
3.0
2.6
4.7


X96401
MAX binding protein
0.31
0.29
6.9
2.3
4.9
3.1
2.9
4.6


AL117533
unknown
0.05
0.26
8.2
2.7
11.1
2.5
11.9
4.5


AK001550
hypothetical protein
0.10
0.30
8.0
2.0
4.9
2.1
7.8
4.5


AB032436
Homo sapiens BNPI mRNA
0.14
0.21
5.1
2.2
9.1
4.5
6.4
4.4


AL035447
hypothetical protein
0.28
0.23
4.3
3.7
8.7
5.2
3.7
4.2


U09414
zinc finger protein
0.28
0.25
4.0
2.2
4.7
3.3
7.2
4.2


AK001256
unknown
0.09
0.08
5.3
6.5
31.1
12.7
6.4
4.1


L14813
carboxyl ester lipase-like
0.64
0.21
2.7
6.2
3.1
2.1
3.4
3.9


AF038181
unknowan
0.06
0.18
34.1
6.4
4.5
8.7
11.3
3.9


NM_001486
glucokinase
0.21
0.08
3.0
2.2
6.5
12.4
5.7
3.9


AB033000
hypothetical protein
0.24
0.22
3.4
3.3
7.1
5.5
4.5
3.8


AL117567
DKFZP566O084 protein
0.44
0.22
2.2
2.7
3.9
4.0
4.5
3.7


NM_012126
carbohydrate sulfotransferase 5
0.31
0.20
5.5
5.4
3.8
5.5
2.6
3.5


AL031687
unknown
0.16
0.27
5.9
2.6
3.4
2.3
4.9
3.5


X04506
apolipoprotein B
0.29
0.32
5.4
4.4
6.9
5.5
2.1
3.5


NM_006641
CCR 9
0.35
0.11
3.3
3.3
2.2
16.5
2.3
3.5


Y00970
acrosin
0.12
0.14
8.2
8.8
3.1
6.2
17.5
3.4


X67098
rTS beta protein
0.19
0.26
2.4
3.1
7.8
3.5
4.4
3.3


U51990
pre-mRNA splicing factor
0.56
0.19
2.2
3.0
2.8
13.7
2.9
3.0


AF030555
fatty-acid-Coenzyme A
0.10
0.39
3.5
6.9
13.3
4.4
7.5
2.9


AL009183
TNFR superfamily, member 9
0.46
0.19
6.0
4.1
2.8
8.6
2.6
2.8


AF045941
sciellin
0.16
0.21
11.6
2.4
2.8
2.2
4.1
2.8


AF072756
A kinase anchor protein 4
0.33
0.07
2.5
5.3
3.9
32.7
2.3
2.7


X78678
ketohexokinase
0.10
0.20
18.0
3.5
4.1
2.5
14.6
2.6


AL031734
unknown
0.03
0.39
43.7
2.3
41.7
4.0
10.8
2.5


D87717
KIAA0013 gene product
0.35
0.42
4.2
2.3
3.6
2.6
2.9
2.5


U01824
solute carrier family 1
0.42
0.29
4.8
2.3
4.2
7.1
4.2
2.4


AF055899
solute carrier family 27
0.14
0.31
9.5
12.3
7.4
4.7
6.6
2.3


U22526
lanosterol synthase
0.09
0.45
4.1
3.4
10.4
2.2
17.9
2.3


AB032963
unknown
0.19
0.34
6.3
6.1
2.9
2.1
5.7
2.2


NM_015974
lambda-crystallin
0.17
0.25
11.4
2.8
5.9
2.4
5.8
2.2


X82200
stimulated trans-acting factor
0.23
0.15
8.2
3.4
3.0
2.8
11.3
2.2


AL137522
unknown
0.12
0.26
12.1
3.7
12.6
6.9
4.3
2.2


Z99916
crystallin, beta B3
0.28
0.65
2.5
2.1
3.6
2.2
2.6
2.1


AF233442
ubiquitin specific protease 21
0.41
0.31
2.6
3.6
3.6
4.5
3.4
2.1


AK001927
hypothetical protein
0.24
0.52
7.6
5.6
5.0
2.5
4.1
2.0
















TABLE 36







Up-regulation of Polynucleotide expression in A549 cells induced by Formula F Peptides.


The peptides at a concentration of 50 μg/ml were shown to increase the expression of


many polynucleotides. Peptide was incubated with the human A549 epithelial cells for


4 h and the RNA was isolated, converted into labeled cDNA probes and hybridized to


Human Operon arrays (PRHU04). The intensity of polynucleotides in control, unstimulated


cells are shown in the second and third columns for labeling of cDNA with the dyes Cy3


and Cy5 respectively. The “Ratio ID#: Control” columns refer to the


intensity of polynucleotide expression in peptide-simulated cells divided by the intensity


of unstimulated cells.



















Ratio
Ratio
Ratio
Ratio
Ratio


Accession

control-
control-
ID 40:
ID 42:
ID 43:
ID 44:
ID 45:


Number
Gene
Cy3
Cy5
control
control
control
control
control


















AF025840
polymerase epsilon 2
0.34
0.96
3.4
2.0
2.0
2.1
4.3


AF132495
CGI-133 protein
0.83
0.67
3.0
2.2
2.6
2.8
5.1


AL137682
hypothetical protein
0.73
0.40
2.0
5.3
4.8
2.9
8.2


U70426
regulator of G-protein signalling 16
0.23
0.25
3.1
3.0
5.3
3.1
12.2


AK001135
Sec23-interacting protein p125
0.29
0.53
3.2
2.6
3.3
14.4
5.2


AB023155
KIAA0938 protein
0.47
0.21
2.7
4.8
8.1
4.2
10.4


AB033080
cell cycle progression 8 protein
0.31
0.31
4.4
2.2
5.9
4.3
6.9


AF061836
Ras association domain family 1
0.29
0.31
3.2
2.5
11.1
18.8
6.8


AK000298
hypothetical protein
0.48
0.27
3.3
2.2
7.1
5.6
7.7


L75847
zinc finger protein
0.35
0.52
3.2
3.0
4.0
3.0
3.9


X97267
protein tyrosine phosphatase
0.19
0.24
4.1
9.3
2.4
4.2
8.3


Z11933
POU domain class 3 TF 2
0.09
0.23
8.7
2.5
3.6
4.3
8.2


AB037744
unknown
0.37
0.57
2.6
2.9
2.7
3.0
3.1


U90908
unknown
0.12
0.16
11.8
7.7
3.4
7.8
11.2


AL050139
unknown
0.29
0.60
5.2
2.4
3.3
3.0
2.8


AB014615
fibroblast growth factor 8
0.19
0.07
5.4
3.5
8.5
3.2
22.7


M28825
CD1A antigen
0.51
0.36
4.1
2.6
2.0
4.6
4.4


U27330
fucosyltransferase 5
0.39
0.08
3.3
2.1
24.5
8.2
19.3


NM_006963
zinc finger protein
0.10
0.08
10.4
12.6
12.3
29.2
20.5


AF093670
peroxisomal biogenesis factor
0.44
0.53
4.0
2.6
2.6
4.3
2.9


AK000191
hypothetical protein
0.50
0.18
2.3
3.6
4.4
2.2
8.2


AB022847
unknown
0.39
0.24
2.1
6.9
4.5
2.8
6.2


AK000358
microfibrillar-associated protein 3
0.28
0.28
5.7
2.0
3.5
5.2
5.2


X74837
mannosidase_alpha class 1A
0.10
0.07
13.1
18.4
23.6
16.3
20.8


AF053712
TNF superfamily_member 11
0.17
0.08
11.3
9.3
13.4
10.6
16.6


AL133114
DKFZP586P2421 protein
0.11
0.32
8.5
3.4
4.9
5.3
4.3


AF049703
E74-like factor 5
0.22
0.24
5.1
6.0
3.3
2.7
5.4


AL137471
hypothetical protein
0.29
0.05
4.0
15.0
10.1
2.7
25.3


AL035397
unknown
0.33
0.14
2.3
2.8
10.6
4.6
9.3


AL035447
hypothetical protein
0.28
0.23
3.8
6.8
2.7
3.0
5.7


X55740
CD73
0.41
0.61
2.1
3.3
2.9
3.2
2.1


NM_004909
taxol resistance associated gene 3
0.20
0.22
3.9
2.9
6.5
3.2
5.6


AF233442
ubiquitin specific protease
0.41
0.31
2.9
4.7
2.7
3.5
3.9


U92980
unknown
0.83
0.38
4.2
4.1
4.8
2.3
3.1


AF105424
myosin heavy polypeptide-like
0.30
0.22
2.8
3.3
4.4
2.3
5.3


M26665
histatin 3
0.29
0.26
7.9
3.5
4.6
3.5
4.5


AF083898
neuro-oncological ventral antigen 2
0.20
0.34
18.7
3.8
2.2
3.6
3.5


AJ009771
ariadne_Drosophila_homolog of
0.33
0.06
2.3
17.6
15.9
2.5
20.3


AL022393
hypothetical protein P1
0.05
0.33
32.9
2.4
3.0
69.4
3.4


AF039400
chloride channel_calcium activated
0.11
0.19
8.4
2.9
5.1
18.1
5.9



family member 1


AJ012008
dimethylarginine dimethylaminohydrolase 2
0.42
0.43
5.1
3.3
3.2
6.2
2.6


AK000542
hypothetical protein
0.61
0.24
2.1
4.5
5.0
3.7
4.4


AL133654
unknown
0.27
0.40
2.8
2.1
2.5
2.5
2.6


AL137513
unknown
0.43
0.43
6.4
3.2
3.8
2.3
2.3


U05227
GTP-binding protein
0.38
0.36
5.0
3.1
3.1
2.2
2.8


D38449
putative G protein coupled receptor
0.18
0.09
5.8
6.7
6.7
9.1
10.4


U80770
unknown
0.31
0.14
3.9
3.8
6.6
3.1
6.8


X61177
IL-5R alpha
0.40
0.27
2.6
4.4
9.8
8.1
3.6


U35246
vacuolar protein sorting 45A
0.15
0.42
5.8
2.8
2.6
4.5
2.2


AB017016
brain-specific protein p25 alpha
0.27
0.29
6.0
2.6
3.4
3.1
3.1


X82153
cathepsin K
0.45
0.20
4.2
5.2
4.8
4.4
4.6


AC005162
probable carboxypeptidase precursor
0.12
0.28
11.9
3.4
6.8
18.7
3.2


AL137502
unknown
0.22
0.16
3.9
4.9
7.3
3.9
5.3


U66669
3-hydroxyisobutyryl-Coenzyme A hydrolase
0.30
0.40
10.3
3.5
5.2
2.3
2.1


AK000102
unknown
0.39
0.30
2.8
5.3
5.2
4.1
2.8


AF034970
docking protein 2
0.28
0.05
3.3
8.5
15.7
4.0
17.3


AK000534
hypothetical protein
0.13
0.29
6.8
2.3
4.0
20.6
2.9


J04599
biglycan
0.39
0.30
4.0
3.7
4.0
4.8
2.8


AL133612
unknown
0.62
0.33
2.7
3.4
5.2
3.0
2.5


D10495
protein kinase C delta
0.18
0.10
12.0
20.7
8.7
6.8
8.1


X58467
cytochrome P450
0.07
0.24
15.4
4.7
7.9
34.4
3.4


AF131806
unknown
0.31
0.25
2.6
3.4
5.7
7.0
3.2


AK000351
hypothetical protein
0.34
0.13
4.0
6.9
5.5
2.8
6.3


AF075050
hypothetical protein
0.55
0.09
2.7
17.8
5.1
2.2
8.3


AK000566
hypothetical protein unknown
0.15
0.35
6.7
2.2
6.8
6.4
2.1


U43328
cartilage linking protein 1
0.44
0.19
2.5
6.2
6.9
7.8
3.8


AF045941
sciellin
0.16
0.21
6.8
7.5
4.8
6.9
3.4


U27655
regulator of G-protein signalling 3
0.24
0.29
5.5
4.9
2.9
4.9
2.4


AK000058
hypothetical protein
0.25
0.15
5.0
9.7
16.4
2.7
4.5


AL035364
hypothetical protein
0.32
0.26
4.4
4.2
7.3
2.8
2.6


AK001864
unknown
0.40
0.25
3.7
3.7
4.6
3.2
2.6


AB015349
unknown
0.14
0.24
10.5
2.8
3.7
8.0
2.7


V00522
MHC class II DR beta 3
0.62
0.22
4.8
3.9
4.7
2.5
3.0


U75330
neural cell adhesion molecule 2
0.42
0.08
2.1
9.6
13.2
3.3
7.8


NM_007199
IL-1R-associated kinase M
0.15
0.25
8.7
7.8
8.6
16.1
2.5


D30742
calcium/calmodulin-dependent
0.28
0.09
6.2
28.7
7.4
2.4
6.8



protein kinase IV


X05978
cystatin A
0.63
0.17
2.7
4.8
9.4
2.2
3.6


AF240467
TLR-7
0.11
0.10
13.8
13.3
4.7
7.7
4.9
















TABLE 37







Up-regulation of Polynucleotide expression in A549 cells induced by


Formula G and additional Peptides.


The peptides at a concentration of 50 μg/ml were shown to increase the


expression of many polynucleotides. Peptide was incubated with the human A549


epithelial cells for 4 h and the RNA was isolated, converted into labelled cDNA probes


and hybridised to Human Operon arrays (PRHU04). The intensity of polynucleotides in


control, unstimulated cells are shown in the second and third columns for labelling of


cDNA with the dyes Cy3 and Cy5 respectively. The “Ratio ID#: Control” columns refer


to the intensity of polynucleotide expression in peptide-simulated cells divided by the


intensity of unstimulated cells. Accession numbers and gene designations are U00115,


zinc finger protein; M91036, hemoglobin gamma G; K000070, hypothetical protein;


AF055899, solute carrier family 27; AK001490, hypothetical protein; X97674, nuclear


receptor coactivator 2; AB022847, unknown; AJ275986, transcription factor; D10495,


protein kinase C, delta; L36642, EphA7; M31166, pentaxin-related gene; AF176012,


unknown; AF072756, A kinase anchor protein 4; NM_014439, IL-1 Superfamily z;


AJ271351, putative transcriptional regulator; AK000576, hypothetical protein;


AJ272265, secreted phosphoprotein 2; AL122038, hypothetical protein; AK000307,


hypothetical protein; AB029001, KIAA1078 protein; U62437, cholinergic receptor;


AF064854, unknown; AL031588, hypothetical protein; X89399, RAS p21 protein


activator; D45399, phosphodiesterase; AB037716, hypothetical protein; X79981,


cadherin 5; AF034208, RIG-like 7-1; AL133355, chromosome 21 open reading frame 53;


NM_016281, STE20-like kinase; AF023614, transmembrane activator and CAML


interactor; AF056717, ash2-like; AB029039, KIAA1116 protein; J03634, inhibin, beta A;


U80764, unknown; AB032963, unknown; X82835, sodium channel, voltage-gated, type


IX

















Accession
control-
control-
ID 53:
ID 54:
ID 47:
ID 48:
ID 49:
ID 50:
ID 51:
ID 52:


Number
Cy3
Cy5
control
control
control
control
control
control
control
control




















U00115
0.51
0.07
27.4
7.3
2.4
3.1
4.8
8.3
3.5
20.0


M91036
0.22
0.02
39.1
32.5
5.2
2.2
37.0
6.0
16.2
18.0


AK000070
0.36
0.18
3.8
7.6
2.6
15.1
12.2
9.9
17.2
15.3


AF055899
0.14
0.31
6.7
3.7
9.7
10.0
2.2
16.7
5.4
14.8


AK001490
0.05
0.02
14.1
35.8
3.2
28.6
25.0
20.2
56.5
14.1


X97674
0.28
0.28
3.2
3.7
4.0
10.7
3.3
3.1
4.0
13.2


AB022847
0.39
0.24
4.1
4.4
4.5
2.7
3.7
10.4
5.0
11.3


AJ275986
0.26
0.35
5.8
2.3
5.7
2.2
2.5
9.7
4.3
11.1


D10495
0.18
0.10
8.0
3.4
4.6
2.0
6.9
2.5
12.7
10.3


L36642
0.26
0.06
5.8
14.2
2.6
4.1
8.9
3.4
6.5
6.6


M31166
0.31
0.12
4.8
3.8
12.0
3.6
9.8
2.4
8.8
6.4


AF176012
0.45
0.26
3.1
2.9
2.8
2.6
2.3
6.9
3.0
5.8


AF072756
0.33
0.07
9.9
9.3
4.4
4.3
3.2
4.9
11.9
5.4


NM_014439
0.47
0.07
12.0
7.1
3.3
3.3
4.7
5.9
5.0
5.4


AJ271351
0.46
0.12
3.4
3.5
2.3
4.7
2.3
2.7
6.9
5.2


AK000576
0.27
0.06
7.4
15.7
2.9
4.7
9.0
2.4
8.2
5.1


AJ272265
0.21
0.09
6.2
7.9
2.3
3.7
10.3
4.5
4.6
4.7


AL122038
0.46
0.06
6.7
4.5
2.6
4.3
16.4
6.5
26.6
4.6


AK000307
0.23
0.09
3.7
4.0
4.3
3.2
5.3
2.9
13.1
4.4


AB029001
0.52
0.21
14.4
4.3
4.6
4.4
4.8
21.9
3.2
4.2


U62437
0.38
0.13
12.6
6.5
4.2
6.7
2.2
3.7
4.8
3.9


AF064854
0.15
0.16
2.6
2.9
6.2
8.9
14.4
5.0
9.1
3.9


AL031588
0.40
0.26
8.3
5.2
2.8
3.3
5.3
9.0
5.6
3.4


X89399
0.25
0.10
15.8
12.8
7.4
4.2
16.7
6.9
12.7
3.3


D45399
0.21
0.18
3.0
4.7
3.3
4.4
8.7
5.3
5.1
3.3


AB037716
0.36
0.40
5.1
7.5
2.6
2.1
3.5
3.1
2.4
2.8


X79981
0.34
0.10
4.7
7.2
3.2
4.6
6.5
5.1
5.8
2.7


AF034208
0.45
0.24
2.7
10.9
2.1
3.7
2.3
5.9
2.2
2.5


AL133355
0.22
0.23
2.3
3.4
7.3
2.7
3.3
4.3
2.8
2.5


NM_016281
0.40
0.19
6.6
10.6
2.1
2.8
5.0
11.2
10.6
2.5


AF023614
0.11
0.42
2.2
2.2
6.0
7.5
5.0
2.7
2.0
2.4


AF056717
0.43
0.62
4.3
3.2
5.1
4.0
4.6
9.7
3.1
2.2


AB029039
0.79
0.49
2.7
3.3
3.7
2.0
2.3
2.4
4.8
2.2


J03634
0.40
0.12
3.7
2.3
2.3
4.0
10.5
4.1
9.1
2.2


U80764
0.31
0.18
2.3
7.4
4.2
2.3
5.1
3.3
8.8
2.1


AB032963
0.19
0.34
4.0
7.3
5.0
3.0
2.9
6.7
3.8
2.1


X82835
0.25
0.38
2.0
2.7
2.9
7.7
3.3
3.1
3.5
2.0









EXAMPLE 5
Induction of Chemokines in Cell Lines, Whole Human Blood, and in Mice by Peptides

The murine macrophage cell line RAW 264.7, THP-1 cells (human monocytes), a human epithelial cell line (A549), human bronchial epithelial cells (16HBEo14), and whole human blood were used. HBE cells were grown in MEM with Earle's. THP-1 cells were grown and maintained in RPMI 1640 medium. The RAW and A549 cell lines were maintained in DMEM supplemented with 10% fetal calf serum. The cells were seeded in 24 well plates at a density of 106 cells per well in DMEM (see above) and A549 cells were seeded in 24 well plates at a density of 105 cells per well in DMEM (see above) and both were incubated at 37° C. in 5% CO2 overnight. DMEM was aspirated from cells grown overnight and replaced with fresh medium. After incubation of the cells with peptide, the release of chemokines into the culture supernatant was determined by ELISA (R&D Systems, Minneapolis, Minn.).


Animal studies were approved by the UBC Animal Care Committee (UBC ACC # A01-0008). BALB/c mice were purchased from Charles River Laboratories and housed in standard animal facilities. Age, sex and weight matched adult mice were anaesthetized with an intraperitoneal injection of Avertin (4.4 mM 2-2-2-tribromoethanol, 2.5% 2-methyl-2-butanol, in distilled water), using 200 μl per 10 g body weight. The instillation was performed using a non-surgical, intratracheal instillation method adapted from Ho and Furst 1973. Briefly, the anaesthetized mouse was placed with its upper teeth hooked over a wire at the top of a support frame with its jaw held open and a spring pushing the thorax forward to position the pharynx, larynx and trachea in a vertical straight line. The airway was illuminated externally and an intubation catheter was inserted into the clearly illuminated tracheal lumen. Twenty-μl of peptide suspension or sterile water was placed in a well at the proximal end of the catheter and gently instilled into the trachea with 200 μl of air. The animals were maintained in an upright position for 2 minutes after instillation to allow the fluid to drain into the respiratory tree. After 4 hours the mice were euthanaised by intraperitoneal injection of 300 mg/kg of pentobarbital. The trachea was exposed; an intravenous catheter was passed into the proximal trachea and tied in place with suture thread. Lavage was performed by introducing 0.75 ml sterile PBS into the lungs via the tracheal cannula and then after a few seconds, withdrawing the fluid. This was repeated 3 times with the same sample of PBS. The lavage fluid was placed in a tube on ice and the total recovery volume per mouse was approximately 0.5 ml. The bronchoalveolar lavage (BAL) fluid was centrifuged at 1200 rpm for 10 min, the clear supernatant removed and tested for TNF-α and MCP-1 by ELISA.


The up-regulation of chemokines by cationic peptides was confirmed in several different systems. The murine MCP-1, a homologue of the human MCP-1, is a member of the β(C-C) chemokine family. MCP-1 has been demonstrated to recruit monocytes, NK cells and some T lymphocytes. When RAW 264.7 macrophage cells and whole human blood from 3 donors were stimulated with increasing concentrations of peptide, SEQ ID NO: 1, they produced significant levels of MCP-1 in their supernatant, as judged by ELISA (Table 36). RAW 264.7 cells stimulated with peptide concentrations ranging from 20-50 μg/ml for 24 hr produced significant levels of MCP-1 (200-400 pg/ml above background). When the cells (24 h) and whole blood (4 h) were stimulated with 100 μg/ml of LL-37, high levels of MCP-1 were produced.


The effect of cationic peptides on chemokine induction was also examined in a completely different cell system, A549 human epithelial cells. Interestingly, although these cells produce MCP-1 in response to LPS, and this response could be antagonized by peptide; there was no production of MCP-1 by A549 cells in direct response to peptide, SEQ ID NO: 1. Peptide SEQ ID NO: 1 at high concentrations, did however induce production of IL-8, a neutrophil specific chemokine (Table 37). Thus, SEQ ID NO: 1 can induce a different spectrum of responses from different cell types and at different concentrations. A number of peptides from each of the formula groups were tested for their ability to induce IL-8 in A549 cells (Table 38). Many of these peptides at a low concentration, 10 μg/ml induced IL-8 above background levels. At high concentrations (100 μg/ml) SEQ ID NO: 13 was also found to induce IL-8 in whole human blood (Table 39). Peptide SEQ ID NO: 2 also significantly induced IL-8 in HBE cells (Table 40) and undifferentiated THP-1 cells (Table 41).


BALB/c mice were given SEQ ID NO: 1 or endotoxin-free water by intratracheal instillation and the levels of MCP-1 and TNF-α examined in the bronchioalveolar lavage fluid after 3-4 hr. It was found that the mice treated with 50 μg/ml peptide, SEQ ID NO: 1 produced significantly increased levels of MCP-1 over mice given water or anesthetic alone (Table 42). This was not a pro-inflammatory response to peptide, SEQ ID NO: 1 since peptide did not significantly induce more TNF-α than mice given water or anesthetic alone, peptide, SEQ ID NO: 1 was also found not to significantly induce TNF-α production by RAW 264.7 cells and bone marrow-derived macrophages treated with peptide, SEQ ID NO: 1 (up to 100 μg/ml) (Table 43). Thus, peptide, SEQ ID NO: 1 selectively induces the production of chemokines without inducing the production of inflammatory mediators such as TNF-α. This illustrates the dual role of peptide, SEQ ID NO: 1 as a factor that can block bacterial product-induced inflammation while helping to recruit phagocytes that can clear infections.









TABLE 38







Induction of MCP-1 in RAW 264.7 cells and whole


human blood.


RAW 264.7 mouse macrophage cells or whole human blood


were stimualted with increasing concentrations of LL-37


for 4 hr. The human blood samples were centrifuged and


the serum was removed and tested for MCP-1 by ELISA along


with the supernatants from the RAW 264.7 cells. The RAW


cell data presented is the mean of three or more experiments


± standard error and the human blood data represents


the mean ± standard error from three separate donors.











Monocyte chemoattractant



Peptide, SEQ ID
protein (MCP)-1 (pg/ml)*












NO: 1 (μg/ml)

RAW cells
Whole blood

















0
135.3 ±
16.3
112.7 ±
43.3



10
165.7 ±
18.2
239.3 ±
113.3



50
367 ±
11.5
371 ±
105



100
571 ±
17.4
596 ±
248.1

















TABLE 39







Induction of IL-8 in A549 cells and whole human blood.


A549 cells or whole human blood were stimulated with


increasing concentrations of peptide for 24 and 4 hr


respectively. The human blood samples were centrifuged


and the serum was removed and tested for IL-8 by ELISA


along with the supernatants from the A549 cells. The


A549 cell data presented is the mean of three or more


experiments ± standard error and the human blood


data represents the mean ± standard error from the


three separate donors.










Peptide, SEQ ID
IL-8 (pg/ml)












NO: 1 (μg/ml)

A549 cells
Whole blood

















0
172 ±
29.1
660.7 ±
126.6



1
206.7 ±
46.1



10
283.3 ±
28.4
945.3 ±
279.9



20
392 ±
31.7



50
542.3 ±
66.2
1160.3 ±
192.4



100
1175.3 ±
188.3

















TABLE 40







Induction of IL-8 in A549 cells by Cationic peptides.


A549 human epithelial cells were stimualted with 10 μg


of peptide for 24 hr. The supernatant was


removed and tested for IL-8 by ELISA.










Peptide (10 ug/ml)
IL-8 (ng/ml)














No peptide
0.164



LPS, no peptide
0.26



SEQ ID NO: 1
0.278



SEQ ID NO: 6
0.181



SEQ ID NO: 7
0.161



SEQ ID NO: 9
0.21



SEQ ID NO: 10
0.297



SEQ ID NO: 13
0.293



SEQ ID NO: 14
0.148



SEQ ID NO: 16
0.236



SEQ ID NO: 17
0.15



SEQ ID NO: 19
0.161



SEQ ID NO: 20
0.151



SEQ ID NO: 21
0.275



SEQ ID NO: 22
0.314



SEQ ID NO: 23
0.284



SEQ ID NO: 24
0.139



SEQ ID NO: 26
0.201



SEQ ID NO: 27
0.346



SEQ ID NO: 28
0.192



SEQ ID NO: 29
0.188



SEQ ID NO: 30
0.284



SEQ ID NO: 31
0.168



SEQ ID NO: 33
0.328



SEQ ID NO: 34
0.315



SEQ ID NO: 35
0.301



SEQ ID NO: 36
0.166



SEQ ID NO: 37
0.269



SEQ ID NO: 38
0.171



SEQ ID NO: 40
0.478



SEQ ID NO: 41
0.371



SEQ ID NO: 42
0.422



SEQ ID NO: 43
0.552



SEQ ID NO: 44
0.265



SEQ ID NO: 45
0.266



SEQ ID NO: 47
0.383



SEQ ID NO: 48
0.262



SEQ ID NO: 49
0.301



SEQ ID NO: 50
0.141



SEQ ID NO: 51
0.255



SEQ ID NO: 52
0.207



SEQ ID NO: 53
0.377



SEQ ID NO: 54
0.133

















TABLE 41







Induction by Peptide of IL-8 in human blood.


Whole human blood was stimulated with the increasing


concentrations of peptide for 4 hr. The human blood


samples were centrifuged and the serum was removed


and tested for IL-8 by ELISA. The data shown is the


average 2 donors.










SEQ ID NO: 3 (μg/ml)
IL-8 (pg/ml)














0
85



10
70



100
323

















TABLE 42







Induction of IL-8 in HBE cells.


Increasing concentrations of the peptide were incubated


with HBE cells for 8 h, the supernantant removed and


tested for IL-8. The data is presented as the mean of


three or more experiments ± standard error.










SEQ ID NO: 2




(μg/ml)
IL-8 (pg/ml)















0
552 ±
90



0.1
670 ±
155



1
712 ±
205



10
941 ±
15



50
1490 ±
715

















TABLE 43







Induction of IL-8 in undifferentiated THP-1 cells.


The human monocyte THP-1 cells were incubated with


indicated concentrations of peptide for 8 hr. The


supernatant was removed and tested for IL-8 by ELISA.










SEQ ID NO: 3(μg/ml)
IL-8 (pg/ml)














0
10.6



10
17.2



50
123.7

















TABLE 44







Induction of MCP-1 by Peptide, SEQ ID NO: 1 in mouse airway.


BALB/c mice were anaesthetised with avertin and given


intratracheal instillation of peptide or water or no


instillation (no treatment). The mice were monitored


for 4 hrs, anaesthetised and the BAL fluid was isolated


and analyzed for MCP-1 and TNF-α concentrations by


ELISA. The data shown is the mean of 4 or 5 mice for


each condition ± standard error.












Condition

MCP-1 (pg/ml)
TNF-α (pg/ml)
















Water
16.5 ±
5
664 ± 107



peptide
111 ±
30
734 ± 210



Avertin
6.5 ±
0.5
393 ± 129

















TABLE 45







Lack of Significant TNF-α induction by the Cationic Peptides.


RAW 264.7 macrophage cells were incubated with


indicated peptides (40 μg/ml) for 6 hours. The


supernatant was collected and tested for levels of


TNF-α by ELISA. The data is presented as the mean


of three or more experiments + standard error.










Peptide Treatment
TNF-α (pg/ml)















Media background
56 ±
8



LPS treatment, No peptide
15207 ±
186



SEQ ID NO: 1
274 ±
15



SEQ ID NO: 5
223 ±
45



SEQ ID NO: 6
297 ±
32



SEQ ID NO: 7
270 ±
42



SEQ ID NO: 8
166 ±
23



SEQ ID NO: 9
171 ±
33



SEQ ID NO: 10
288 ±
30



SEQ ID NO: 12
299 ±
65



SEQ ID NO: 13
216 ±
42



SEQ ID NO: 14
226 ±
41



SEQ ID NO: 15
346 ±
41



SEQ ID NO: 16
341 ±
68



SEQ ID NO: 17
249 ±
49



SEQ ID NO: 19
397 ±
86



SEQ ID NO: 20
285 ±
56



SEQ ID NO: 21
263 ±
8



SEQ ID NO: 22
195 ±
42



SEQ ID NO: 23
254 ±
58



SEQ ID NO: 24
231 ±
32



SEQ ID NO: 26
281 ±
34



SEQ ID NO: 27
203 ±
42



SEQ ID NO: 28
192 ±
26



SEQ ID NO: 29
242 ±
40



SEQ ID NO: 31
307 ±
71



SEQ ID NO: 33
196 ±
42



SEQ ID NO: 34
204 ±
51



SEQ ID NO: 35
274 ±
76



SEQ ID NO: 37
323 ±
41



SEQ ID NO: 38
199 ±
38



SEQ ID NO: 43
947 ±
197



SEQ ID NO: 44
441 ±
145



SEQ ID NO: 45
398 ±
90



SEQ ID NO: 48
253 ±
33



SEQ ID NO: 49
324 ±
38



SEQ ID NO: 50
311 ±
144



SEQ ID NO: 53
263 ±
40



SEQ ID NO: 54
346 ±
86










EXAMPLE 6
Cationic Peptides Increase Surface Expression of Chemokine Receptors

To analyze cell surface expression of IL-8RB, CXCR-4, CCR2, and LFA-1, RAW macrophage cells were stained with 10 μg/ml of the appropriate primary antibody (Santa Cruz Biotechnology) followed by FITC-conjugated goat anti-rabbit IgG [IL-8RB and CXCR-4 (Jackson ImmunoResearch Laboratories, West Grove, Pa.)] or FITC-conjugated donkey anti-goat IgG (Santa Cruz). The cells were analyzed using a FACscan, counting 10,000 events and gating on forward and side scatter to exclude cell debris.


The polynucleotide array data suggested that some peptides up-regulate the expression of the chemokine receptors IL-8RB, CXCR-4 and CCR2 by 10, 4 and 1.4 fold above unstimulated cells respectively. To confirm the polynucleotide array data, the surface expression was examined by flow cytometry of these receptors on RAW cells stimulated with peptide for 4 hr. When 50 μg/ml of peptide was incubated with RAW cells for 4 hr, IL-8RB was up-regulated an average of 2.4-fold above unstimulated cells, CXCR-4 was up-regulated an average of 1.6-fold above unstimulated cells and CCR2 was up-regulated 1.8-fold above unstimulated cells (Table 46). As a control CEMA was demonstrated to cause similar up-regulation. Bac2A was the only peptide to show significant up-regulation of LFA-1 (3.8 fold higher than control cells).









TABLE 46







Increased surface expression of CXCR-4, IL-8RB and CCR2


in response to peptides.


RAW macrophage cells were stimulated with peptide for 4


hr. The cells were washed and stained with the appropriate


primary and FITC-labeled secondary antibodies. The data


shown represents the average (fold change of RAW cells


stimulated with peptide from media) ± standard error.










Concentration
Fold Increase in Protein Expression











Peptide
(μg/ml)
IL-8RB
CXCR-4
CCR2

















SEQ ID
10
1.0

1.0

1.0



NO: 1


SEQ ID
50
1.3
± 0.05
1.3
± 0.03
1.3
+ 0.03


NO: 1


SEQ ID
100
2.4
± 0.6
1.6
± 0.23
1.8
± 0.15


NO: 1













SEQ ID
100
2.0
± 0.6
Not Done
4.5



NO: 3














CEMA
50
1.6
± 0.1
1.5
± 0.2
1.5
± 0.15














100
3.6
± 0.8
Not Done
4.7
± 1.1









EXAMPLE 7
Phosphorylation of Map Kinases by Cationic Peptides

The cells were seeded at 2.5×105-5×105 cells/ml and left overnight. They were washed once in media, serum starved in the morning (serum free media—4 hrs). The media was removed and replaced with PBS, then sat at 37° C. for 15 minutes and then brought to room temp for 15 minutes. Peptide was added (concentrations 0.1 ug/ml-50 ug/ml) or H2O and incubated 10 min. The PBS was very quickly removed and replaced with ice-cold radioimmunoprecipitation (RIPA) buffer with inhibitors (NaF, B-glycerophosphate, MOL, Vanadate, PMSF, Leupeptin Aprotinin). The plates were shaken on ice for 10-15 min or until the cells were lysed and the lysates collected. The procedure for THP-1 cells was slightly different; more cells (2×106) were used. They were serum starved overnight, and to stop the reaction 1 ml of ice-cold PBS was added then they sat on ice 5-10 min, were spun down then resuspended in RIPA. Protein concentrations were determined using a protein assay (Pierce, Rockford, Ill.). Cell lysates (20 μg of protein) were separated by SDS-PAGE and transferred to nitrocellulose filters. The filters were blocked for 1 h with 10 mM Tris-HCl, pH 7.5, 150 mM NaCl (TBS)/5% skim milk powder and then incubated overnight in the cold with primary antibody in TBS/0.05% Tween 20. After washing for 30 min with TBS/0.05% Tween 20, the filters were incubated for 1 h at room temperature with 1 μg/ml secondary antibody in TBS. The filters were washed for 30 min with TBS/0.05% Tween 20 and then incubated 1 h at room temperature with horseradish peroxidase-conjugated sheep anti-mouse IgG (1:10,000 in TBS/0.05% Tween 20). After washing the filters for 30 min with TBS/0.1% Tween 20, immunoreactive bands were visualized by enhanced chemiluminescence (ECL) detection. For experiments with peripheral blood mononuclear cells: The peripheral blood (50-100 ml) was collected from all subjects. Mononuclear cells were isolated from the peripheral blood by density gradient centrifugation on Ficoll-Hypaque. Interphase cells (mononuclear cells) were recovered, washed and then resuspended in recommended primary medium for cell culture (RPMI-1640) with 10% fetal calf serum (FCS) and 1% L-glutamine. Cells were added to 6 well culture plates at 4×106 cells/well and were allowed to adhere at 37° C. in 5% CO2 atmosphere for 1 hour. The supernatant medium and non-adherent cells were washed off and the appropriate media with peptide was added. The freshly harvested cells were consistently >99% viable as assessed by their ability to exclude trypan blue. After stimulation with peptide, lysates were collected by lysing the cells in RIPA buffer in the presence of various phosphatase- and kinase-inhibitors. Protein content was analyzed and approximately 30 μg of each sample was loaded in a 12% SDS-PAGE gel. The gels were blotted onto nitrocellulose, blocked for 1 hour with 5% skim milk powder in Tris buffered saline (TBS) with 1% Triton X 100. Phosphorylation was detected with phosphorylation-specific antibodies.


The results of peptide-induced phosphorylation are summarized in Table 46. SEQ ID NO: 2 was found to cause dose dependent phosphorylation of p38 and ERK1/2 in the mouse macrophage RAW cell line and the HBE cells. SEQ ID NO: 3 caused phosphorylation of MAP kinases in THP-1 human monocyte cell line and phosphorylation of ERK1/2 in the mouse RAW cell line.









TABLE 47







Phosphorylation of MAP kinases in response to peptides.










MAP kinase phosphorylated











Cell Line
Peptide
p38
ERK1/2





RAW 264.7
SEQ ID NO: 3

+



SEQ ID NO: 2
+
+


HBE
SEQ ID NO: 3

+



SEQ ID NO: 2
+
+


THP-1
SEQ ID NO: 3
+
+



SEQ ID NO: 2
















TABLE 48







Peptide Phosphorylation of MAP kinases in human blood


monocytes. SEQ ID NO: 1 at 50 μg/ml) was used to


promote physphorylation.












p38 phosphorylation

ERK1/2 phosphorylation













15 minutes
60 minutes
15 minutes
60 minutes







+

+
+










EXAMPLE 8
Cationic Peptides Protect Against Bacterial Infection by Enhancing the Immune Response

BALB/c mice were given 1×105 Salmonella and cationic peptide (200 μg) by intraperitoneal injection. The mice were monitored for 24 hours at which point they were euthanized, the spleen removed, homogenized and resuspended in PBS and plated on Luria Broth agar plates with Kanamycin (50 μg/ml). The plates were incubated overnight at 37° C. and counted for viable bacteria (Table 49 and 50). CD-1 mice were given 1×108 S. aureus in 5% porcine mucin and cationic peptide (200 μg) by intraperitoneal injection (Table 51). The mice were monitored for 3 days at which point they were euthanized, blood removed and plated for viable counts. CD-1 male mice were given 5.8×106 CFU EHEC bacteria and cationic peptide (200 μg) by intraperitoneal (IP) injection and monitored for 3 days (Table 52). In each of these animal models a subset of the peptides demonstrated protection against infections. The most protective peptides in the Salmonella model demonstrated an ability to induce a common subset of genes in epithelial cells (Table 53) when comparing the protection assay results in Tables 50 and 51 to the gene expression results in Tables 31-37. This clearly indicates that there is a pattern of gene expression that is consistent with the ability of a peptide to demonstrate protection. Many of the cationic peptides were shown not to be directly antimicrobial as tested by the Minimum Inhibitory Concentration (MIC) assay (Table 54). This demonstrates that the ability of peptides to protect against infection relies on the ability of the peptide to stimulate host innate immunity rather than on direct antimicrobial activity.









TABLE 49







Effect of Cationic Peptides on Salmonella Infection in BALB/c mice.


The BALB/c mice were injected IP with Salmonella and


Peptide, and 24 h later the animals were euthanized,


the spleen removed, homogenized, diluted in PBS and


plate counts were done to determine bacteria viability.












Viable Bacteria
Statistical



Peptide
in the Spleen
Significance



Treatment
(CFU/ml)
(p value)







Control
2.70 ± 0.84 × 105




SEQ ID NO: 1
1.50 ± 0.26 × 105
0.12



SEQ ID NO: 6
2.57 ± 0.72 × 104
0.03



SEQ ID NO: 13
3.80 ± 0.97 × 104
0.04



SEQ ID NO: 17
4.79 ± 1.27 × 104
0.04



SEQ ID NO: 27
1.01 ± 0.26 × 105
0.06

















TABLE 50







Effect of Cationic Peptides on Salmonella Infection in BALB/c mice.


The BALB/c mice were injected intraperitoneally with


Salmonella and Peptide, and 24 h later the animals were


euthanized, the spleen removed, homogenized, diluted in


PBS and plate counts were done to determine bacteria viability.










Peptide Treatment
Viable Bacteria in the Spleen (CFU/ml)















Control
1.88 ±
0.16 × 104



SEQ ID NO: 48
1.98 ±
0.18 × 104



SEQ ID NO: 26
7.1 ±
1.37 × 104



SEQ ID NO: 30
5.79 ±
0.43 × 103



SEQ ID NO: 37
1.57 ±
0.44 × 104



SEQ ID NO: 5
2.75 ±
0.59 × 104



SEQ ID NO: 7
5.4 ±
0.28 × 103



SEQ ID NO: 9
1.23 ±
0.87 × 104



SEQ ID NO: 14
2.11 ±
0.23 × 103



SEQ ID NO: 20
2.78 ±
0.22 × 104



SEQ ID NO: 23
6.16 ±
0.32 × 104

















TABLE 51







Effect of Cationic Peptides in a Murine S. aureus infection model.


CD-1 mice were given 1 × 108 bacteria in 5% porcine


mucin via intraperitoneal (IP) injection. Cationic


peptide (200 μg) was given via a sepearte IP injection.


The mice were monitored for 3 days at which point they


were euthanized, blood removed and plated for viable counts.


The following peptides were not effective in controlling



S. aureus infection: SEQ ID NO: 48, SEQ ID NO: 26
















# Mice Survived






(3 days)/Total



Treatment

CFU/ml (blood)
mice in group
















No Peptide
7.61
± 1.7 × 103
6/8



SEQ ID NO: 1
0

4/4



SEQ ID NO: 27
2.25
± 0.1 × 102
3/4



SEQ ID NO: 30
1.29
± 0.04 × 102
4/4



SEQ ID NO: 37
9.65
± 0.41 × 102
4/4



SEQ ID NO: 5
3.28
± 1.7 × 103
4/4



SEQ ID NO: 6
1.98
± 0.05 × 102
3/4



SEQ ID NO: 7
3.8
± 0.24 × 103
4/4



SEQ ID NO: 9
2.97
± 0.25 × 102
4/4



SEQ ID NO: 13
4.83
± 0.92 × 103
3/4



SEQ ID NO: 17
9.6
± 0.41 × 102
4/4



SEQ ID NO: 20
3.41
± 1.6 × 103
4/4



SEQ ID NO: 23
4.39
± 2.0 × 103
4/4

















TABLE 52







Effect of Peptide in a Murine EHEC infection model.


CD-1 male mice (5 weeks old) were given 5.8 × 106


CFU EHEC bacteria via intraperitoneal (IP) injection.


Cationic peptide (200 μg) was given via a separate


IP injection. The mice were monitored for 3 days.









Treatment
Peptide
Survival (%)





control
none
25


SEQ ID NO: 23
200 μg
100
















TABLE 53







Up-regulation of patterns of gene expression in A549 epithelial cells


induced by peptides that are active in vivo.


The peptides SEQ ID NO: 30, SEQ ID NO: 7 and SEQ ID NO: 13 at


concentrations of 50 μg/ml were each shown to increase the expression of a pattern of


genes after 4 h treatment. Peptide was incubated with the human A549 epithelial cells for


4 h and the RNA was isolated, converted into labelled cDNA probes and hybridised to


Human Operon arrays (PRHU04). The intensity of polynucleotides in control,


unstimulated cells are shown in the second columns for labelling of cDNA (average of


Cy3 and Cy5). The Fold Up regulation column refers to the intensity of polynucleotide


expression in peptide-simulated cells divided by the intensity of unstimulated cells. The


SEQ ID NO: 37 peptide was included as a negative control that was not active in the


murine infection models.









Fold Up regulation of Gene Expression



relative to Untreated Cells













Unstimulated
SEQ ID
SEQ ID
SEQ ID
SEQ ID


Target (Accession number)
Cell Intensity
NO: 30
NO: 7
NO: 13
NO: 37















Zinc finger protein (AF061261)
13
2.6
9.4
9.4
1.0


Cell cycle gene (S70622)
1.62
8.5
3.2
3.2
0.7


IL-10 Receptor (U00672)
0.2
2.6
9
4.3
0.5


Transferase (AF038664)
0.09
12.3
9.7
9.7
0.1


Homeobox protein (AC004774)
0.38
3.2
2.5
2.5
1.7


Forkhead protein (AF042832)
0.17
14.1
3.5
3.5
0.9


Unknown (AL096803)
0.12
4.8
4.3
4.3
0.6


KIAA0284 Protein (AB006622)
0.47
3.4
2.1
2.1
1.3


Hypothetical Protein (AL022393)
0.12
4.4
4.0
4.0
0.4


Receptor (AF112461)
0.16
2.4
10.0
10.0
1.9


Hypothetical Protein (AK002104)
0.51
4.7
2.6
2.6
1.0


Protein (AL050261)
0.26
3.3
2.8
2.8
1.0


Polypeptide (AF105424)
0.26
2.5
5.3
5.3
1.0


SPR1 protein (AB031480)
0.73
3.0
2.7
2.7
1.3


Dehydrogenase (D17793)
4.38
2.3
2.2
2.2
0.9


Transferase (M63509)
0.55
2.7
2.1
2.1
1.0


Peroxisome factor (AB013818)
0.37
3.4
2.9
2.9
1.4
















TABLE 54







Most cationic peptides studied here and especially the cationic peptides


effective in infection models are not significantly antimicrobial. A dilution


series of peptide was incubated with the indicated bacteria overnight in a


96-well plate. The lowest concentration of peptide that killed the bacteria


was used as the MIC. The symbol > indicates the MIC is too large to measure.


An MIC of 8 μg/ml or less was considered clinically meaningful activity.


Abbreviations: E. coli, Escherichia coli; S. aureus, Staphylococcus aureus;



P. aerug, Pseudomonas aeruginosa; S. Typhim, Salmonella enteritidis ssp.




typhimurium, C. rhod, Citobacter rhodensis; EHEC, Enterohaemorrhagic




E. coli.










MIC (μg/ml)













Peptide

E. coli


S. aureus


P. aerug.


S. typhim.


C. rhod.

EHEC
















Polymyxin
0.25
16
0.25
0.5
0.25
0.5


Gentamicin
0.25
0.25
0.25
0.25
0.25
0.5


SEQ ID NO: 1
32
>
96
64
8
4


SEQ ID NO: 5
128
>
>
>
64
64


SEQ ID NO: 6
128
>
>
128
64
64


SEQ ID NO: 7
>
>
>
>
>
>


SEQ ID NO: 8
>
>
>
>
>
>


SEQ ID NO: 9
>
>
>
>
>
>


SEQ ID NO: 10
>
>
>
>
>
64


SEQ ID NO: 12
>
>
>
>
>
>


SEQ ID NO: 13
>
>
>
>
>
>


SEQ ID NO: 14
>
>
>
>
>
>


SEQ ID NO: 15
128
>
>
>
128
64


SEQ ID NO: 16
>
>
>
>
>
>


SEQ ID NO: 17
>
>
>
>
>
>


SEQ ID NO: 19
8
16
16
64
4
4


SEQ ID NO: 2
4
16
32
16
64


SEQ ID NO: 20
8
8
8
8
16
8


SEQ ID NO: 21
64
64
96
64
32
32


SEQ ID NO: 22
8
12
24
8
4
4


SEQ ID NO: 23
4
8
8
16
4
4


SEQ ID NO: 24
16
16
4
16
16
4


SEQ ID NO: 26
0.5
32
64
2
2
0.5


SEQ ID NO: 27
8
64
64
16
2
4


SEQ ID NO: 28
>
>
>
64
64
128


SEQ ID NO: 29
2
>
>
16
32
4


SEQ ID NO: 30
16
>
128
16
16
4


SEQ ID NO: 31
>
>
128
>
>
64


SEQ ID NO: 33
16
32
>
16
64
8


SEQ ID NO: 34
8
>
>
32
64
8


SEQ ID NO: 35
4
128
64
8
8
4


SEQ ID NO: 36
32
>
>
32
32
16


SEQ ID NO: 37
>
>
>
>
>
>


SEQ ID NO: 38
0.5
32
64
4
8
4


SEQ ID NO: 40
4
32
8
4
4
2


SEQ ID NO: 41
4
64
8
8
2
2


SEQ ID NO: 42
1.5
64
4
2
2
1


SEQ ID NO: 43
8
128
16
16
8
4


SEQ ID NO: 44
8
>
128
128
64
64


SEQ ID NO: 45
8
>
128
128
16
16


SEQ ID NO: 47
4
>
16
16
4
4


SEQ ID NO: 48
16
>
128
16
1
2


SEQ ID NO: 49
4
>
16
8
4
4


SEQ ID NO: 50
8
>
16
16
16
8


SEQ ID NO: 51
4
>
8
32
4
8


SEQ ID NO: 52
8
>
32
8
2
2


SEQ ID NO: 53
4
>
8
8
16
8


SEQ ID NO: 54
64
>
16
64
16
32









EXAMPLE 9
Use of Polynucleotides Induced by Bacterial Signaling Molecules in Diagnostic/Screening


S. typhimurium LPS and E. coli 0111:B4 LPS were purchased from Sigma Chemical Co. (St. Louis, Mo.). LTA (Sigma) from S. aureus, was resuspended in endotoxin free water (Sigma). The Limulus amoebocyte lysate assay (Sigma) was performed on LTA preparations to confirm that lots were not significantly contaminated by endotoxin (i.e. <1 ng/ml, a concentration that did not cause significant cytokine production in the RAW cell assay). The CpG oligodeoxynucleotides were synthesized with an Applied Biosystems Inc., Model 392 DNA/RNA Synthesizer, Mississauga, ON., then purified and resuspended in endotoxin-free water (Sigma). The following sequences were used CpG: 5′-TCATGACGTTCCTGACGTT-3′ (SEQ ID NO: 57) and nonCpG: 5′-TTCAGGACTTTCCTCAGGTT-3′ (SEQ ID NO: 58). The nonCpG oligo was tested for its ability to stimulate production of cytokines and was found to cause no significant production of TNF-α or IL-6 and therefore was considered as a negative control. RNA was isolated from RAW 264.7 cells that had been incubated for 4 h with medium alone, 100 ng/ml S. typhimurium LPS, 1 μg/ml S. aureus LTA, or 1 μM CpG (concentrations that led to optimal induction of tumor necrosis factor (TNF-α) in RAW cells). The RNA was used to polynucleotiderate cDNA probes that were hybridized to Clontech Atlas polynucleotide array filters, as described above. The hybridization of the cDNA probes to each immobilized DNA was visualized by autoradiography and quantified using a phosphorimager. Results from at least 2 to 3 independent experiments are summarized in Tables 55-59. It was found that LPS treatment of RAW 264.7 cells resulted in increased expression of more than 60 polynucleotides including polynucleotides encoding inflammatory proteins such as IL-1β, inducible nitric oxide synthase (iNOS), MIP-1α, MIP-1β, MIP-2α, CD40, and a variety of transcription factors. When the changes in polynucleotide expression induced by LPS, LTA, and CpG DNA were compared, it was found that all three of these bacterial products increased the expression of pro-inflammatory polynucleotides such as iNOS, MIP-1α, MIP-2α, IL-1β, IL-15, TNFR1 and NF-κB to a similar extent (Table 57). Table 57 describes 19 polynucleotides that were up-regulated by the bacterial products to similar extents in that their stimulation ratios differed by less than 1.5 fold between the three bacterial products. There were also several polynucleotides that were down-regulated by LPS, LTA and CpG to a similar extent. It was also found that there were a number of polynucleotides that were differentially regulated in response to the three bacterial products (Table 58), which includes many of these polynucleotides that differed in expression levels by more than 1.5 fold between one or more bacterial products). LTA treatment differentially influenced expression of the largest subset of polynucleotides compared to LPS or CpG, including hyperstimulation of expression of Jun-D, Jun-B, Elk-1 and cyclins G2 and A1. There were only a few polynucleotides whose expression was altered more by LPS or CpG treatment. Polynucleotides that had preferentially increased expression due to LPS treatment compared to LTA or CpG treatment included the cAMP response element DNA-binding protein 1 (CRE-BPI), interferon inducible protein 1 and CACCC Box-binding protein BKLF. Polynucleotides that had preferentially increased expression after CpG treatment compared to LPS or LTA treatment included leukemia inhibitory factor (LIF) and protease nexin 1 (PN-1). These results indicate that although LPS, LTA, and CpG DNA stimulate largely overlapping polynucleotide expression responses, they also exhibit differential abilities to regulate certain subsets of polynucleotides.


The other polynucleotide arrays used are the Human Operon arrays (identification number for the genome is PRHU04-S1), which consist of about 14,000 human oligos spotted in duplicate. Probes were prepared from 5 μg of total RNA and labeled with Cy3 or Cy5 labeled dUTP. In these experiments, A549 epithelial cells were plated in 100 mm tissue culture dishes at 2.5×106 cells/dish, incubated overnight and then stimulated with 100 ng/ml E. coli O111:B4 LPS for 4 h. Total RNA was isolated using RNAqueous (Ambion). DNA contamination was removed with DNA-free kit (Ambion). The probes prepared from total RNA were purified and hybridized to printed glass slides overnight at 42° C. and washed. After washing, the image was captured using a Perkin Elmer array scanner. The image processing software (Imapolynucleotide 5.0, Marina Del Rey, Calif.) determines the spot mean intensity, median intensities, and background intensities. An “in house” program was used to remove background. The program calculates the bottom 10% intensity for each subgrid and subtracts this for each grid. Analysis was performed with Polynucleotidespring software (Redwood City, Calif.). The intensities for each spot were normalized by taking the median spot intensity value from the population of spot values within a slide and comparing this value to the values of all slides in the experiment. The relative changes seen with cells treated with LPS compared to control cells can be found in the Tables below. A number of previously unreported changes that would be useful in diagnosing infection are described in Table 60.


To confirm and assess the functional significance of these changes, the levels of selected mRNAs and proteins were assessed and quantified by densitometry. Northern blots using a CD 14, vimentin, and tristetraprolin-specific probe confirmed similar expression after stimulation with all 3 bacterial products (Table 60). Similarly measurement of the enzymatic activity of nitric oxide synthetase, iNOS, using Griess reagent to assess levels of the inflammatory mediator NO, demonstrated comparable levels of NO produced after 24 h, consistent with the similar up-regulation of iNOS expression (Table 59). Western blot analysis confirmed the preferential stimulation of leukemia inhibitory factor (LIF, a member of the IL-6 family of cytokines) by CpG (Table 59). Other confirmatory experiments demonstrated that LPS up-regulated the expression of TNF-α and IL-6 as assessed by ELISA, and the up-regulated expression of MIP-2α, and IL-1β mRNA and down-regulation of DP-1 and cyclin D mRNA as assessed by Northern blot analysis. The analysis was expanded to a more clinically relevant ex vivo system, by examining the ability of the bacterial elements to stimulate pro-inflammatory cytokine production in whole human blood. It was found that E. coli LPS, S. typhimurium LPS, and S. aureus LTA all stimulated similar amounts of serum TNF-α, and IL-1β. CpG also stimulated production of these cytokines, albeit to much lower levels, confirming in part the cell line data.









TABLE 55







Polynucleotides Up-regulated by E. coli O111:B4 LPS in


A549 Epithelial Cells.



E. coli O111:B4 LPS (100 ng/ml) increased the expression



of many polynucleotides in A549 cells as studied by


polynucleotide microarrays. LPS was incubated with the


A549 cells for 4 h and the RNA was isolated. 5 μg total


RNA was used to make Cy3/Cy5 labelled cDNA probes and


hybridised onto Human Operon arrays (PRHU04). The intensity


of unstimulated cells is shown in the second column of


Table 55. The “Ratio: LPS/control” column refers to


the intensity of polynucleotide expression in LPS simulated


cells divided by in the intensity of unstimulated cells.










Accession

Control: Media
Ratio:


Number
Gene
only Intensity
LPS/control













D87451
ring finger
715.8
183.7



protein 10


AF061261
C3H-type zinc
565.9
36.7



finger protein


D17793
aldo-keto reductase
220.1
35.9



family 1, member C3


M14630
prothymosin, alpha
168.2
31.3


AL049975
Unknown
145.6
62.3


L04510
ADP-ribosylation
139.9
213.6



factor domain



protein 1, 64kD


U10991
G2 protein
101.7
170.3


U39067
eukaryotic trans-
61.0
15.9



lation initiation



factor 3, subunit 2


X03342
ribosomal protein
52.6
10.5



L32


NM_004850
Rho-associated,
48.1
11.8



coiled-coil con-



taining protein



kinase 2


AK000942
Unknown
46.9
8.4


AB040057
serine/threonine
42.1
44.3



protein kinase



MASK


AB020719
KIAA0912 protein
41.8
9.4


AB007856
FEM-1-like death
41.2
15.7



receptor binding



protein


J02783
procollagen-proline,
36.1
14.1



2-oxoglutarate



4-dioxygenase


AL137376
Unknown
32.5
17.3


AL137730
Unknown
29.4
11.9


D25328
phosphofructo-
27.3
8.5



kinase, platelet


AF047470
malate dehydro-
25.2
8.2



genase 2, NAD


M86752
stress-induced-
22.9
5.9



phosphoprotein 1


M90696
cathepsin S
19.6
6.8


AK001143
Unknown
19.1
6.4


AF038406
NADH dehydro-genase
17.7
71.5


AK000315
hypothetical protein
17.3
17.4



FLJ20308


M54915
pim-1 oncogene
16.0
11.4


D29011
proteasome subunit,
15.3
41.1



beta type, 5


AK000237
membrane protein
15.1
9.4



of cholinergic



synaptic vesicles


AL034348
Unknown
15.1
15.8


AL161991
Unknown
14.2
8.1


AL049250
Unknown
12.7
5.6


AL050361
PTD017 protein
12.6
13.0


U74324
RAB interacting
12.3
5.2



factor


M22538
NADH dehydrogenase
12.3
7.6


D87076
KIAA0239 protein
11.6
6.5


NM_006327
translocase of inner
11.5
10.0



mitochondrial mem-



brane 23 (yeast)



homolog


AK001083
Unknown
11.1
8.6


AJ001403
mucin 5, subtype B,
10.8
53.4



tracheobronchial


M64788
RAP1, GTPase
10.7
7.6



activating



protein 1


X06614
retinoic acid re-
10.7
5.5



ceptor, alpha


U85611
calcium and integring
10.3
8.1



binding protein


U23942
cytochrome P450, 51
10.1
10.2


AL031983
Unknown
9.7
302.8


NM_007171
protein-O-mannosyl-
9.5
6.5



transferase 1


AK000403
hypothetical protein
9.5
66.6



FLJ20396


NM_002950
ribophorin I
9.3
35.7


L05515
cAMP response element-
8.9
6.2



binding protein



CRE-BPa


X83368
phosphoinositide-
8.7
27.1



3-kinase, catalytic,



gamma polypeptide


M30269
nidogen (enactin)
8.7
5.5


M91083
chromosome 11 open
8.2
6.6



reading frame 13


D29833
salivary proline-
7.7
5.8



rich protein


AB024536
immunoglobulin super-
7.6
8.0



family containing



leucine-rich repeat


U39400
chromosome 11 open
7.4
7.3



reading frame 4


AF028789
unc119 (C.elegans)
7.4
27.0



homo log


NM_003144
signal sequence
7.3
5.9



receptor, alpha



(translocon-asso-



ciated protein alpha)


X52195
arachidonate 5-lipoxy-
7.3
13.1



genase-activating



protein


U43895
human growth factor-
6.9
6.9



regulated tyrosine



kinase substrate


L25876
cyclin-dependent
6.7
10.3



kinase inhibitor 3


L04490
NADH dehydrogenase
6.6
11.1


Z18948
S100 calcium-binding
6.3
11.0



protein


D10522
myristoylated alanine-
6.1
5.8



rich protein kinase



C substrate


NM_014442
sialic acid binding
6.1
7.6



Ig-like lectin 8


U81375
solute carrier
6.0
6.4



family 29


AF041410
malignancy-asso-
5.9
5.3



ciated protein


U24077
killer cell immuno-
5.8
14.4



globulin-like receptor


AL137614
hypothetical protein
4.8
6.8


NM_002406
mannosyl (alpha-1,3-)-
4.7
5.3



glycoprotein beta-1,2-



N-acetylglucosaminyl-



transferase


AB002348
KIAA0350 protein
4.7
7.6


AF165217
tropomodulin 4 (muscle)
4.6
12.3


Z14093
branched chain keto
4.6
5.4



acid dehydrogenase E1,



alpha polypeptide


U82671
caltractin
3.8
44.5


AL050136
Unknown
3.6
5.0


NM_005135
solute carrier
3.6
5.0



family 12


AK001961
hypothetical protein
3.6
5.9



FLJ11099


AL034410
Unknown
3.2
21.3


S74728
antiquitin 1
3.1
9.2


AL049714
ribosomal protein L34
3.0
19.5



pseudogene 2


NM_014075
PRO0593 protein
2.9
11.5


AF189279
phospholipase A2,
2.8
37.8



group IIE


J03925
integrin, alpha M
2.7
9.9


NM_012177
F-box protein Fbx5
2.6
26.2


NM_004519
potassium voltage-gated
2.6
21.1



channel, KQT-like



subfamily,member 3


M28825
CD1A antigen, a
2.6
16.8



polypeptide


X16940
actin, gamma 2, smooth
2.4
11.8



muscle, enteric


X03066
major histocompati-
2.2
36.5



bility complex, class



II, DO beta


AK001237
hypothetical protein
2.1
18.4



FLJ10375


AB028971
KIAA1048 protein
2.0
9.4


AL137665
Unknown
2.0
7.3
















TABLE 56







Polynucleotides Down-regulated by E. coli O111:B4 LPS


in A549 Epithelial Cells.



E. coli O111:B4 LPS (100 ng/ml) decreased the expression



of many polynucleotides in A549 cells as studied by


polynucleotide microarrays. LPS was incubated with the


A549 cells for 4 h and the RNA was isolated. 5 μg total


RNA was used to make Cy3/Cy5 labeled cDNA probes and


hybridized onto Human Operon arrays (PRHU04). The Intensity


of unstimulated cells is shown in the second column of the


Table. The “Ratio: LPS/control” column refers to the


intensity of polynucleotide expression in LPS simulated cells


divided by in the intensity of unstimulated cells.












Control:



Accession

Media only
Ratio:


Number
Gene
Intensity
LPS/control













NM_017433
myosin IIIA
167.8
0.03


X60484
H4 histone family
36.2
0.04



member E


X60483
H4 histone family
36.9
0.05



member D


AF151079
hypothetical protein
602.8
0.05


M96843
inhibitor of DNA
30.7
0.05



binding 2, dominant



negative helix-



loop-helix protein


S79854
deiodinase, iodothy-
39.4
0.06



ronine, type III


AB018266
matrin 3
15.7
0.08


M33374
NADH dehydrogenase
107.8
0.09


AF005220
Homo sapiens mRNA for
105.2
0.09



NUP98-HOXD13 fusion



protein, partial cds


Z80783
H2B histone family,
20.5
0.10



member L


Z46261
H3 histone family,
9.7
0.12



member A


Z80780
H2B histone family,
35.3
0.12



member H


U33931
erythrocyte membrane
18.9
0.13



protein band



7.2 (stomatin)


M60750
H2B histone family,
35.8
0.14



member A


Z83738
H2B histone family,
19.3
0.15



member E


Y14690
collagen, type V,
7.5
0.15



alpha 2


M30938
X-ray repair comple-
11.3
0.16



menting defective



repair in Chinese



hamster cells 5


L36055
eukaryotic trans-
182.5
0.16



lation initiation



factor 4E binding



protein 1


Z80779
H2B histone family,
54.3
0.16



member G


AF226869
5(3)-deoxyribonu-
7.1
0.18



cleotidase; RB-



associated



KRAB repressor


D50924
KIAA0134 gene
91.0
0.18



product


AL133415
vimentin
78.1
0.19


AL050179
tropomyosin 1
41.6
0.19



(alpha)


AJ005579
RD element
5.4
0.19


M80899
AHNAK nucleo-
11.6
0.19



protein


NM_004873
BCL2-associated
6.2
0.19



athanogene 5


X57138
H2A histone family,
58.3
0.20



member N


AF081281
lysophos-
7.2
0.22



pholipase I


U96759
von Hippel-Lindau
6.6
0.22



binding protein 1


U85977
Human ribosomal
342.6
0.22



protein L12



pseudogene,



partial cds


D13315
glyoxalase I
7.5
0.22


AC003007
Unknown
218.2
0.22


AB032980
RU2S
246.6
0.22


U40282
integrin-linked
10.1
0.22



kinase


U81984
endothelial PAS
4.7
0.23



domain protein 1


X91788
chloride channel,
9.6
0.23



nucleotide-



sensitive, 1A


AF018081
collagen, type
6.9
0.24



XVIII, alpha 1


L31881
nuclear factor
13.6
0.24



I/X (CCAAT-binding



transcription



factor)


X61123
B-cell trans-
5.3
0.24



location gene 1,



anti-proliferative


L32976
mitogen-activated
6.3
0.24



protein kinase



kinase kinase 11


M27749
immunoglobulin
5.5
0.24



lambda-like poly-



peptide 3


X57128
H3 histone family,
9.0
0.25



member C


X80907
phosphoinositide-
5.8
0.25



3-kinase, regulatory



subunit, polypeptide



2


Z34282

H. sapiens (MAR11)

100.6
0.26



MUC5AC mRNA for



mucin (partial)


X00089
H2A histone family,
4.7
0.26



member M


AL035252
CD39-like 2
4.6
0.26


X95289
PERB11 family member
27.5
0.26



in MHC class I region


AJ001340
U3 snoRNP-associated
4.0
0.26



55-kDa protein


NM_014161
HSPC071 protein
10.6
0.27


U60873
Unknown
6.4
0.27


X91247
thioredoxin reductase
84.4
0.27



1


AK001284
hypothetical protein
4.2
0.27



FLJ10422


U90840
synovial sarcoma,
6.6
0.27



X breakpoint 3


X53777
ribosomal protein L17
39.9
0.27


AL035067
Unknown
10.0
0.28


AL117665
DKFZP586M1824 protein
3.9
0.28


L14561
ATPase, Ca++
5.3
0.28



transporting,



plasma membrane 1


L19779
H2A histone family,
30.6
0.28



member O


AL049782
Unknown
285.3
0.28


X00734
tubulin, beta, 5
39.7
0.29


AK001761
retinoic acid
23.7
0.29



induced 3


U72661
ninjurin 1
4.4
0.29


S48220
deiodinase, iodo-
1,296.1
0.29



thyronine, type I


AF025304
EphB2
4.5
0.30


S82198
chymotrypsin C
4.1
0.30


Z80782
H2B histone family,
31.9
0.30



member K


X68194
synaptophysin-like
7.9
0.30



protein


AB028869
Unknown
4.2
0.30


AK000761
Unknown
4.3
0.30
















TABLE 57







Polynucleotides expressed to similar extents after stimulation by the


bacterial products LPS, LTA, and CpG DNA.


Bacterial products (100 ng/ml S. typhimurium LPS, 1 μg/ml S. aureus


LTA or 1 μM CpG) were shown to potently induce the expression of


several polynucleotides. Peptide was incubated with the RAW cells for


4 h and the RNA was isolated, converted into labeled cDNA probes and


hybridized to Atlas arrays. The intensity of control, unstimulated


cells is shown in the second column. The “Ratio LPS/LTA/CpG:


Control” column refers to the intensity of polynucleotide


expression in bacterial product-simulated cells divided by the intensity


of unstimulated cells.













Control
Ratio
Ratio
Ratio



Accession
Unstim.
LPS:
LTA:
CpG:
Protein/


number
Intensity
Control
Control
Control
polynucleotide















M15131
20
82
80
55
IL-1β


M57422
20
77
64
90
tristetraprolin


X53798
20
73
77
78
MIP-2α


M35590
188
50
48
58
MIP-1β


L28095
20
49
57
50
ICE


M87039
20
37
38
45
iNOS


X57413
20
34
40
28
TGFβ


X15842
20
20
21
15
c-rel proto-







oncopolynucleotide


X12531
489
19
20
26
MIP-1α


U14332
20
14
15
12
IL-15


M59378
580
10
13
11
TNFR1


U37522
151
6
6
6
TRAIL


M57999
172
3.8
3.5
3.4
NF-κB


U36277
402
3.2
3.5
2.7
I-κB (alpha







subunit)


X76850
194
3
3.8
2.5
MAPKAP-2


U06924
858
2.4
3
3.2
Stat 1


X14951
592
2
2
2
CD18


X60671
543
1.9
2.4
2.8
NF-2


M34510
5970
1.6
2
1.4
CD14


X51438
2702
1.3
2.2
2.0
vimentin


X68932
4455
0.5
0.7
0.5
c-Fms


Z21848
352
0.5
0.6
0.6
DNA polymerase


X70472
614
0.4
0.6
0.5
B-myb
















TABLE 58







Polynucleotides that were differentially regulated by the bacterial


products LPS, LTA, and CpG DNA.


Bacterial products (100 ng/ml S. typhimurium LPS, 1 μg/ml S. aureus


LTA or 1 μM CpG) were shown to potently induce the expression of


several polynucleotides. Peptide was incubated with the RAW cells for


4 h and the RNA was isolated, converted into labeled cDNA probes and


hybridized to Atlas arrays. The intensity of control, unstimulated


cells is shown in the second column. The “Ratio LPS/LTA/CpG: Control”


column refers to the intensity of polynucleotide expression in


bacterial product-simulated cells divided by the intensity of


unstimulated cells.













Unstim.
Ratio
Ratio
Ratio



Accession
Control
LPS:
LTA:
CpG:
Protein/


number
Intensity
Control
Control
Control
polynucleotide















X72307
20
1.0
23
1.0
hepatocyte







growth factor


L38847
20
1.0
21
1.0
hepatoma







transmembrane







kinase ligand


L34169
393
0.3
3
0.5
thrombopoietin


J04113
289
1
4
3
Nur77


Z50013
20
7
21
5
H-ras proto-







oncopolynucleotide


X84311
20
4
12
2
Cyclin A1


U95826
20
5
14
2
Cyclin G2


X87257
123
2
4
1
Elk-1


J05205
20
18
39
20
Jun-D


J03236
20
11
19
14
Jun-B


M83649
20
71
80
42
Fas 1 receptor


M83312
20
69
91
57
CD40L receptor


X52264
20
17
23
9
ICAM-1


M13945
573
2
3
2
Pim-1


U60530
193
2
3
3
Mad related







protein


D10329
570
2
3
2
CD7


X06381
20
55
59
102
Leukemia







inhibitory







factor (LIF)


X70296
20
6.9
13
22
Protease nexin 1







(PN-1)


U36340
20
38
7
7
CACCC







Box-binding







protein BKLF


S76657
20
11
6
7
CRE-BPI


U19119
272
10
4
4
interferon







inducible







protein 1
















TABLE 59







Confirmation of Table 57 and 58 Array Data.









Relative levels











Product
Untreated
LPS
LTA
CpG





CD14a
1.0
2.2 ± 0.4
1.8 + 0.2
1.5 ± 0.3


Vimentina
1.0
1.2 ± 0.07
1.5 ± 0.05
1.3 ± 0.07


Tristetraprolina
1.0
5.5 ± 0.5
5.5 ± 1.5
9.5 ± 1.5


LIFb
1.0
2.8 ± 1.2
2.7 ± 0.6
5.1 ± 1.6


NOc
8 ± 1.5
 47 ± 2.5
 20 ± 3
 21 ± 1.5






aTotal RNA was isolated from unstimulated RAW macrophage cells and cells treated for 4 hr with 100 ng/ml S. typhimurium LPS, 1 μg/ml S. aureus LTA, 1 μM CpG DNA or media alone and Northern blots were performed the membrane was probed for GAPDH, CD14, vimetin, and tristetraprolin as described previously [Scott et al]. The hybridization intensities of the Northern blots were compared to GAPDH to look for inconsistencies in loading. These experiments were repeated at least three times and the data shown is the average relative levels of each condition compared to media (as measured by densitometry) ± standard error.




bRAW 264.7 cells were stimulated with 100 ng/ml S. typhimurium LPS, 1 μg/ml S. aureus LTA, 1 μM CpG DNA or media alone for 24 hours. Protein lysates were prepared, run on SDS Page gels and western blots were performed to detect LIF (R & D Systems) These experiments were repeated at least three times and the data shown is the relative levels of LIF compared to media (as measured by densitometry) ± standard error.




cSupernatant was collected from RAW macrophage cells treated with 100 ng/ml S. typhimurium LPS, 1 μg/ml S. aureus LTA, 1 μM CpG DNA, or media alone for 24 hours and tested for the amount of NO formed in the supernatant as estimated from the accumulation of the stable NO metabolite nitrite with the Griess reagent as described previously [Scott, et al]. The data shown is the average of three experiments ± standard error.














TABLE 60







Pattern of Gene expression in A549 Human Epithelial cells


up-regulated by bacterial signalling molecules (LPS).



E. Coli O111:B4 LPS (100 ng/ml) increased the expression



of many polynucleotides in A549 cells as studied by


polynucleotide microarrays. LPS was incubated with the A549


cells for 4 h and the RNA was isolated. 5 μg total RNA was


used to make Cy3/Cy5 labelled cDNA probes and hybridised onto


Human Operon arrays (PRHU04). The example of polynucleotide


expression changes in LPS simulated cells represent a greater


than 2-fold intensity level change of LPS treated cells from


untreated cells.










Accession Number
Gene







AL050337
interferon gamma receptor 1



U05875
interferon gamma receptor 2



NM_002310
leukemia inhibitory factor receptor



U92971
coagulation factor II (thrombin)




receptor-like 2



Z29575
tumor necrosis factor receptor




superfamily member 17



L31584
Chemokine receptor 7



J03925
cAMP response element-




binding protein



M64788
RAP1, GTPase activating




protein



NM_004850
Rho-associated kinase 2



D87451
ring finger protein 10



AL049975
Unknown



U39067
eukaryotic translation initiation




factor 3, subunit 2



AK000942
Unknown



AB040057
serine/threonine protein




kinase MASK



AB020719
KIAA0912 protein



AB007856
FEM-1-like death receptor




binding protein



AL137376
Unknown



AL137730
Unknown



M90696
cathepsin S



AK001143
Unknown



AF038406
NADH dehydrogenase



AK000315
hypothetical protein FLJ20308



M54915
pim-1 oncogene



D29011
proteasome subunit, beta type, 5



AL034348
Unknown



D87076
KIAA0239 protein



AJ001403
mucin 5, subtype B,




tracheobronchial



J03925
integrin, alpha M










EXAMPLE 10
Altering Signaling to Protect Against Bacterial Infections

The Salmonella Typhimurium strain SL1344 was obtained from the American Type Culture Collection (ATCC; Manassas, Va.) and grown in Luria-Bertani (LB) broth. For macrophage infections, 10 ml LB in a 125 mL flask was inoculated from a frozen glycerol stock and cultured overnight with shaking at 37° C. to stationary phase. RAW 264.7 cells (1×105 cells/well) were seeded in 24 well plates. Bacteria were diluted in culture medium to give a nominal multiplicity of infection (MOI) of approximately 100, bacteria were centrifuged onto the monolayer at 1000 rpm for 10 minutes to synchronize infection, and the infection was allowed to proceed for 20 min in a 37° C., 5% CO2 incubator. Cells were washed 3 times with PBS to remove extracellular bacteria and then incubated in DMEM+10% FBS containing 100 μg/ml gentamicin (Sigma, St. Louis, Mo.) to kill any remaining extracellular bacteria and prevent re-infection. After 2 h, the gentamicin concentration was lowered to 10 μg/ml and maintained throughout the assay. Cells were pretreated with inhibitors for 30 min prior to infection at the following concentrations: 50 μM PD 98059 (Calbiochem), 50 μM U 0126 (Promega), 2 mM diphenyliodonium (DPI), 250 μM acetovanillone (apocynin, Aldrich), 1 mM ascorbic acid (Sigma), 30 mM N-acetyl cysteine (Sigma), and 2 mM NG-L-monomethyl arginine (L-NMMA, Molecular Probes) or 2 mM NG-D-monomethyl arginine (D-NMMA, Molecular Probes). Fresh inhibitors were added immediately after infection, at 2 h, and 6-8 h post-infection to ensure potency. Control cells were treated with equivalent volumes of dimethylsulfoxide (DMSO) per mL of media. Intracellular survival/replication of S. Typhimurium SL1344 was determined using the gentamicin-resistance assay, as previously described. Briefly, cells were washed twice with PBS to remove gentamicin, lysed with 1% Triton X-100/0.1% SDS in PBS at 2 h and 24 h post-infection, and numbers of intracellular bacteria calculated from colony counts on LB agar plates. Under these infection conditions, macrophages contained an average of 1 bacterium per cell as assessed by standard plate counts, which permitted analysis of macrophages at 24 h post-infection. Bacterial filiamentation is related to bacterial stress. NADPH oxidase and iNOS can be activated by MEK/ERK signaling. The results (Table 61) clearly demonstrate that the alteration of cell signaling is a method whereby intracellular Salmonella infections can be resolved. Thus since bacteria to up-regulate multiple genes in human cells, this strategy of blocking signaling represents a general method of therapy against infection.









TABLE 61







Effect of the Signaling Molecule MEK on Intracellular


Bacteria in IFN-gamma-primed RAW cells.








Treatmenta
Effectb





0
None


MEK inhibitor U 0126
Decrease bacterial filamentation



(bacterial stress)c Increase in the



number of intracellular S. Typhimurium


MEK inhibitor PD 98059
Decrease bacterial filamentation



(bacterial stress)c Increase in the



number of intracellular S. Typhimurium


NADPH oxidase inhibitord
Decrease bacterial filamentation



(bacterial stress)c Increase in the



number of intracellular S. Typhimurium









EXAMPLE 11
Anti-Viral Activity

SDF-1, a C-X-C chemokine is a natural ligand for HIV-1 coreceptor-CXCR4. The chemokine receptors CXCR4 and CCR5 are considered to be potential targets for the inhibition of HIV-1 replication. The crystal structure of SDF-1 exhibits antiparallel β-sheets and a positively charged surface, features that are critical in binding to the negatively charged extracellular loops of CXCR4. These findings suggest that chemokine derivatives, small-size CXCR4 antagonists, or agonists mimicking the structure or ionic property of chemokines may be useful agents for the treatment of X4 HIV-1 infection. It was found that the cationic peptides inhibited SDF-1 induced T-cell migration suggesting that the peptides may act as CXCR4 antagonists. The migration assays were performed as follows. Human Jurkat T cells were resuspended to 5×106/ml in chemotaxis medium (RPMI 1640/10 mM Hepes/0.5% BSA). Migration assays were performed in 24 well plates using 5 μm polycarbonate Transwell inserts (Costar). Briefly, peptide or controls were diluted in chemotaxis medium and placed in the lower chamber while 0.1 ml cells (5×106/ml) was added to the upper chamber. After 3 hr at 37° C., the number of cells that had migrated into the lower chamber was determined using flow cytometry. The medium from the lower chamber was passed through a FACscan for 30 seconds, gating on forward and side scatter to exclude cell debris. The number of live cells was compared to a “100% migration control” in which 5×105/ml cells had been pipetted directly into the lower chamber and then counted on the FACscan for 30 seconds. The results demonstrate that the addition of peptide results in an inhibition of the migration of Human Jurkat T-cells (Table 62) probably by influencing CXCR4 expression (Tables 63 and 64).









TABLE 62







Peptide inhibits the migration of human Jurkat-T cells:









Migration (%)












Positive
SDF-1
SDF-1 + SEQ 1D1
Negative


Experiment
control
(100 ng/ml)
(50 μg/ml)
control





1
100%
32%
0%
<0.01%


2
100%
40%
0%
0%
















TABLE 63







Corresponding polynucleotide array data to Table 56:











Polynu-


Ratio



cleotide/
Polynucleotide
Unstimulated
peptide:
Number


Protein
Function
Intensity
Unstimulated
Accession





CXCR-4
Chemokine
36
4
D87747



receptor
















TABLE 64







Corresponding FACs data to Tables 62 and 63:













Fold Increase in




Concentration
Protein Expression



Peptide
(μg/ml)
CXCR-4















SEQ ID NO: 1
10
No change



SEQ ID NO: 1
50
1.3 ± 0.03



SEQ ID NO: 1
100
1.6 ± 0.23



SEQ ID NO: 3
100
1.5 ± 0.2 










EXAMPLE 12
Synergistic Combinations

Methods and Materials



S. aureus was prepared in phosphate buffered solution (PBS) and 5% porcine mucin (Sigma) to a final expected concentration of 1-4×107 CFU/ml. 100 μl of S. aureus (mixed with 5% porcine mucin) was injected intraperitoneally (IP) into each CD-1 mouse (6˜8 weeks female weighing 20-25 g (Charles River)). Six hours after the onset of infection, 100 μl of the peptide was injected (50-200 μg total) IP along with 0.1 mg/kg Cefepime. After 24 hours, animals were sacrificed and heart puncture was performed to remove 100 μl of blood. The blood was diluted into 1 ml PBS containing Heparin. This was then further diluted and plated for viable colony counts on Mueller-Hinton agar plates (10−1, 10−2, 10−3, & 10−4). Viable colonies, colony-forming units (CFU), were counted after 24 hours. Each experiment was carried out a minimum of three times. Data is presented as the average CFU±standard error per treatment group (8-10 mice/group).


Experiments were carried out with peptide and sub-optimal Cefepime given 6 hours after the onset of systemic S. aureus infection (FIG. 1). The data in FIG. 1 is presented as the mean±standard error of viable counts from blood taken from the mice 24 hrs after the onset of infection. The combination of sub optimal antibiotic (cefepime) dosing and SEQ ID NO: 7 resulted in improved therapeutic efficacy. The ability of the peptides to work in combination with sub-optimal concentrations of an antibiotic in a murine infection model is an important finding. It suggests the potential for extending the life of antibiotics in the clinic and reducing incidence of antibiotic resistance.


SEQ ID NO: 1, as an example, induced phosphorylation and activation of the mitogen activated protein kinases, ERK1/2 and p38 in human peripheral blood-derived monocytes and a human bronchial epithelial cell line but not in B- or T-lymphocytes. Phosphorylation was not dependent on the G-protein coupled receptor, FPRL-1, which was previously proposed to be the receptor for SEQ ID NO: 1-induced chemotaxis on human monocytes and T cells. Activation of ERK1/2 and p38 was markedly increased by the presence of granulocyte macrophage-colony stimulating factor (GM-CSF), but not macrophage-colony stimulating factor (M-CSF). Exposure to SEQ ID NO: 1 also led to the activation of Elk-1, a transcription factor that is downstream of and activated by phosphorylated ERK1/2, as well as the up-regulation of various Elk-1 controlled genes. The ability of SEQ ID NO: 1 to signal through these pathways has broad implications in immunity, monocyte activation, proliferation and differentiation.


Methods and Materials


SEQ ID NO: 1 (sequence LLGDFFRKSKEKIGKEFKRIVQRIKDFLRNLVPRTES), was synthesized by Fmoc [(N-(9-fluorenyl) methoxycarbonyl)] chemistry at the Nucleic Acid/Protein Synthesis (NAPS) Unit at UBC. Human recombinant granulocyte-macrophage colony-stimulating factor (GM-CSF), interleukin-4 (IL-4) and macrophage colony-stimulating factor (M-CSF) were purchased from Research Diagnostics Inc. (Flanders, N.J., USA). Pertussis toxin was supplied by List Biological Laboratories Inc. (Campbell, Calif., USA).


Blood monocytes were prepared using standard techniques. Briefly, 100 ml of fresh human venous blood was collected in sodium heparin Vacutainer collection tubes (Becton Dickinson, Mississauga, ON, Canada) from volunteers according to UBC Clinical Research Ethics Board protocol C02-0091. The blood was mixed, at a 1:1 ratio, with RPMI 1640 media [supplemented with 10% v/v fetal calf serum (FBS), 1% L-glutamine, 1 nM sodium pyruvate] in an E-toxa-clean (Sigma-Aldrich, Oakville, ON, Canada) washed, endotoxin-free bottle. PBMC were separated using Ficoll-Paque Plus (Amersham Pharmacia Biotech, Baie D'Urfé, PQ, Canada) at room temperature and washed with phosphate buffered saline (PBS). Monocytes were enriched with the removal of T-cells by rosetting with fresh sheep red blood cells (UBC animal care unit) pre-treated with Vibrio cholerae neuraminidase (Calbiochem Biosciences Inc., La Jolla, Calif., USA) and repeat separation by Ficoll Paque Plus. The enriched monocytes were washed with PBS, then cultured (approximately 2-3×106 per well) for 1 hour at 37° C. followed by the removal of non-adherent cells; monocytes were >95% pure as determined by flow cytometry (data not shown). B-lymphocytes were isolated by removing non-adherent cells and adding them to a new plate for one hour at 37° C. This was repeated a total of three times. Any remaining monocytes adhered to the plates, and residual non-adherent cells were primarily B cells. Cells were cultured in Falcon tissue culture 6-well plates (Becton Dickinson, Mississauga, ON, Canada). The adherent monocytes were cultured in 1 ml media at 37° C. in which SEQ ID NO: 1 and/or cytokines dissolved in endotoxin-free water (Sigma-Aldrich, Oakville, ON, Canada) were added. Endotoxin-free water was added as a vehicle control. For studies using pertussis toxin the media was replaced with 1 ml of fresh media containing 100 ng/ml of toxin and incubated for 60 min at 37° C. SEQ ID NO: 1 and cytokines were added directly to the media containing pertussis toxin. For the isolation of T lymphocytes, the rosetted T cells and sheep red blood cells were resuspended in 20 ml PBS and 10 ml of distilled water was added to lyse the latter. The cells were then centrifuged at 1000 rpm for 5 min after which the supernatant was removed. The pelleted T cells were promptly washed in PBS and increasing amounts of water were added until all sheep red blood cells had lysed. The remaining T cells were washed once in PBS, and viability was confirmed using a 0.4% Trypan blue solution. Primary human blood monocytes and T cells were cultured in RPMI 1640 supplemented with 10% v/v heat-inactivated FBS, 1% v/v L-glutamine, 1 nM sodium pyruvate (GIBCO Invitrogen Corporation, Burlington, ON, Canada). For each experiment between two and eight donors were used.


The simian virus 40-transformed, immortalized 16HBE4o- bronchial epithelial cell line was a generous gift of Dr. D. Gruenert (University of California, San Francisco, Calif.). Cells were routinely cultured to confluence in 100% humidity and 5% CO2 at 37° C. They were grown in Minimal Essential media with Earles' salts (GIBCO Invitrogen Corporation, Burlington, ON, Canada) containing 10% FBS (Hyclone), 2 mM L-glutamine. For experiments, cells were grown on Costar Transwell inserts (3-μm pore size, Fischer Scientific) in 24-well plates. Cells were seeded at 5×104 cells per 0.25 ml of media on the top of the inserts while 0.95 ml of media was added to the bottom of the well and cultured at 37° C. and 5% CO2. Transmembrane resistance was measured daily with a Millipore voltohmeter and inserts were used for experiments typically after 8 to 10 days, when the resistance was 500-700 ohms. The cells were used between passages 8 and 20.


Western Immunoblotting


After stimulation, cells were washed with ice-cold PBS containing 1 mM vanadate (Sigma). Next 125 μl of RIPA buffer (50 mM Tris-HCl, pH 7.4, NP-40 1%, sodium deoxycholate 0.25%, NaCl 150 mM, EDTA 1 mM, PMSF 1 mM, Aprotinin, leupeptin, pepstatin 11 g/ml each, sodium orthovanadate 1 mM, NaF 1 mM) was added and the cells were incubated on ice until they were completely lysed as assessed by visual inspection. The lysates were quantitated using a BCA assay (Pierce). 30 μg of lysate was loaded onto 1.5 mm thick gels, which were run at 100 volts for approximately 2 hours. Proteins were transferred to nitrocellulose filters for 75 min at 70 V. The filters were blocked for 2 hours at room temperature with 5% skim milk in TBST (10 mM Tris-HCl pH 8, 150 mM NaCl, 0.1% Tween-20). The filters were then incubated overnight at 4° C. with the anti-ERK1/2-P or anti-p38-P (Cell Signaling Technology, Massachusetts) monoclonal antibodies. Immunoreactive bands were detected using horseradish peroxidase-conjugated sheep anti-mouse IgG antibodies (Amersham Pharmacia, New Jersey) and chemiluminescence detection (Sigma, Missouri). To quantify bands, the films were scanned and then quantified by densitometry using the software program, ImageJ. The blots were reprobed with a β-actin antibody (ICN Biomedical Incorporated, Ohio) and densitometry was performed to allow correction for protein loading.


Kinase Assay


An ERK1/2 activity assay was performed using a non-radioactive kit (Cell Signaling Technology). Briefly, cells were treated for 15 min and lysed in lysis buffer. Equal amounts of proteins were immunoprecipitated with an immobilized phospho-ERK1/2 antibody that reacts only with the phosphorylated (i.e. active) form of ERK1/2. The immobilized precipitated enzymes were then used for the kinase assay using Elk-1 followed by Western blot analysis with antibodies that allow detection and quantitation of phosphorylated substrates.


Quantification of IL-8


Human IL-8 from supernatants of 16HBE40-cells was measured by using the commercially available enzyme-linked immunosorbent assay kit (Biosource) according to the manufacturer's instructions.


Semiquantitative RT-PCR


Total RNA from two independent experiments was isolated from 16HBE4o- cells using RNaqueous (Ambion) as described by the manufacturer. The samples were DNase treated, and then cDNA synthesis was accomplished by using a first-strand cDNA synthesis kit (Gibco). The resultant cDNAs were used as a template in PCRs for various cytokine genes MCP-1 (5′-TCATAGCAGCCACCTTCATTC-3′ (SEQ ID NO:59), 5′-TAGCGCAGATTCTTGGGTTG-3 (SEQ ID NO:60)), MCP-3, (5′-TGTCCTTTCTCAGAGTGGTTCT-3′ (SEQ ID NO:61), 5′-TGCTTCCATAGGGACATCATA-3′ (SEQ ID NO:62)) IL-6, (5′-ACCTGAACCTTCCAAAGATGG-3′ (SEQ ID NO:63), 5′-GCGCAGAATGAGATGAGTTG-3′ (SEQ ID NO:64)), and IL-8, (5′-GTGCAGAGGGTTGTGGAGAAG-3′ (SEQ ID NO:65), 5′-TTCTCCCGTGCAATATCTAGG-3′ (SEQ ID NO:66)) Each RT-PCR reaction was performed in at least duplicate. Results were analysed in the linear phase of amplification and normalized to the housekeeping control, glyceraldehyde-3-phosphate dehydrogenase. Reactions were verified for RNA amplification by including controls without reverse transcriptase.


Results


A. Peptides induce ERK1/2 and p38 phosphorylation in peripheral blood derived monocytes.


To determine if peptide induced the activation of the MAP kinases, ERK1/2 and/or p38, peripheral blood derived monocytes were treated with 50 μg/ml SEQ ID NO: 1 or water (as a vehicle control) for 15 min. To visualize the activated (phosphorylated) form of the kinases, Western blots were performed with antibodies specific for the dually phosphorylated form of the kinases (phosphorylation on Thr202+Tyr204 and Thr180+Tyr182 for ERK1/2 and p38 respectively). The gels were re-probed with an antibody for β-actin to normalize for loading differences. In all, an increase in phosphorylation of ERK1/2 (n=8) and p38 (n=4) was observed in response to SEQ ID NO: 1 treatment (FIG. 2).



FIG. 2 shows exposure to SEQ ID NO: 1 induces phosphorylation of ERK1/2 and p38. Lysates from human peripheral blood derived monocytes were exposed to 50 μg/ml of SEQ ID NO: 1 for 15 minutes. A) Antibodies specific for the phosphorylated forms of ERK and p38 were used to detect activation of ERK1/2 and p38. All donors tested showed increased phosphorylation of ERK1/2 and p38 in response to SEQ ID NO: 1 treatment. One representative donor of eight. Relative amounts of phosphorylation of ERK (B) and p38(C) were determined by dividing the intensities of the phosphorylated bands by the intensity of the corresponding control band as described in the Materials and Methods.


B. Peptide induced activation of ERK1/2 is greater in human serum than in fetal bovine serum.


We were able to demonstrate that LL-37 induced phosphorylation of ERK1/2 did not occur in the absence of serum and the magnitude of phosphorylation was dependent upon the type of serum present such that activation of ERK1/2 was far superior in human serum (HS) than in fetal bovine serum (FBS).



FIG. 3 shows LL-37 induced phosphorylation of ERK1/2 does not occur in the absence of serum and the magnitude of phosphorylation is dependent upon the type of serum present. Human blood derived monocytes were treated with 50 μg/ml of LL-37 for 15 minutes. Lysates were run on a 12% acrylamide gel then transferred to nitrocellulose membrane and probed with antibodies specific for the phosphorylated (active) form of the kinase. To normalize for protein loading, the blots were reprobed with β-actin. Quantification was done with ImageJ software. The FIG. 3 inset demonstrates that LL-37 is unable to induce MAPK activation in human monocytes under serum free conditions. Cells were exposed to 50 mg/ml of LL-37 (+), or endotoxin free water (−) as a vehicle control, for 15 minutes. (A) After exposure to LL-37 in media containing 10% fetal calf serum, phosphorylated ERK1/2 was detectable, however, no phosphorylation of ERK1/2 was detected in the absence of serum (n=3). (B) Elk-1, a transcription factor downstream of ERK1/2, was activated (phosphorylated) upon exposure to 50 μg/ml of LL-37 in media containing 10% fetal calf serum, but not in the absence of serum (n=2).


C. Peptide induced activation of ERK1/2 and p38 is dose dependent and demonstrates synergy with GM-CSF.


GM-CSF, IL-4, or M-CSF (each at 100 ng/ml) was added concurrently with SEQ ID NO: 1 and phosphorylation of ERK1/2 was measured in freshly isolated human blood monocytes. ERK1/2 phosphorylation was evident when cells were treated with 50 μg/ml of SEQ ID NO: 1 (8.3 fold increase over untreated, n=9) but not at lower concentrations (n=2). In the presence of 100 ng/ml GM-CSF, SEQ ID NO: 1-induced ERK1/2 phosphorylation increased markedly (58 fold greater than untreated, n=5). Furthermore, in the presence of GM-CSF, activation of ERK1/2 occurred in response to concentrations of 5 and 10 μg/ml of SEQ ID NO: 1, respectively, in the two donors tested (FIG. 4). This demonstrates that SEQ ID NO: 1 induced activation of ERK1/2 occurred at a lower threshold in the presence of GM-CSF, a cytokine found locally at sites of infection.



FIG. 4 shows LL-37 induced activation of ERK1/2 occurs at lower concentrations and is amplified in the presence of certain cytokines. When freshly isolated monocytes were stimulated in media containing both GM-CSF (100 ng/ml) and IL-4 (100 ng/ml) LL-37 induced phosphorylation of ERK1/2 was apparent at concentrations as low as 5 μg/ml. This synergistic activation of ERK1/2 seems to be due primarily to GM-CSF.


D. Activation of ERK1/2 leads to transcription of Elk-1 controlled genes and secretion of IL-8


IL-8 release is governed, at least in part, by activation of the ERK1/2 and p38 kinases. In order to determine if peptide could induce IL-8 secretion the human bronchial cell line, 16HBE4o-, was grown to confluency in Transwell filters, which allows for cellular polarization with the creation of distinct apical and basal surfaces. When the cells were stimulated with 50 μg/ml of SEQ ID NO: 1 on the apical surface for four hours a statistically significant increase in the amount of IL-8 released into the apical supernatant was detected (FIG. 5). To determine the downstream transcriptional effects of peptide-induced MAP kinase activation, the expression of genes known to be regulated by ERK1/2 or p38 was assessed by RT-PCR. RT-PCR was performed on RNA isolated from 16HBE4o- cells, treated for four hours with 50 μg/ml of SEQ ID NO: 1 in the presence of serum, from two independent experiments. MCP-1 and IL-8 have been demonstrated to be under the transcriptional control of both ERK1/2 and p38, consistent with this they are up-regulated 2.4 and 4.3 fold respectively. Transcription of MCP-3 has not previously been demonstrated to be influenced by the activation of the mitogen activated protein kinases, consistent with this, expression is not affected by peptide treatment. (FIG. 5). These data are consistent with the hypothesis that activation of the activation of the ERK1/2 and p38 signaling pathways has functional effects on transcription of cytokine genes with immunomodulatory functions. The inset to FIG. 3B also demonstrates that peptide induced the phosphorylation of transcription factor Elk-1 in a serum dependent manner.



FIG. 5 shows peptide affects both transcription of various cytokine genes and release of IL-8 in the 16HBE4o- human bronchial epithelial cell line. Cells were grown to confluency on a semi-permeable membrane and stimulated on the apical surface with 50 μg/ml of SEQ ID NO: 1 for four hours. A) SEQ ID NO: 1 treated cells produced significantly more IL-8 than controls, as detected by ELISA in the supernatant collected from the apical surface, but not from the basolateral surface. Mean±SE of three independent experiments shown, asterisk indicates p=0.002. B) RNA was collected from the above experiments and RT-PCR was performed. A number of cytokine genes known to be regulated by either ERK1/2 or p38 were up-regulated upon stimulation with peptide. The average of two independent experiments is shown.


Although the invention has been described with reference to the presently preferred embodiment, it should be understood that various modifications can be made without departing from the spirit of the invention. Accordingly, the invention is limited only by the following claims.

Claims
  • 1. A method of treating inflammation in a subject having or at risk of having inflammation comprising administering to the subject a therapeutically effective amount of the peptide as set forth in SEQ ID NO:7.
  • 2. The method of claim 1, wherein the peptide contains at least one amino acid that is a D-enantiomer.
  • 3. The method of claim 1, wherein the peptide is cyclic.
  • 4. The method of claim 1, wherein the peptide sequence is reversed.
  • 5. The method of claim 1, wherein the peptide is administered in combination with an antibiotic.
  • 6. The method of claim 1, wherein the peptide is administered in combination with granulocyte-macrophage colony stimulating factor (GM-CSF).
  • 7. The method of claim 5, wherein the antibiotic is selected from aminoglycosides, penicillins, cephalosporins, cerbacephems, cephamycins, chloramphenicols, glycylcyclines, licosamides, aminocyclitols, cationic antimicrobial peptides, lipopeptides, poymyxins, streptogramins, oxazoladinones, lincosamides, fluoroquinolones, carbapenems, tetracyclines, macrolides, beta-lactams carbapenems, monobactams, quinolones, tetracyclines, or glycopeptides.
  • 8. A method of treating sepsis in a subject having or at risk of having sepsis comprising administering to the subject a therapeutically effective amount of the peptide as set forth in SEQ ID NO:7.
  • 9. The method of claim 8, wherein the peptide contains at least one amino acid that is a D-enantiomer.
  • 10. The method of claim 8, wherein the peptide is cyclic.
  • 11. The method of claim 8, wherein the peptide sequence is reversed.
  • 12. The method of claim 8, wherein the peptide is administered in combination with an antibiotic.
  • 13. The method of claim 8, wherein the peptide is administered in combination with granulocyte-macrophage colony stimulating factor (GM-CSF).
  • 14. The method of claim 12, wherein the antibiotic is selected from aminoglycosides, penicillins, cephalosporins, cerbacephems, cephamycins, chioramphenicols, glycylcyclines, licosamides, aminocyclitols, cationic antimicrobial peptides, lipopeptides, poymyxins, streptogramins, oxazoladinones, lincosamides, fluoroquinolones, carbapenems, tetracyclines, macrolides, beta-lactams carbapenems, monobactams, quinolones, tetracyclines, or glycopeptides.
RELATED APPLICATION DATA

This application claims priority under 35 USC 120 to U.S. patent application Ser. No. 10/308,905, filed Dec. 2, 2002, and under 35 USC 119(e) to U.S. Patent Application Ser. No. 60/336,632, filed Dec. 3, 2001, herein incorporated by reference in their entirety.

US Referenced Citations (2)
Number Name Date Kind
6040435 Karunarante et al. Mar 2000 A
20020064501 Khan et al. May 2002 A1
Foreign Referenced Citations (3)
Number Date Country
2456477 Feb 2003 CA
2468907 Jun 2003 CA
WO0012528 Mar 2000 WO
Related Publications (1)
Number Date Country
20040180038 A1 Sep 2004 US
Continuation in Parts (1)
Number Date Country
Parent 10308905 Dec 2002 US
Child 10661471 US