This application is a U.S. National Phase of International Patent application No.: PCT/IB03/00280, filed Jan. 10, 2003, designating the U.S. and published in English as WO 03/098991 on Dec. 4, 2003.
The present invention relates generally to methods for regulating tight junction sealing, and more particularly to the use of proteins and peptides that inhibit cell adhesion and the formation of tissue permeability barriers.
The Tight Junction (TJ)
In multicellular organisms fluids with different molecular compositions (urine, milk, gastric juice, blood etc.) are contained in compartments delineated by epithelia (e.g. renal tubules) and endothelia (blood vessels). These cellular sheets constitute the frontier between the organism internal milieu and the compartments' contents. Therefore in order for components of the blood to enter a given tissue, they must first traverse from the lumen of the blood vessel through the endothelial cells of that vessel. In case of substances that enter the body via the gut, they must first pass the barrier formed by the epithelial cells that line the cavity, and to enter the blood via the skin, both epithelial and endothelial sheets must be crossed.
Although cell-cell adhesion is crucial to develop tissues and for maintaining discrete compartments within the organism, there are conditions in which a controlled regulation of cell adhesion is desirable. Such situation is encountered when the barrier formed by the epithelia or endothelia creates difficulties for the delivery of drugs to specific tissues and tumors within the body.
The passage of substances through endothelia and epithelia proceeds through two parallel routes: a transcellular and a paracellular pathway. In the former ions and molecules employ for their transit channels, carriers and pumps located in the plasma membrane of epithelia and endothelia. Attempts to facilitate the passage of drugs to specific tissues within the body have generally relied on such specific channels or carriers that in vivo transport molecules. However such methods have been largely inefficient due to low endogenous transport rates or to their poor functioning with applied drugs.
To overcome these impediments transport through the paracellular pathway has been assayed. This route consists of the intercellular space existent between adjacent cells and is regulated by the tight junction (TJ).
The TJ is a structure that surrounds the cellular borders at the limit between the apical and lateral membranes. It displays two fundamental roles: 1) as a gate that regulates the passage of ions, water and molecules through the paracellular route; and 2) as a fence that blocks the lateral diffusion within the plane of the membrane of lipids and proteins. This fence is crucial since it maintains the polarized distribution of lipids and proteins between the apical and basolateral to plasma membrane (Cereijido et al., 1998).
On ultrathin section electron micrographs, TJ are viewed as a series of fusion points “kisses” between the outer leaflets of the membranes of adjacent cells. At these kissing points, the intercellular space is completely obliterated. On freeze-fracture replica electron micrographs TJ appear at the plasma membrane as a network of continuous and anastomosing filaments on the protoplasmic face (P), with complementary grooves on the exoplasmic face (E) (Gonzalez-Mariscal et al., 2001).
Two models have been proposed to explain the chemical nature of TJ. In the protein model, TJ strands are formed by integral membrane proteins that associate with a partner in the apposing membrane of the adjacent cell. In the lipid model instead, TJ filaments are supposed to be formed of inverted cylindrical micelles (Kachar et al., 1982). Although the lipid content of the bilayer appears to be important for the formation of TJ, the discovery in recent years of TJ specific integral proteins gives strong support to the protein model of TJ.
TJ are constituted by a complex array of cortical and integral proteins. Of the former, 16 different molecules have so far been identified. Some function as scaffolds, that link the integral proteins of the TJ to the actin cytoskeleton (ZO-1, ZO-2, ZO-3 and cingulin) (Citi et al., 1988; Gonzalez-Mariscal et al., 2000), or as crosslinkers of transmembrane junctional proteins (MUPP1, MUPP2 and MUPP3) (Hamazaki et al., 2002). Others are involved in vesicular trafficking to the TJ (Rab13, Rab3b) (Zahraoui et al., 1994), in cell signaling through their association to kinases (Par3 and Par 6) (Izumi et al., 1998) and Ras (e.g. AF6) (Yamamoto et al., 1997), and in gene expression by their specific binding to transcription factors (ZO-1 and ZO-2) (Balda et al., 2000). The role of several other cortical proteins found at the TJ still remains unclear [e.g. Jeap (Nishimura et al., 2002), Pilt (Kawabe et al., 2001), Barmotin (Zhong et al., 1993) and symplekin (Keon et al., 1996)].
At the TJ three integral proteins are found: occludin, claudins and JAM. Occludin was the first one identified (Furuse et al., 1993). It is considered a component of TJ strands, since immuno replica electron microscopy with specific antibodies revealed its labeling within the TJ filaments (Saitou et al., 1997). Furthermore, when introduced into L fibroblasts, that lack TJ, structures that resemble TJ strands were formed.
Occludin comprises four transmembrane regions, two extracellular loops of similar size, and three cytoplasmic domains: one intracellular short turn, a small amino terminal domain and a long carboxyl terminal region.
Several lines of evidence assign occludin an important role at TJ. Thus, the over-expression of mutant forms of this protein in epithelial cells leads to changes in the barrier and fence function of TJ (Balda et al., 1996b; McCarthy et al., 1996) (Bamforth et al., 1999) and in the transepithelial migration of neutrophils (Huber et al., 2000). (Lacaz-Vieira et al., 1999). (Medina et al., 2000) (Vietor et al., 2001) Additionally, a correlation has been observed in several tissues between the expression of occludin and the degree of sealing of epithelia evaluated by transepithelial electrical resistance (TER) and permeability to extracellular tracers. Despite this evidence the physiological function of occludin is not completely understood. In this regard it should be highlighted that embryonic cells and mice carrying a null mutation in the occludin gene are still able to form well developed TJ (Saitou et al., 1998), although the animals display postnatal growth retardation and histological abnormalities in several tissues (Saitou et al., 2000).
More recently other integral proteins named claudin 1 and claudin 2 were identified as TJ constituents. By data base searching and cDNA and genomic cloning the claudin family has expanded to 20 members (Tsukita et al., 2001). All claudins encode 20 to 27 kDa proteins with four transmembrane domains; two extracellular loops where the first one is significantly longer than the second one, and a short carboxyl intracellular tail.
When claudins were transfected into fibroblasts, they conferred cell-cell aggregation activity, concentrated at the cells contact points and formed networks of filaments that looked like TJ strands. Furthermore, in immunoreplica electron microscopy antibodies against different claudins selectively labeled the TJ filaments of epithelia. All this evidence has let to consider claudins as the backbone of TJ strands.
Different claudin species are capable of generating different freeze fracture patterns. Thus, claudins 1 or 3 form TJ with continuous smooth fibrils on the protoplasmic surface (P face) of the replicas (Furuse et al., 1999), whereas claudins 2 or 5 generate junctions with discontinuous chains of particles associated to the exoplasmic face (E face) (Morita et al., 1999b). Claudin 11 instead constitutes parallel TJ strands on the P face that scarcely branch (Morita et al., 1999a).
Heterogeneous claudins can interact within a single TJ strand and their particular combination gives rise to different freeze fracture patterns. Thus strands formed with claudins 1 and 3 are continuous and associated to the P face, while strands formed with claudins 1 and 2 or 3 and 2 have evenly scattered particles in the E face grooves. At the paracellular space the extracellular loops of different species of claudins belonging to neighboring cells can also interact, except in some combinations (Furuse et al., 1999).
The expression of different claudins in epithelia and endothelia might give rise to the ample variety in permeability and paracellular ionic selectivity displayed in distinct tissues. The nephron that displays a wide range of TER along the different tubular segments (6 Ωcm2 in proximal Vs 870-2000 Ωcm2 in collecting duct) expresses almost all claudins, yet each one is restricted to a particular segment (Enck et al., 2001; Kiuchi-Saishin et al., 2002) (Reyes et al., 2002): claudins 5 and 15 at endothelia, claudins 2, 10 and 11 at the proximal segment, claudins 1, 3 and 8 at de distal tubule and claudins 1, 3, 4 and 8 at the collecting segment.
The onset of expression for different claudins is developmentally regulated. Thus, claudin 5 is transiently expressed during the development of the retinal pigment epithelium (Kojima et al., 2002), claudin 11 is expressed in Sertoli cells, immediately after the peak of expression of the sex determining region in the Y gene (Hellani et al., 2000), and claudin 6 is found in embryonic stem cells committed to the epithelial fate (Turksen et al., 2001).
Claudin 16 is mutated in human patients with hypomagnesemia hypercalciuria syndrome (HHS) (Simon et al., 1999). These patients manifest a selective defect in paracellular Mg2+ and Ca2+ reabsorption in the thin ascending limb of Henle's, with intact NaCl resorption ability at this site (Blanchard et al., 2001). Therefore claudin 16 appears to function as a paracellular channel selective for Mg2+ and Ca2+ (Goodenough et al., 1999). Other claudins are also proved ionic selective. Thus when claudin 4 is transfected into epithelial cells, the paracellular conductance decreases through a selective decrease in Na+ permeability without a significant effect on Cl− permeability (Van Itallie et al., 2001).
More than two decades ago Claude observed that the TER increases with the number of TJ strands, not in a linear fashion as would be expected from the addition of resistors in series, but exponentially (Gonzalez-Mariscal et al., 2001). To explain this relationship a proposal arose suggesting the existence of ion channels or pores within the TJ strands (Claude 1978; Gonzalez-Mariscal et al., 2001). Now that claudins have begun to be characterized, it appears that the ionic selectivity at the TJ could be determined by the specific claudin isoforms that constitute the pores or channels of TJ strands. On analyzing the extracellular loops of claudins an enormous variability in distribution and number of charged residues is found. For example the isoelectric points of the first loop range from 4.17 in claudin 16 to 10.49 in claudin 14, and in the second extracellular loop from 4.05 in claudins 2, 7, 10 and 14 to 10.5 in claudin 13. Based on the pKIs of the extracellular loops sequences, claudin 16 is a cation pore, a proposal that agrees with the observed effect of its mutation in human patients, whereas claudins 4, 11 and 17 are anion pores (Mitic et al., 2001).
Variations in the tightness of the TJ appear to be determined by the combination and mixing ratios of different claudin species. Thus when MDCK cells expressing claudin 1 and 4 were incubated with a claudin 4 binding peptide (Clostridium perfringens enterotoxin, CPE), claudin 4 was selectively removed from TJ, generating a significant decrease in TER (Sonoda et al., 1999). Furthermore, when claudin-2 was introduced into high resistance MDCK cells (MDCK I), TJ became leaky and morphologically similar to those found in low resistance cells (MDCK II), which normally contain claudin 2 (Furuse et al., 2001).
The role of claudins in carcinogenesis is controversial. Claudin 4 is over-expressed in pancreatic cancer and gastrointestinal tumors, and the treatment with TGFβ or CPE, the enterotoxin that specifically targets claudin 4, leads to a significant reduction of tumor growth (Michl et al., 2001). In contrast, other claudins remain low or undetectable in a number of tumors and cancer cell lines. For example Claudin 1 expression is lost in most human breast cancers without presenting alterations in its promoter or coding sequences (Hoevel et al., 2002; Kramer et al., 2000), and claudin 7 is downregulated in head and neck squamous cell carcinomas (Al Moustafa et al., 2002).
The crucial role of certain claudins in the gate function of epithelia is highlighted by the observation that in claudin 1 deficient mice the epidermis looses it barrier function, leading to dehydration of the animals, wrinkled skin and death within 1 day of birth (Furuse et al., 2002). In these mice occludin was still expressed at all layers of the stratified epithelia, and claudin 4 remained concentrated at the second and third layers of the stratum granulosum. Therefore in the epidermis claudin-1 constitutes an indispensable element for the barrier function of TJ.
The last integral proteins of the TJ are JAM and the three JAM like proteins (Palmeri et al., 2000). They belong to the immunoglobulin superfamily, have a single transmembrane segment and their extracellular portion consists of two folded immunoglobulin like domains. JAM appears not to be a constituent of TJ strands since its transfection into fibroblasts does not generate the appearance of filaments. JAM plays a role in cross-linking occludin and claudins, as well as in the transepithelial and transendothelial migration of monocytes (Martin-Padura et al., 1998).
Physiological and Pathological Regulation of Tight Junctions.
Epithelia and endothelia encounter diverse physiological and pathological conditions that provoke changes in the degree of sealing of TJ. These variations in TJ permeability are regulated by a broad spectrum of factors such as calcium (Gonzalez-Mariscal et al., 1990; Martinez-Palomo et al., 1980), hormones, cytokines and growth factors, activation of G proteins and phospholipases, generation of CAMP and diacylglicerol (Balda et al., 1991), and by the phosphorylation of TJ proteins by different kinases (Avila-Flores et al., 2001; Balda et al., 1996a; Sakakibara et al., 1997).
In recent years the action of enteric pathogens (e.g. Escherichia coli, Salmonella typhimurium) and bacterial toxins upon TJ has been recognized (Hecht2002). Thus, treatment with Clostridium perfringens enterotoxin (CPE) destroys TJ and TER by specifically removing claudins 3 and 4 from the strands (Sonoda et al., 1999), while the hemaglutinin and ZOT toxin of Vibrio cholera increase epithelial permeability due to their respective action upon occludin (Wu et al., 2000) and PKC (Fasano et al., 1995). From an evolutionary point of view, bacteria that counted with toxins that mimicked endogenous modulators of TJ were in advantage since by traversing epithelial barriers they gained access to new environments. This appears to be the case for Vibrio cholera, as an endogenous protein that modulates TJ has been recently identified employing antibodies generated against ZOT toxin (Fasano1999; Wang et al., 2000).
Rotaviruses
Rotaviruses are the leading cause of morbidity and mortality caused by gastroenteritis in children less than 2 years old. These viruses of the Reoviridae family have a genome composed of 11 double stranded segments of RNA, surrounded by three concentric layers of protein. The outermost layer is smooth and formed by a 37 kDa glycoprotein named VP7. From it around 60 spikes formed of an 88 kDa protein named VP4, project outwards (Estes1996).
VP4 is essential for early virus-cell interactions, since it participates in receptor binding and cell penetration. In fact the infectivity of rotaviruses is dependent upon the specific cleavage by trypsin of VP4 into peptides VP5 and VP8 (Almeida et al., 1978; Espejo et al., 1981).
In vivo rotavirus infection is restricted to ileum microvellosities (Kapikian et al., 1996). In vitro infectiveness is less restrictive as a broad variety of renal and intestinal epithelial cell lines are susceptible to rotavirus infection (Estes et al., 1989).
Some rotaviruses bind to a cell-surface receptor containing sialic acid (SA), while others (e.g. human rotavirus) do not require SA for infection (Fukudome et al., 1989). Therefore binding to SA appears not to be an essential step for rotavirus infection. Furthermore, association to a secondary SA independent receptor can overcome the initial interaction of certain rotavirus with SA. SA dependent rhesus rotavirus (RRV) initially bind to the cell through VP8 (Fiore et al., 1991; Isa et al., 1997), while variants of RRV which no longer depend on the presence of SA (e.g. nar3), interact with the cell through VP5 (Zarate et al., 2000b). The comparative characterization of many strains of animal and human origin, including RRV, its SA independent variant nar3, and the human rotavirus strain Wa, has shown that rotavirus contain integrin ligand sequences (Coulson et al., 1997) (Guerrero et al., 2000) and that α2β1 integrin is used as a primary cell receptor by nar3, and by RRV in a secondary interaction, subsequent to its initial contact with the SA containing cell receptor (Zarate et al., 2000a). Integrin αVβ3 is used by all three rotavirus strains as a co-receptor, subsequent to their initial attachment to the cell (Guerrero et al., 2000). Integrins αXβ2 and α4β1 have also been suggested to participate in rotavirus cell entry (Coulson et al., 1997; Hewish et al., 2000).
Aside of their function as cellular receptors for viruses, integrins constitute a family of αβ heterodimers that mediate the interaction between the cell and the extracellular matrix. This interaction plays a crucial role in the regulation of cell no proliferation, migration and differentiation. In epithelial and endothelial cells integrins have a polarized distribution and localize at the basolateral plasma membrane. Therefore rotaviruses contained in the lumen of the intestine or at the apical surface of confluent epithelial cell lines could only have access to their integrin receptors at the basolateral surface if the TJ that seal the paracellular route are opened.
Since as stated at the beginning of this description, there is a need in the art for compounds that modulate junctional tightness and improve drug delivery across permeability barriers, we proceeded to explore the capacity of rotavirus proteins to modulate TJ sealing. The present invention fulfills this need and provides other related advantages. Recently, cell transformation has been correlated with over expression of certain claudins (Michl et al., 2001). Therefore the rotavirus proteins and derived peptides that target junctional proteins could also be employed for reducing tumor cell growth.
In the present invention we have worked with proteins and peptides derived from the VP4 molecule of Rhesus monkey rotavirus (RRV). Rotavirus infect a wide variety of vertebrates, such as chickens, horses, pigs, monkeys and humans, and several strains of viruses have been isolated from different individuals of the same specie. However, since the amino acid sequence of VP4 maintains a high degree of identity among most of the different rotavirus strains, it is expected that the different strains independent of their origin will exert a similar effect upon TJ. In consequence in the present invention we will further refer to VP4 and its derived peptides, without placing special emphasis on their origin.
The present invention provides proteins, peptides and methods for modulating tight junction mediated cell-cell adhesion and the formation of permeability barriers.
One aspect of the present invention is the use of rotavirus protein VP4, its derived polypeptide VP8, or peptides derived from them, to induce the opening of tight junctions.
Another aspect of the present invention is the use of rotavirus protein VP4 or its derived polypeptide VP8 or peptides derived from them to increase the paracellular permeability of epithelia and endothelia.
One crucial aspect of the present invention is the use of the rotavirus protein VP4, of the derived polypeptide VP8, or of peptides from them derived to allow and/or to enhance the passage of therapeutical agents through the paracellular pathway.
One additional aspect of the present invention is the use of rotavirus protein VP4, its derived polypeptide VP8, or peptides derived from them, to modulate and/or enhance the passage of therapeutical agents through the intestinal, nasal, ocular, vaginal and rectal epithelium.
A further objective of the present invention is the use of rotavirus protein VP4, its derived polypeptide VP8, or peptides derived from them, to allow and/or to enhance the passage of dermatological agents.
Within another aspect of the present invention, is the use of rotavirus protein VP4, its derived polypeptide VP8, or peptides derived from them, to allow and/or to enhance the passage of therapeutical agents across the blood-brain barrier.
Within a further aspect of the present invention, is to enhance the delivery of a drug to a tumor in a mammal, comprising administering the rotavirus protein VP4, its derived polypeptide VP8 or peptides derived from them, in combination with a drug to a tumor-bearing mammal.
The present invention further provides pharmaceutical compositions comprising rotavirus protein VP4, its derived polypeptide VP8 or peptides derived from it in combination with a pharmaceutically acceptable carrier. Such compositions may further comprise a drug. In addition, or alternatively, such compositions may comprise one or more of: a) peptides that modulate tight and/or adherens junctions; and/or b) an antibody or antigen binding fragment that specifically binds to TJ proteins.
Within further aspects, the present invention proposes the use of rotavirus protein VP4, its derived polypeptide VP8 or peptides derived from it, for treating cancer in mammals, where epithelial transformation is related to over expression of tight junction proteins.
Within a related aspect of the present invention rotavirus protein VP4, its derived polypeptide VP8, or peptides derived from it, might be employed to treat cancer and/or inhibit metastasis, by disrupting the growth of new capillaries that constitute a prerequisite for tumor growth and the emergence of metastases.
Within another related aspect of the present invention, protein VP4, its derived polypeptide VP8, or peptides derived from them can be used to reduce unwanted cellular adhesion that can occur between tumor cells, tumor cells and normal cells or between normal cells as a result of surgery, injury, chemotherapy, disease, inflammation or other condition jeopardizing cell viability or function.
One preferent form of the invention consists in the use of protein VP4, with ID SEQ. 1
Another preferent form of the invention consists in the use of polypeptide VP8, with ID SEQ. 2.
Yet another preferent form of the invention is centered on the use of fragment 141 to 182 of VP8 with ID SEQ 3:
141IDVVKTTQNGSYSQYGPLQSTPKLYGVMKHNGKIYTYNGETP182
Even another preferent form of the invention is the use of one or more of the following peptides derived from VP4:
Peptide SEQ. ID 4:144VVKT147
Peptide SEQ. ID 5:151SYSQYGPL158
Peptide SEQ. ID 6:174IYTY177
Peptide SEQ. ID 7:13NVTT186
Such peptides can be without limitations either cyclic (include a Cys on each of their terminal ends) or linear.
These and other aspects of the invention will become evident upon reference to the following detailed description and attached drawings.
Arrowheads indicate the clear distribution of ZO-1, occludin and claudin-3 at the cellular boundaries of control monolayers. Arrowheads point to the diffuse staining of ZO-1, occludin and claudin-3 that appears near the cellular borders of VP8 treated monolayers.
(A) The shadowed segments of VP8 sequence (SEQ ID NO:2) have a ≧50% identity to regions of the extracellular loops of occludin or claudin. Next to the brackets the name of the similar protein is indicated (e.g. cl 2, occl etc.). The sequence of peptide VP8141-182 is indicated within a frame. (B) Sequence comparison of VP8150-159 (SEQ ID NO: 8) and VP8174-177 (SEQ ID NO: 6) with occludin external loops. First Loop: Dog, (SEQ ID NO: 9); mouse, (SEQ ID NO:10); rat, (SEQ ID NO:11); human, (SEQ ID NO:12); chicken, (SEQ ID NO:13); and kangaroo rat, (SEQ ID NO:14). Second Loop: Dog, (SEQ ID NO:15); mouse, (SEQ ID NO:16); rat, (SEQ ID NO:17); human, (SEQ ID NO:18); chicken, (SEQ ID NO:19); and kangaroo rat, (SEQ ID NO:20). (C) Sequence comparison between diverse VP8 segments and claudins.
VP8 Segments: 5-10, (SEQ ID NO: 21); 18-23, (SEQ ID NO: 22); 27-31, (SEQ ID NO: 23); 39-45, (SEQ ID NO: 24); 45-49, (SEQ ID NO: 25); 65-70, (SEQ ID NO: 26); 69-72, (SEQ ID NO: 27); 74-78, (SEQ ID NO: 28); 81-85, (SEQ ID NO: 29); 88-94, (SEQ ID NO: 30); 113-123, (SEQ ID NO: 31); 116-121, (SEQ ID NO: 32); 134-140, (SEQ ID NO: 33); 142-146, (SEQ ID NO: 34); 152-155, (SEQ ID NO: 35); 155-158, (SEQ ID NO: 36); 161-164, (SEQ ID NO: 37); 170-175, (SEQ ID NO: 38); 173-177, (SEQ ID NO: 39); 183-186, (SEQ ID NO: 40); 187-191, (SEQ ID NO: 41); 194-197, (SEQ ID NO: 42); 202-205, (SEQ ID NO: 43); 216-219, (SEQ ID NO: 44);
C1-1 Segments: 149-154, (SEQ ID NO: 45); 31-35, (SEQ ID NO: 46); 39-44, (SEQ ID NO: 47); 65-68, (SEQ ID NO: 48);
C1-2 Segments: 66-71, (SEQ ID NO: 49); 148-151, (SEQ ID NO: 50); 67-70, (SEQ ID NO: 51); 64-67, (SEQ ID NO: 52); 145-148, (SEQ ID NO: 53);
C1-3 Segments: 151-154, (SEQ ID NO: 54); 146-149, (SEQ ID NO: 55); 146-150, (SEQ ID NO: 56); 31-35, (SEQ ID NO: 57); 67-70, (SEQ ID NO: 58);
C1-4 Segments: 148-151, (SEQ ID NO: 59); 148-152, (SEQ ID NO: 60); 55-59, (SEQ ID NO: 61); 67-70, (SEQ ID NO: 62); 145-148, (SEQ ID NO: 63);
C1-5 Segments: 64-69, (SEQ ID NO: 64); 139-143, (SEQ ID NO: 65); 33-38, (SEQ ID NO: 66);
C1-6 Segments: 148-152, (SEQ ID NO: 67); 148-151, (SEQ ID NO: 68); 67-70, (SEQ ID NO: 69);
C1-7 Segments: 129-133, (SEQ ID NO: 70); 129-132, (SEQ ID NO: 71); 64-67, (SEQ ID NO: 72);
C1-8 Segments: 139-143, (SEQ ID NO: 73); 139-142, (SEQ ID NO: 74); 73-76, (SEQ ID NO: 75); 136-139, (SEQ ID NO: 76);
C1-9 Segments: 148-152, (SEQ ID NO: 77); 43-49, (SEQ ID NO: 78); 148-151, (SEQ ID NO: 79); 47-50, (SEQ ID NO: 80); 145-149, (SEQ ID NO: 81);
C1-10 Segments: 72-77, (SEQ ID NO: 82);
C1-11 Segments: 33-38, (SEQ ID NO: 83); 156-159, (SEQ ID NO: 84);
C1-12 Segments: 165-168, (SEQ ID NO: 85);
C1-13 Segments: 154-158, (SEQ ID NO: 86); 63-66, (SEQ ID NO: 87);
C1-14 Segments: 66-71, (SEQ ID NO: 88); 148-152, (SEQ ID NO: 89); 148-151, (SEQ ID NO: 90); 150-153, (SEQ ID NO: 91); 57-62, (SEQ ID NO: 92);
C1-15 Segments: 69-74, (SEQ ID NO: 93); 160-163, (SEQ ID NO: 94);
C1-16 Segments: 29-33, (SEQ ID NO: 95);
C1-17 Segments: 65-69 (SEQ ID NO: 96); 64-67, (SEQ ID NO: 97);
C1-18 Segments: 167-175, (SEQ ID NO: 98),
C1-19 Segments: 63-68, (SEQ ID NO: 99); and
C1-20 Segments: 54-57, (SEQ ID NO: 100).
The shadowed letters correspond to amino acids in VP8 that are identical to those present in claudins. The sequence access number for the different claudins employed are: claudin 1, rat, NP113887; claudin 2, dog, AAK57433; claudin 3, rat, NP113888; claudin 4, mouse, NP034033; claudin 5, rat, AAF73425; claudin 6, mouse, Q9Z262; claudin 7, rat, CAA09790; claudin 8, mouse, Q9Z260; claudin 9, mouse, NP064689; claudin 10, mouse, Q9Z056; claudin 11, rat, NP445909; claudin 12, human, XP004591; claudin 13, mouse, Q9Z054; claudin 14, mouse, NP062373; claudin 15, mouse, NP68365; claudin 16, rat, NP571980; claudin 17, human, P56750; claudin 18, mouse, P56857; claudin 19, mouse, AAF98323; claudin 20, human P56880.
As noted above, the present invention deals with the use of rotavirus protein VP4 (SEQ. ID No. 1) and its functional variants, as well as the derived proteins VP8 (SEQ: ID. No. 2) and VP8141-182 (SEQ. ID. No. 3) and peptides derived from them (SEQ. ID. No. 4, 5, 6 and 7), to facilitate and/or enhance passage of pharmaceutical agents through epithelia and endothelia.
VP4 is a rotavirus protein. The particular strain of rotavirus from which VP4 is derived is not critical to the present invention.
The present invention considers any VP4 strain, independent of its origin, either natural or as a result of genetic manipulation, a functional variant of VP4, as long as it maintains the capacity to modulate the sealing of tight junctions.
Proteins VP4, VP8 or their derived fragments can be obtained and purified, e.g., by genetically engineered E. coli strains overexpressing their cDNA alone or fused to other genes, such as histidine or glutathione-s-transferase).
Proteins VP4, VPB, and VP8141-182 can be employed to generate antibodies, either monoclonals or polyclonals, that can be used to generate the same effect on tight junctions as proteins VP4, VP8 or their derived fragments and peptides, by employing methods well known in the art (Abrams et al., 1986).
Alternatively, proteins VP4 and VP8 can be employed either in their full length, in shorter versions, as fusion proteins or as derived synthetic functional peptides.
In yet another aspect of the invention, methods are proposed to determine the regions of protein VP4 that facilitate or enhance the opening of TJ. Such methods employ the following procedures:
As employed in the present invention, a “decrease in transepithelial electrical resistance” means a decrease in the resistance offered by the TJ to the passage of ions and molecules through the paracellular pathway.
The assay to determine the biological activity of proteins VP4, VP8 or their derived fragments and peptides, is not critical to the present invention. For example, the assay may involve (1) assaying for a decrease of tissue resistance of ileum mounted in Ussing chambers (Fasano et al., 1991) (2) assaying for a decrease of tissue resistance of epithelia cell line monolayers in Ussing chambers as described in Example 1 below; or (3) assaying for intestinal or nasal enhancement of absorption of a therapeutic agent, as described in U.S. Pat. No. 5,827,534 and U.S. Pat. No. 5,665,389.
Within another aspect of the invention, proteins VP4, VP8 or their derived fragments and peptides, could be employed for treating cancers, such as pancreatic cancer, where epithelial transformation is related to over expression of tight junction proteins (e.g. claudin-4) (Michl et al., 2001).
Furthermore, proteins VP4, VP8 or their derived fragments and peptides, could be employed to treat cancer and/or inhibit metastasis, by disrupting the TJ of new capillaries, whose formation constitute a prerequisite for tumor growth and the emergence of metastases.
Within another related aspect protein VP4, its derived polypeptide VP8, or peptides derived from them can be used to reduce unwanted cellular adhesion that can occur between normal cells as a result of surgery, injury, chemotherapy, disease, inflammation or other condition jeopardizing cell viability or function.
Proteins VP4 and VP8 can be obtained and purified by methods known to the art, for example by the methods referred to in example 1.
As employed in the present invention “functional peptide” or “functional protein” refers to any polypeptide derived from VP4 that is capable of decreasing the transepithelial electrical resistance and/or is able to modulate the structure of TJ, and/or the appearance of its molecular components.
In another aspect of the invention pharmaceutical compositions are described for the delivery of a therapeutic compound, where such compositions comprise:
The pharmaceutical composition is preferably an oral dosage composition for intestinal delivery, a nasal dosage composition for nasal delivery or intravenous dosage composition for delivery of a therapeutic agent through the blood-brain barrier.
The oral dosage composition for intestinal delivery comprises:
Oral dosage compositions for ileum delivery are well known in the art. Such oral dosage compositions can be in the form of solutions, tablets or capsules.
In the context of the present invention, oral dosage compositions include liquid compositions that contain aqueous agents. In such compositions it is recommended that the composition be prepared just before its administration, in order to minimise potential problems with the stability of the proteins and polypeptides of this invention.
The nasal dosage composition for nasal delivery of a therapeutic agent comprises:
Nasal dosage compositions for nasal delivery are well known in the art. Such nasal dosage compositions generally comprise water-soluble polymers that have been used extensively to prepare pharmaceutical dosage forms. The particular water-soluble polymer employed is not critical to the present invention, and can be selected from any of the well-known water-soluble polymers employed for nasal dosage forms.
The intravenous dosage composition for delivery of a therapeutic agent through the blood-brain barrier comprises:
Intravenous dosage compositions for delivery to the brain are well known in the art. Such intravenous dosage compositions generally comprise a physiological diluent, e.g., distilled water, or 0.9% (w/v) NaCl.
A “nasal” delivery composition differs from an “intestinal” delivery composition in that the latter must have gastroresistent properties in order to prevent the acidic degradation of the active agents (e.g. VP4, VP8 or their derived fragments and peptides and the therapeutic agent) in the stomach, whereas the former generally comprises water-soluble polymers in order to reduce the mucociliary clearance, and to achieve a reproducible bioavailability of the nasally administered agents. An “intravenous” delivery composition differs from both the “nasal” and “intestinal” delivery compositions in that there is no need for gastroresistance or water-soluble polymers in the “intravenous” delivery composition.
The mode of administration is not critical to the present invention. Although, it is preferable that the mode of administration is orally, for the intestinal delivery composition; intranasally, for the nasal delivery composition; and intravenously for delivery through the blood-brain barrier.
The particular therapeutic agent employed is not critical to the present invention, and can be, e.g., any drug compound, biologically active peptide, vaccine, or any other moiety otherwise not absorbed through the transcellular pathway, regardless of size or charge.
Examples of drug compounds, which can be employed in the present invention, include drugs that act on the cardiovascular system, drugs that act on the central nervous system, antineoplastic drugs and antibiotics.
Examples of drugs that act on the cardiovascular system, which can be employed in the present invention, include lidocaine, adenosine, dobutamine, dopamine, epinephrine, norepinephrine and phentolamine.
Examples of drugs that act on the central nervous system, which can be employed in the present invention, include doxapram, alfentanil, dezocin, nalbuphine, buprenorphine, naloxone, ketorolac, midazolam, propofol, metacurine, mivacurium and succinylcholine.
Examples of antineoplastic drugs that can be employed in the present include cytarabine, mitomycin, doxorubicin, vincristine and vinblastine.
Examples of antibiotics that can be employed in the present include methicillin, mezlocillin, piperacillin, cetoxitin, cefonicid, cefmetazole and aztreonam.
Examples of biologically active peptides that can be employed in the present invention include hormones, lymphokines, globulins, and albumins.
Examples of hormones which can be employed in the present invention include testosterone, nandrolene, menotropins, progesterone, insulin and urofolltropin.
Examples of lymphokines that can be employed in the present invention include interferon-alpha, interferon-beta, interferon-gamma, interleukin-1, interleukin-2, interleukin-4 and interleukin-8.
Examples of globulins that can be employed in the present invention include alpha-globulins, beta-globulins and gamma.-globulins (immunoglobulin).
Examples of immunoglobulins which can be employed in the present invention include polyvalent IgG or specific IgG, IgA and IgM, e.g., anti-tetanus antibodies.
An example of albumin that can be employed in the present invention is human serum albumin and ovalbumin.
Examples of vaccines that can be employed in the present invention include peptide antigens and attenuated micro-organisms and viruses.
Examples of peptide antigens which can be employed in the present invention include the B subunit of the heat-labile enterotoxin of enterotoxigenic E. coli, the B subunit of cholera toxin, capsular antigens of enteric pathogens, fimbriae or pili of enteric pathogens, HIV surface antigens, dust allergens and acari allergens.
Examples of attenuated micro-organisms and viruses that can be employed in the present invention include those of enterotoxigenic Escherichia coli, enteropathogenic Escherichia coli, Vibrio cholerae, Shigella flexneri, Salmonella typhi, and Helicobacter pylori.
When the therapeutic agent is insulin, the pharmaceutical composition of the present invention is useful for the treatment of diabetes.
The amount of therapeutic agent employed is not critical to the present invention and will vary depending upon the particular agent selected, the disease or condition being treated, as well as the age, weight and sex of the subject being treated.
The amount of VP4, VP8 or their derived fragments and peptides employed is also not critical to the present invention and will vary depending upon the age, weight and sex of the subject being treated.
The ratio of therapeutic agent to of VP4, VP8 or their derived fragments and peptides employed is not critical to the present invention and will vary depending upon the amount of therapeutic agent to be delivered within the selected period of time.
The following examples are offered by way of illustration and not by way of limitation.
This example illustrates an assay for evaluating the effect of rotavirus proteins on transepithelial electrical resistance.
A) VP8 Cloning
B) VP5 Cloning
C) Expression, Purification, and Administration of Fusion Proteins
Expression and purification of fusion proteins was performed following previously described standard procedures (Frangioni et al., 1993). For their experimental use, fusion proteins VP5 and VP8 were dissolved in fresh Dulbecco's minimal essential medium (DMEM) and sterilized by passage through a 0.22 μm filtration unit.
D) Cell Culture
MDCK cells were cultured as previously described (Gonzalez-Mariscal et al., 1990) and used for experiments between passages 70-90.
E) Transepithelial Electrical Resistance Measurements
The degree of sealing of tight junctions was evaluated by measuring the transepithelial electrical resistance (TER) across the monolayer. Standard procedures were followed (Gonzalez-Mariscal et al., 1990). Briefly, monolayers grown over Millipore filters were mounted between two Lucite chambers with an exposed area of 0.23 cm2. Current was delivered via Ag—AgCl electrodes placed at 2.0 cm form the monolayer; the voltage deflection elicited was measured with a second set of electrodes placed at 1.0 mm from the membrane. The contribution if the filter and the bathing solution was subtracted, and all values reported correspond exclusively to the monolayer. Each disk was used for a single determination.
This example illustrated an epithelial cell assay for evaluating the effect of VP8 on the distribution of TJ proteins.
A) Immunolocalization of TJ Proteins.
MDCK cells were cultured in glass coverslips. Confluent cultures were exposed to 4 μg/ml of GST-VP8 for 1 hr. The cells were then fixed for 30 min with 2% p-formaldehyde in PBS, pH 7.4, and permeabilized for 3 min with 0.2% PBS-TX. Cells were washed five times with PBS and then blocked for 30 minutes with 1% BSA Ig free (Research Organics 1331-a). The monolayers were incubated overnight at 4° C. with rabbit polyclonal antibodies against ZO-1 (Zymed 61-7300, dilution 1:100), Claudin 3 (Zymed 34-1700, dilution 3 μgr/ml) or occludin (Zymed 71-1500, dilution 1:100 in 1% Ig-free BSA). After being washed five times with PBS, the coverslips were incubated for one hour at room temperature with a secondary antibody (FITC-conjugated goat anti-rabbit, catalogue no. 65-6111, diluted 1:100, Zymed). The monolayers were washed five times in PBS before being mounted with the antifade reagent Vectashield (Vector Laboratories Inc.). The fluorescence of the monolayers was examined using a confocal microscope (MRC600, Bio-Rad) with a Krypton-argon laser.
This example illustrates how the pattern of TJ filaments is modified by VP8.
A) Freeze Fracture Analysis of TJ.
Confluent monolayers of MDCK cells were incubated for 1 hour with 4 μg/ml of GST-VP8 dissolved in DMEM, while control monolayers remained in DMEM. Freeze-fracture replicas were obtained from monolayers fixed with 2.5% glutaraldehyde for 30 minutes, and gradually infiltrated with glycerol up to a 20% concentration, in which they were left for 1 hour. The monolayers were then detached from the substrate and frozen in liquid nitrogen. Freeze fracture was carried out at −120° C., and 2×10−6 mm Hg using a Balzers apparatus (BAF400T). After evaporation of platinum and carbon, the organic material was digested for 1 hour in chromic mixture. Replicas were extensively washed in distilled water and mounted in Formvar coated grids. The observations were done in an electron microscope JEOL 200EX.
To assess modifications in the pattern of TJ strands, we counted the number of strands intercepting lines drawn perpendicular to the main axis of the junction, every 48 nm, as well as the distance between the upper and lowermost strand. 59 and 54 μm of TJ networks were analysed respectively for control and VP8 treated monolayers.
As has been previously reported (Gonzalez-Mariscal et al., 1985) the amount of junction is defined by the following function:
Where ni is the number of strands in a segment of TJ, and % is the percentage in which that number of strands is present in the sample.
Total junctional width is defined as:
Where ni is the distance between the upper and lowermost filament in TJ segment, and %i is the percentage in which that width is present in the sample.
The morphometric analysis present in the lower panel of
This example illustrates an epithelial assay for evaluating the effect of VP8 on the formation of TJ.
A) Calcium-Switch Assay for Evaluating TJ Assembly.
The ability of VP8 to inhibit the development of TJ was assessed utilizing the Ca2+ switch assay (Gonzalez-Mariscal et al., 1990). Cells were plated at confluency on Millipore filters and incubated for 1 hour in DMEM (normal calcium media, NC; 1.8 mM Ca2+). Then, the resulting monolayers were washed three times with PBS without Ca2+ and transferred to minimal essential medium without Ca2+ (low calcium media, LC; 1-5 μM Ca2+). Twenty hours later experimental monolayers were transferred to LC media containing 4 μg/ml of GST-VP8 or of GST-VP5 dissolved in LC media, while control monolayers were again incubated in LC media. After 30 minutes, the experimental monolayers were transferred to NC media containing 4 μg/ml of GST-VP8 or of GST-VP5. Control monolayers received instead NC media. The TER was measured at different time points after the monolayers were transferred to NC media.
This example illustrates a method for selecting domains of VP8 that can enhance or modulate the opening of TJ.
This Example illustrates an assay for evaluating the effect of VP8 on orally administered insulin.
A) Generation of Diabetic Rats.
B) Determination of Glucose Concentration in Blood.
C) Administration of Insulin to Diabetic Rats.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IB03/00280 | 1/10/2003 | WO | 00 | 5/18/2006 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO03/098991 | 12/4/2003 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5422110 | Potter et al. | Jun 1995 | A |
5503833 | Redmond et al. | Apr 1996 | A |
6004534 | Langer et al. | Dec 1999 | A |
20020055618 | Langridge et al. | May 2002 | A1 |
Number | Date | Country |
---|---|---|
WO 9606971 | Aug 1989 | WO |
Entry |
---|
Cao and Lam, Projections for Insulin treatment for diabetes, 2002, Drugs Today, vol. 38, No. 6, abstract. |
Ginger et al. A novel Dictyostelium cell surface protein important for both cell adhesion and cell sorting, 1998, Development, vol. 125, pp. 3343-3352. |
Hendrick et al., Survey of amino-terminal proteolytic cleavage sites in mitochondrial precursor proteins: Leader peptides cleaved by two matrix proteases share a three-amino acid motif, 1989, PNAS, vol. 86, pp. 4056-4060. |
Genbank Accession # AAK52093, published Jul. 24, 2001. |
Honeyman et al., Association Between Rotavirus Infection and Pancreatic Islet Autoimmunity in Children at Risk of Developing Type 1 Diabetes, 2000, Diabetes, vol. 49, pp. 1319-1324. |
Kang et al., Peroral Immunization of Microencapsulated Human VP8 in Combination with Cholera Toxin Induces Intestinal Antibody Responses, 1999, Molecules and Cells, vol. 9, No. 6, pp. 609-616. |
GenBank Accession No. AAA47345, outer capsid protein VP3 [Rhesus rotavirus], Aug. 1993. |
Database EBI Database accession No. P12473, XP002260536, “100% identical to Seq-ID-No. 1, 3 in a 776aa overlap; 100% identical to Seq-ID-No. 2 in a 231 aa overlap” abstract, 2003. |
Dormitzer, P.R. et al. (2001) “Proteolysis of monomeric recombinant rotavvirusvp4 yields an oligomeric vp5* core” Journal of Virology 75:7339-7350. |
Tafazoli, F. et al. (2001) “NSP4 enterotoxin of rotavirus induces paracellular leakage in polarized epithelial cells” Journal of Virology 75:1540-1546. |
Dickman K.G. et al. (2000) “Rotavirus alters paracellular permeability and energy metabolism of caco-2 cells” Am. J. Physiol. Gastrointes. Lover Physiol. 279:G757-G766. |
Tihova, M. et al. (2001) “Localization of membrane permeabilization and receptor binding sites on the vp4 hemagglutinin of rotavirus: implications for cell entry” J. Mol. Biol. 314:985-992. |
Zarate S. et al. (2003) “Interaction of rotaviruses with hsc70 during cell entry is mediated by vp5” Journal of Virology 77:7254-7260. |
Number | Date | Country | |
---|---|---|---|
20060251663 A1 | Nov 2006 | US |