The repertoire of safe and cost-effective vaccines for generation of mucosal immunity against a variety of agents is limited. The leading bacterial cause of human gastrointestinal disease worldwide is Campylobacter. Bacterial gastroenteritis continues to pose a significant threat to the general public in the United States and abroad for the foreseeable future. Infections with Campylobacter jejuni occur more frequently than the more publicized infections from Salmonella species or Escherichia coil O157:H7. The actual burden of illness of Campylobacter gastroenteritis nationwide is 500-850 infections/100,000 persons per year.
Not only is Campylobacter the leading cause of bacterial gastroenteritis, but C. jejuni has been associated with the neuropathological disease Guillain-Barré Syndrome (GBS). This life-threatening disease may be an immune response to ganglioside-like structures on certain C. jejuni strains leading to an autoimmune response against nerve cells. Although GBS is the most important chronic sequelae, Campylobacter infection is also associated with a reactive arthritis, which may progress to Reiter's syndrome.
Vaccination against Campylobacter has had limited success using killed whole-cell or protein based vaccines. In addition, there are concerns regarding the development of Guillain-Barre syndrome or other sequelae from killed whole-cell vaccination. A successful vaccine would need to be cost-effective, safe, orally effective, and be produced in large quantities in a very short time-period. At the present time there is no such vaccine.
Vectors and methods for enhancing resistance to Campylobacter infection or enhancing the immune response to Campylobacter are provided herein.
In one aspect, vectors including a first polynucleotide sequence encoding an antigenic polypeptide not natively associated with the vector are provided. The antigenic polypeptide may be SEQ ID NO: 7 (cjaD; cj0113; GVSITVEGNCDEWGTDEYNQA), SEQ ID NO: 8(cjaA; cj0982; KDIVLDAEIGGVAKOKDGKEK) or SEQ ID NO: 9(ACE 393; cj0420; KVALGVAVPKDSNITSVEDLKDKTLLLNKGTTADA) or a fragment thereof. The vector may also include an immunostimulatory polypeptide not natively associated with the vector. The vaccine vector is capable of eliciting an immune response from a vaccinated subject that includes an IgA antibody response against Campylobacter. The response may be protective against challenge with Campylobacter.
In another aspect, vectors including a first polynucleotide sequence encoding an antigenic polypeptide not natively associated with the vector and a second polynucleotide sequence encoding an immunostimulatory polypeptide are provided. The antigenic polypeptides may be a fragment of SEQ ID NO: 1 (cjaD), SEQ ID NO: 2 (cjaA) or SEQ ID NO: 3 (ACE393). The vaccine vector is capable of eliciting an immune response from a vaccinated subject that includes an IgA antibody response against Campylobacter. The response may be protective against challenge with Campylobacter.
In still another aspect, pharmaceutical compositions comprising the vectors provided herein in a pharmaceutically acceptable carrier are disclosed.
In yet another aspect, methods of enhancing an immune response directed to Campylobacter in a subject are provided. The methods include administering an effective amount of the vectors provided herein to a subject. In one embodiment, the enhanced immune response includes an IgA antibody response and the response may be protective.
In still a further aspect, methods of enhancing resistance to Campylobacter infection are provided herein. The methods include administering an effective amount of the vectors disclosed herein to the subject such that the subject is resistant to infection after subsequent exposure to Campylobacter. In one embodiment the enhanced immune response includes an IgA antibody response and the response may be protective.
Vaccine vectors that elicit mucosa, humoral, and cell-mediated immune responses against multiple serovars of Campylobacter offer a promising approach to limit Campylobacter gastroenteritis. This project utilizes a novel approach in the development of vaccines by inserting polynucleotide sequences encoding non-native linear epitopes (antigenic polypeptides). The antigenic polypeptides may be used in combination with an immunostimulatory polypeptide such as CD154 (CD40L) or HMGB1 (high mobility group box 1) in the vaccine vector. The antigenic polypeptide and the immunostimulatory polypeptide are suitably not polypeptide found natively associated with the vector. The epitope or antigenic polypeptide and the immunostimulatory polypeptide may be expressed on the surface of recombinant vectors. The vectors may be bacterial, viral or even liposome vectors. The vectors may be live, live and attenuated, or killed prior to administration. Substantial preliminary data, such as that shown in the Examples, demonstrates that Salmonella or Bacillus constructs expressing a foreign epitope are able to rapidly induce high titer epitope-specific antibodies in vivo. Furthermore, co-expression of surface CD154 or HMGB1 effectively enhanced the antibody response against the foreign epitope.
Recombinant DNA technologies enable relatively easy manipulation of many bacterial and viral species. Some bacteria and viruses are mildly or non-pathogenic, but are capable of generating a robust immune response. These bacteria and viruses make attractive vaccine vectors for eliciting an immune response to a heterologous, non-native, or foreign antigen. Bacterial or viral vaccine vectors may mimic the natural infection and produce robust and long lasting immunity. Vaccine vectors are often relatively inexpensive to produce and administer. In addition, such vectors can often carry more than one antigen and may provide protection against multiple infectious agents.
Polynucleotides encoding polypeptide antigens from any number of pathogenic organisms may be inserted into the vaccine vector and expressed to generate antigenic polypeptides. An antigenic polypeptide is a polypeptide that is capable of being specifically recognized by the adaptive immune system. An antigenic polypeptide includes any polypeptide that is immunogenic. The antigenic polypeptides include, but are not limited to, antigens that are pathogen-related, allergen-related, tumor-related or disease-related. Pathogens include viral, parasitic, fungal and bacterial pathogens as well as protein pathogens such as the prions.
The antigenic polypeptides may be full-length proteins or portions thereof. It is well established that immune system recognition of many proteins is based on a relatively small number of amino acids, often referred to as the epitope. Epitopes may be only 8-10 amino acids. Thus, the antigenic polypeptides described herein may be full-length proteins, 8 amino acid long epitopes or any portion between these extremes. In fact the antigenic polypeptide may include more than one epitope from a single pathogen or protein. Suitably the antigenic polypeptide is a polypeptide that is not natively associated with the vector. Not natively associated includes antigenic polypeptides that may also occur natively in the vector, but that are being expressed recombinantly as an epitope, are being expressed in combination with a different polypeptide as a fusion protein to allow for differential display and differential enhancement of the immune response as compared to the natively expressed polypeptide.
Multiple copies of the same epitope or multiple epitopes from different proteins may be included in the vaccine vector. It is envisioned that several epitopes or antigens from the same or different pathogens or diseases may be administered in combination in a single vaccine vector to generate an enhanced immune response against multiple antigens. Recombinant vaccine vectors may encode antigens from multiple pathogenic microorganisms, viruses or tumor associated antigens. Administration of vaccine vectors capable of expressing multiple antigens has the advantage of inducing immunity against two or more diseases at the same time.
The polynucleotides may he inserted into the chromosome of the vaccine vector or encoded on plasmids or other extrachromosomal DNA. Polynucleotides encoding epitopes may be expressed independently (i.e., operably linked to a promoter functional in the vector) or may be inserted into a vaccine vector polynucleotide (i.e., a native polynucleotide or a non-native polynucleotide) that is expressed in the vector. Suitably, the vaccine vector polynucleotide encodes a polypeptide expressed on the surface of the vaccine vector such as a transmembrane protein. The polynucleotide encoding the antigenic polypeptide may be inserted into the vaccine vector polynucleotide sequence in frame to allow expression of the antigenic polypeptide on the surface of the vector. For example, the polynucleotide encoding the antigenic polypeptide may be inserted in frame into a bacterial polynucleotide in a region encoding an external loop region of a transmembrane protein such that the vector polynucleotide sequence remains in frame. See the Examples below in which the antigenic polypeptides are inserted into an external loop of the lamB gene of the Salmonella enteritidis vector.
Alternatively, the polynucleotide encoding the antigenic polypeptide may be inserted into a secreted polypeptide. Those of skill in the as will appreciate that the polynucleotide encoding the antigenic polypeptide could be inserted in a wide variety of vaccine vector polynucleotides to provide expression and presentation of the antigenic polypeptide to the immune cells of a subject treated with the vaccine vector. In the Examples, several Campylobacter polynucleotides were inserted into the lamB coding sequence of Salmonella enteritidis. The resulting recombinant bacteria express the inserted antigenic polypeptides on the surface of the bacteria. The polynucleotides may be inserted in CotB of Bacillus subtilis such that the recombinant bacteria expressed the inserted antigenic polypeptides in spores or into sip for surface expression in vegetative bacteria.
The vectors may include a polynucleotide encoding full length Campylobacter proteins including cjaD (SEQ ID NO: 1), cjaA (SEQ ID NO: 2) and ACE393 (SEQ ID NO: 3) or an antigenic polypeptide of these proteins. In the Examples, antigenic polypeptides derived from the full-length proteins were used as follows: SEQ ID NO: 7 (a cjaD polypeptide called cj0113); SEQ ID NO: 8 (a cjaA polypeptide called cj0982); and SEQ ID NO: 9 (an ACE 393 polypeptide called cj0420). The polynucleotides used in the Examples are provided as SEQ ID NOs: 4-6, respectively. The polynucleotides used in the Examples had the antigenic polypeptides of SEQ ID NOs 7-9 separated by serine linkers and linked to CD154 amino acids 140-149 (three amino acids before, after and in between the antigenic polypeptide and the immunostimulatory polypeptide).
Suitably, the portion of the antigenic polypeptide inserted into the vaccine vector is immunogenic or antigenic. An immunogenic fragment is a peptide or polypeptide capable of eliciting a cellular or humoral immune response. Suitably, an antigenic polypeptide may be the full-length protein, or suitably may be 20 or more amino acids, 15 or more amino acids, 10 or more amino acids or 8 or more amino acids of the full-length sequence. Suitably the immune response generated against the target pathogen is a protective immune response. A protective immune response is a response capable of blocking or reducing morbidity or mortality caused by subsequent infection with the target pathogen, namely Campylobacter.
One of skill in the art will appreciate that any of these polynucleotide sequences may be used in combination with any other antigenic polypeptide including polypeptides from other heterologous pathogens or organisms and may also he used in conjunction with polynucleotides encoding immunostimulatory polypeptides such as a polypeptide of CD154 or HMGB1 such as is described in International Application Nos. PCT/US07/078785 and PCT/US2011/022062 both of which are incorporated herein by reference in their entireties.
Polynucleotides encoding immunostimulatory polypeptides that are homologous to proteins of the subject and capable of stimulating the immune system to respond to the foreign epitope may also be inserted into a vector. As described in more detail below, the vector may include a CD154 polypeptide that is capable of binding CD40 in the subject and stimulating the subject to respond to the vector and its associated foreign antigenic polypeptide. In addition, a vector may include a HMGB1 polypeptide or a functional fragment thereof. As described above with regard to antigenic polypeptides, polynucleotides encoding these polypeptides may be inserted into the chromosome of the vector or maintained extrachromosomally. One of skill in the art will appreciate that these polynucleotides can be inserted in a variety of vector polynucleotides for expression in different parts of the vector or for secretion of the polypeptides.
The polynucleotide encoding an immunostimulatory polypeptide capable of enhancing the immune response to a non-native antigenic polypeptide may also encode the antigenic polypeptide. The polynucleotide encoding an immunostimulatory polypeptide may be linked to the polynucleotide encoding the antigenic polypeptide, such that in the vaccine vector the immunostimulatory polypeptide and the foreign antigenic polypeptide are present on the same polynucleotide. For example, the antigenic polypeptide and the immunostimulatory polypeptide may be portions of a fusion protein. In the Examples, a polynucleotide encoding a polypeptide of CD154 that is capable of binding to CD40 also encodes an antigenic polypeptide from cjaD, cjaA or ACE 393 of Campylobacter. See SEQ ID NOS: 10-12 in the attached sequence listing for some examples of potential polypeptide sequences and SEQ ID NOs: 4-6 for polynucleotide sequences which encode for optional serine linkers between the antigenic polypeptide, the immunostimulatory polypeptide and the host polypeptide.
in the Examples, the polynucleotide encoding the Campylobacter antigenic polypeptides and the polynucleotide encoding the immunostimulatory polypeptide are both inserted in the outer loop of the transmembrane lamB gene. Those of skill in the art will appreciate that vector poly-nucleotides encoding other transmembrane proteins may also be used. In addition, the antigenic polynucleotides may be extrachromosomal or secreted by the vector, in the Examples, the polynucleotide encoding the Campylobacter cj0113 antigen (SEQ ID NO: 7) and the immunostimulatory peptide HMGB1 (SEQ NO:20) were expressed from a plasmid carried by a Bacillus vector and expressed on the cell surface.
Suitably, the CD154 polypeptide is fewer than 50 amino acids long, more suitably fewer than 40, fewer than 30 or fewer than 20 amino acids in length. The polypeptide may be between 10 and 15 amino acids, between 10 and 20 amino acids or between 10 and 25 amino acids in length. The CD154 sequence and CD40 binding region are not highly conserved among various species. The CD154 sequences of chicken and human are provided in SEQ ID NO: 13 and SEQ ID NO: 14, respectively.
The CD40 binding regions of CD154 have been determined for a number of species, including human, chicken, duck, mouse and cattle and are shown in SEQ ID NO 15, SEQ ID NO: 16, SEQ ID NO: 17, SEQ ID NO:18, and SEQ ID NO:19, respectively. Although there is variability in the sequences in the CD40 binding region between species, cross-species binding of CD154 to CD40 has been reported. For example, the human CD154 polypeptide was able to enhance the immune response in chickens. Therefore, one may practice the invention using species specific CD154 polypeptides or a heterologous CD154 polypeptide.
The HMGB1 (High Mobility Group Box-1) protein was first identified as a DNA-binding protein critical for DNA structure and stability, it is a ubiquitously expressed nuclear protein that binds DNA with no sequence specificity. The protein is highly conserved and found in plants to mammals. The zebrafish, chicken and human HMGB1 amino acid sequences are provided in SEQ ID NO: 28, SEQ ID NO: 20 and SEQ ID NO: 27, respectively. The sequence throughout mammals is highly conserved with 98% amino acid identity and the amino acid changes are conservative. Thus an HMGB1 protein from one species can likely substitute for that from another species functionally. The hill-length HMGB1 protein or a portion thereof may be used as the HMGB1 polypeptide in the vaccine vectors described herein. HMGB1 has two DNA binding regions termed A box as shown in SEQ ID NO: 21 and 22 and B box as shown in SEQ ID NO: 23 and 24. See Andersson and Tracey, Annu. Rev. Immunol. 2011, 29:139-162, which is incorporated herein by reference in its entirety.
HMGB1 is a mediator of inflammation and serves as a signal of nuclear damage, such as from necrotic cells. HMGB1 can also be actively secreted by cells of the monocyte/macrophage lineage in a process requiring acetylation of the protein, translocation across the nucleus and secretion. Extracellular HMGB1 acts as a potent mediator of inflammation by signaling via the Receptor for Advanced Glycated End-products (RAGE) and via members of the Toll-like Receptor family (TLR), in particular TLR4. The RAGE binding activity has been identified and requires the polypeptide of SEQ ID NO: 25. TLR4 binding requires the cysteine at position 106 of SEQ ID NO: 20, which is found in the B box region of HMGB1.
The inflammatory activities of HMGB1 do not require the hill-length protein and functional fragments have been identified. The B box has been shown to be sufficient to mediate the pro-inflammatory effects of HMGB1 and thus SEQ ID NO: 23 and 24 are HMGB1 polypeptides or functional fragments thereof within the context of the present invention. In addition, the RAGE binding site and the pro-inflammatory cytokine activity have been mapped to SEQ ID NO; 25 and SEQ ID NO: 26, respectively. Thus, these polypeptides are functional fragments of HMGB1 polypeptides in the context of the present invention.
Those of skill in the art are capable of identifying HMGB1 polypeptides and fragments thereof capable of stimulating pro-inflammatory cytokine activity, using methods such as those in International Publication No. WO02 092004, which is incorporated herein by reference in its entirety. Suitably, the HMGB1 polypeptide includes the RAGE binding domain at amino acids 150-183 of SEQ ID NO:20 (SEQ ID NO: 25 or a homolog thereof) and the pro-inflammatory cytokine activity domain between amino acids 89-109 of SEQ ID NO: 20 (SEQ ID NO: 26 or a homolog thereof) In particular, HMGB1 polypeptides and functional fragments or homologs thereof include polypeptides identical to, or at least 99% identical, at least 98% identical, at least 95% identical, at least 90% identical, at least 85% identical, or at least 80% identical to the HMGB1 polypeptides of SEQ ID NOs: 20-28.
One of skill in the art will appreciate that the HMGB1 polypeptide could be used to enhance the immune response to more than one antigenic polypeptide present in a vector. The polypeptide from IHMGB1 stimulates an immune response at least in part by activating dendritic cells and macrophages and thus stimulating production of IL-1, IL-6, IFN-γ and TNF-α. Suitably, HMGB1 may be expressed on the surface of the vector.
At least a portion of the antigenic polypeptide and at least a portion of the HMGB1 polypeptide or another immunostimulatory polypeptide may be present on the surface of the vaccine vector. Present on the surface of the vaccine vector includes polypeptides that are comprised within a transmembrane protein, interacting with, covalently or chemically cross-linked to a transmembrane protein, a membrane lipid or membrane anchored carbohydrate. A polypeptide can be comprised within a transmembrane protein by having the amino acids comprising the polypeptide linked via a peptide bond to the N-terminus, C-terminus or anywhere within the transmembrane protein (i.e. inserted between two amino acids of the transmembrane protein or in place of one or more amino acids of the transmembrane protein (i.e. deletion-insertion). Suitably, the polypeptides may be inserted into an external loop of a transmembrane protein. Suitable transmembrane proteins are cotB and lamB, but those of skill in the al will appreciate many suitable transmembrane proteins are available.
Alternatively, the polypeptides may be covalently or chemically linked to proteins, lipids or carbohydrates in the membrane, or capsid if a viral vector is being used through methods available to persons of skill in the art. For example, di-sulfide bonds or biotin—avidin cross-linking could be used to present the antigenic and HMGB1 polypeptides on the surface of a vaccine vector. Suitably, the antigenic polypeptide and the HMGB1 polypeptide are part of a fusion protein. The two polypeptides may be directly linked via a peptide bond or may be separated by a linker or a section of a third protein into which they are inserted.
In the Examples, some of the vectors have the Campylobacter antigenic polypeptides (cj0113, cj0420 and cj0982) and the immunostimulatory polypeptide (CD154 amino acids 140-149 or HMGB1 or a functional fragment thereof) encoded on the same polynucleotide (lamB) such that the sequences are in frame with each other and with the Salmonella polynucleotide in which they were inserted. In some embodiments, linkers may be added between the polynucleotide sequences encoding the antigenic polypeptide and the immunostimulatory polypeptide such that in the expressed polypeptide several amino acids separate the two polypeptides. The linker may be 3 nucleotides encoding a single amino acid, or may be much longer, e.g. 30 nucleotides encoding 10 or more amino acids. In the Examples a 9 nucleotide linker was used and encoded for three serine residues. Those of skill in the art will readily envision many other types of linkers that could be used.
In addition, the polynucleotides may be present in a single copy or in multiple copies. For example, three copies of the antigenic polypeptide and three copies of the immunostimulatory polypeptide may be found in the same external loop of a transmembrane protein or expressed within several different vector proteins. In alternative embodiments, the immunostimulatory polypeptide and the antigenic polypeptide may be encoded by distinct polynucleotides.
Potential vaccine vectors for use in the methods include, but are not limited to, Bacillus, Salmonella (Salmonella enteritidis), Shigella, Escherichia (E. coli), Yersinia, Bordetella, Lactococcus, Lactobacillus, Streptococcus, Vibrio (Vibrio cholerae), Listeria, adenovirus, poxvirus, herpesvirus, alphavirus, and adeno-associated virus. Suitably, the vaccine vector is a GRAS organism. The vaccine vector may be inactivated or killed such that it is not capable of replicating. Methods of inactivating or killing bacterial or viral vaccine vectors are known to those of skill in the art and include, but are not limited to methods such as formalin inactivation, antibiotic-based inactivation, heat treatment and ethanol treatment. In some embodiments the vaccine vector may he a liposome based vector.
Compositions comprising the vector and a pharmaceutically acceptable carrier are also provided. A pharmaceutically acceptable carrier is any carrier suitable for in vivo administration. The pharmaceutically acceptable carrier may include water, buffered solutions, glucose solutions or bacterial culture fluids. Additional components of the compositions may suitably include excipients such as stabilizers, preservatives, diluents, emulsifiers and lubricants. Examples of pharmaceutically acceptable carriers or diluents include stabilizers such as carbohydrates (e.g., sorbitol, mannitol, starch, sucrose, glucose, dextran), proteins such as albumin or casein, protein-containing agents such as bovine serum or skimmed milk and buffers (e.g., phosphate buffer). Especially when such stabilizers are added to the compositions, the composition is suitable for freeze drying or spray-drying.
Methods of enhancing immune responses to Campylobacter in a subject by administering the vectors described herein are also provided. The vector may contain a HMGB1 polypeptide or a CD154 polypeptide capable of stimulating the immune response to the vector and the antigenic polypeptides described above. The vector is administered to a subject in an amount effective to enhance the immune response of the subject to the non-native antigenic polypeptides. Suitably the immune response to challenge with Campylobacter is enhanced.
Enhancing an immune response includes, but is not limited to enhancing antibody responses. Suitably the IgA response is enhanced, more suitably the secretory IgA response is enhanced after administration of the vector as compared to a control. The control may be the same subject prior to administration of the vector, a comparable subject administered a vector alone or a vector expressing an irrelevant or a non-Campylobacter antigenic polypeptide. The antibody response, suitably the IgA response, may be increased as much as two fold, three fold, four fold, five fold or more as compared to the response of a control subject. The enhanced immune response may also result in a reduction of the ability of Campylobacter to grow or replicate and colonize the subject after administration of the vectors described herein. Such a reduction may be tested by challenging a subject administered the vector with a Campylobacter infection and monitoring the ability of the bacteria to colonize and replicate, i.e. infect, the subject as compared to a control subject. The growth of Campylobacter in the subject may be reduced by 1 log, 2 logs, 3 logs, 4 logs, 5 logs or even more. The growth of Campylobacter in a subject administered the vector may be below the level of detection.
In addition, methods of enhancing resistance to Campylobacter infection are disclosed. Briefly, the methods comprise administering to a subject the vectors described above comprising Campylobacter antigenic polypeptides in an amount effective to elicit an immune response. Enhancing resistance to Campylobacter infection includes but is not limited to reducing the incidence of Campylobacter infections, limiting the spread of Campylobacter infections from one host to another, reducing Campylobacter replication in the subject, invasion or spread within a single host, reduced morbidity associated with Campylobacter infections, and reduced duration of a Campylobacter infection.
Administration of the vector may prevent the subject from contracting Campylobacter or from exhibiting any outward signs of disease, such as gastroenteritis or GBS. Increased resistance to Campylobacter may also include increased antibody production, suitably IgA production. The antibody response, suitably the IgA response, may be increased as much as two fold, three fold, four fold, five fold or more as compared to the response of a control subject. The enhanced immune response may also result in a reduction of the ability of Campylobacter to grow or replicate and colonize the subject after administration of the vectors described herein. Such a reduction may be tested by challenging a subject administered the vector with a Campylobacter infection and monitoring the ability of the bacteria to colonize and replicate, i.e. infect, the subject as compared to a control subject. The growth of Campylobacter in the subject may be reduced by 1 log, 2 logs, 3 logs, 4 logs, 5 logs or even more. The growth of Campylobacter in a subject administered the vector may be below the level of detection.
The antigenic polypeptides for use in all the methods described herein may be from cjaD, cjaA or ACE 393 as discussed above. The insertion of the antigenic polypeptides into the vector may be accomplished in a variety of ways known to those of skill in the art, including but not limited to the scarless site-directed mutation system described in International Patent Publication No. WO2008/036675, which is incorporated herein by reference in its entirety. The vector may be a bacterium engineered to express Campylobacter antigenic polypeptides in conjunction with polynucleotides capable of enhancing the immune response as discussed above. In particular, a polypeptide of CD154 or HMGB1 may be expressed by the vector to enhance the immune response of the subject to the antigenic polypeptides. The vectors used in these methods may be attenuated or killed prior to administration or use in the methods.
The useful dosage to be administered will vary depending on the age, weight and species of the subject, the mode and route of administration and the type of pathogen against which an immune response is sought. The composition may be administered in any dose of vector sufficient to evoke an immune response. For bacterial vectors, it is envisioned that doses ranging from 103 to 101° bacteria, from 104 to 109 bacteria, or from 105 to 107 bacteria are suitable. The composition may be administered only once or may be administered two or more times to increase the immune response. For example, the composition may be administered two or more times separated by one week, two weeks, or by three or more weeks. The bacteria vectors are suitably viable prior to administration, but in some embodiments the bacteria vectors may be killed prior to administration. In some embodiments, the bacteria vectors may be able to replicate in the subject, while in other embodiments the bacteria vectors may be attenuated and/or may not be capable of replicating in the subject.
For administration to animals or humans, the compositions may be administered by a variety of means including, but not limited to, intranasally, mucosally, by spraying, intradermally, parenterally, subcutaneously, orally, by aerosol or intramuscularly. Eye drop administration or addition to drinking water or food are additionally suitable means of administration. For chickens, the compositions may be administered in ovo.
With regard to the methods, a subject includes, but is not limited to, a vertebrate, suitably a mammal, suitably a human, or birds, suitably poultry such as chickens or turkeys. Other animal models of infection may also be used. Enhancing an immune response includes, but is not limited to, inducing a therapeutic or prophylactic effect that is mediated by the immune system of the subject. For example, an immune response is enhanced if the subject is protected from subsequent infection with Campylobacter. Specifically, enhancing an immune response may include enhanced production of antibodies, such as demonstrated in
It is envisioned that several epitopes or antigens from the same or different pathogens may be administered in combination in a single vector to generate an enhanced immune response against multiple antigens and their associated pathogens. Recombinant vaccine vectors may encode antigens from multiple pathogenic microorganisms, viruses or tumor associated antigens. Administration of vaccine vectors capable of expressing multiple antigens has the advantage of inducing immunity against two or more diseases at the same time.
Heterologous polynucleotides encoding antigens can be inserted in the vaccine vector genome at any non-essential site or alternatively may be carried on a plasmid using methods well known in the art. One suitable site for insertion of polynucleotides is within external portions of transmembrane proteins or coupled to sequences which target the heterologous polynucleotide for secretory pathways. One example of a suitable transmembrane protein for insertion of polynucleotides is the lamB gene of Salmonella. Heterologous polynucleotides include, but are not limited to, polynucleotides encoding antigens selected from pathogenic microorganisms or viruses other than the vaccine vector, i.e., non-native polynucleotides encoding non-native polypeptides.
The following examples are meant only to be illustrative and are not meant as limitations on the scope of the invention or of the appended claims. All references cited herein are hereby incorporated by reference in their entirety.
Attenuation of Salmonella Vaccine Candidate Strains
Salmonella enteritidis phage type 13A (S. enteritidis) was attenuated by introducing defined, irreversible deletion mutations in the aroA and/or htrA gene of the S. enteritidis genome as previously described (available as ATCC Deposit Nos: PTA-7871, PTA-7872 and PTA-7873). Briefly, the target gene sequence in the bacterial genome of S. enteritidis was replaced with the kanamycin-resistant (KmR) gene sequence. This was performed using 3S-PCR and electroporation of the 3S-PCR products into electrocompetent Salmonella cells containing the pkD46 plasmid. The resulting cell mixture was plated on LB agar plates supplemented with Km to select for positive clones containing a KmR gene. The KmR gene was inserted into the genomic region containing the genes of interest (aroA or htrA) by flanking the KmR gene with sequences homologous to the genes of interest. Once KmR mutants were obtained, the deletion mutations were confirmed by PCR and DNA sequencing. All KmR genes were removed before epitope insertion was started.
Construction of Recombinant Vaccine Candidates
Three potential candidate antigenic polypeptides were selected: Omp18/cjaD (cj0113), cjaA (cj0982) and ACE393 (cj0420). The polypeptides selected were as follows: cj0113 (GVSITVEGNCDEWGTDEYNQAWMTTSYAPTS; SEQ ID NO: 10), cj0982c (KDIVLDAEIGGVAKGKDGKEKWMTTSYAPTS; SEQ ID NO: 11), and cj0420 (KVALGVAVPKDSNITSVEDLKDKTLLLNKGTTADAWMTTSYAPTS; SEQ ID NO: 12), all inserts additionally contain a sequence for amino acids 140-149 of CD154.
Recombinant S. enteritidis strains containing stable integrated copies of cj0113-CD154 (cj0113), c10420-CD154 (cj0420) or cj0982c-CD154 (cj0982) were constructed using the method of Cox et al. Searless and site-directed mutagenesis in Salmonella enteritidis chromosome. BMC Biotechnol 2007;7;59. Briefly, an I-SceI enzyme site along with a KmR gene was introduced into Loop 9 of the lamB gene by design of a PCR product which had the I-SceI enzyme site and KmR gene flanked by approximately 200-300 base pairs of DNA on each side, homologous to the up and downstream regions of Loop 9. Primers used are shown in Table I below. The PCR product was electroporated into electrocompetent attenuated Salmonella cells containing the pKD46 plasmid and the resulting cell mixture plated on LB agar plates supplemented with Km to select for positive clones now containing a KmR gene. After the See-I/Km mutation was made in Loop 9, this region was replaced by a codon-optimized foreign epitope DNA sequence (Burns D M, Beacham I R. Rare codons in E. coli and S. typhimurium signal. sequences. FEBS Lett 1985;189(2):318-24.). This second 3S-PCR reaction produced the foreign epitope insert flanked by Loop 9 up and downstream regions, and the resulting PCR product was electroporated into electrocompetent SE13A containing the See-I/Km mutation described above. Plasmid pBC-I-SceI was also electroporated into the cells along with the insert as the plasmid produces the I-SceI enzyme which recognizes and cleaves a sequence creating a gap at the I-SceI enzyme site in the Loop 9 region of the LamB gene where the foreign epitope sequences inserted into the SE13A genome. The plasmid also carries with it a chloramphenicol (Cm) resistant gene (CmR) as the inserts that will replace the KmR gene the mutations must have a new selection marker to counter-select against the previous I-SceI/Km mutation. After electroporation, cells were plated on LB agar plates containing 25 μg/mL Cm for the selection of positive mutants.
Once positive mutation/inserts were suspected, PCR and DNA sequencing were performed to confirm that the insertion sequences arc present and correct.
Challenge with Campylobacter jejuni
Three wild-type isolates of C. jejuni from broiler chickens were individually grown to log-phase growth, combined, serially diluted and spread plated for conventional culture enumeration as previously described (Cole et al, Effect of aeration and storage temperature on Campylobacter concentrations in poultry semen, Poult Sci 2004;83:1734-8.). These were diluted to approximately 107 to 108 cfu/ml for challenge by oral gavage, using spectrophotometric density and comparison to a previously-generated standard curve. Empirically determined cfu administered are reported for each of experiment involving challenge (see below).
Vaccination Study 1
In the first immunization study, 210 day-of-hatch broiler chicks were obtained from a local commercial hatchery and randomly assigned to one of four treatment groups: saline only (Negative control), or one of three vaccine candidate groups: cj0113, cj0420 or cj0982 , n=50/pen. Each treatment group was housed in an individual floor per on fresh pine litter and provided water and feed ad libitum. On day-of-hatch, all chicks in each treatment group were inoculated, via oral gavage, with 0.25 mL of a solution containing approximately 108 cfu/mL of the appropriate treatment. On day 21 post-hatch, all birds in each treatment group were challenged with C. jejuni, via oral gavage, with 0.25 mL of a solution containing 1×107 cfu/ml. On days 3, 11, 21 (prior to booster inoculation) and 32 post-hatch, 10-15 birds from each treatment group were humanely killed and their liver, spleen and cecal tonsils aseptically removed for the determination of organ invasion, colonization and clearance of the Salmonella vaccine vector strains. Also, on days 21 and 32 post-hatch, ileum sections were removed and processed for use in qRT-PCR and on day 32 a separate ileum sample was removed and diluted 1:5 in saline and was used to test for secretory immunoglobulin A (sIgA). In addition, blood samples were collected from 10 birds per treatment group and the serum was used for determining antibody response on days 21 and 32 post-vaccination.
Vaccination Study 2
In experiment 2, 110 day-of-hatch broiler chicks were obtained from a local commercial hatchery and randomly assigned to one of two treatment groups: saline only (vehicle control) or Salmonella vaccine candidate, cj0113, (n=55/pen). Each treatment group was housed in an individual floor pen on fresh pine litter and provided water and feed ad libitum. On day-of-hatch, all chicks in each treatment group were inoculated via oral gavage with 0.25 mL of a solution containing approximately 108 cfu/mL, of the appropriate treatment. On day 21 post-hatch, all birds in each treatment group were challenged with C. jejuni, via oral gavage, with 0.25 mL of a solution containing 1×107 cfu/ml. On days 3, 11, 21 (prior to booster inoculation) and 32 post-hatch, 10-15 birds from each treatment group were humanely killed and their liver, spleen and cecal tonsils aseptically removed for the determination of organ invasion, colonization and clearance of the Salmonella vaccine vector strains. Also, on days 21 and 32 post-hatch ileum sections were removed and processed for use in qRT-PCR. In addition, blood samples were collected from 10 birds per treatment group and the serum was used for determining antibody response on days 21 and 32 post-hatch.
Vaccination Study 3
A third experiment was similar to vaccination experiment 2 (described above) except with the addition of a third group of S. enteriditis 13A aroA/htrA without the Campylobacter epitope (SE13A) as a control for the oral vaccination of the vector itself. All sample collections were the same as vaccination study 2 except on day 32 post-hatch an additional section of ileum was used to harvest the mucosal layer for sIgA as in experiment 1.
Measurement of Campylobacter Antibody Response
Serum collected from birds in both immunization studies was used in an ELISA to determine relative antibody responses. Briefly, individual wells of a 96-well plate were coated with C. jejuni. Antigen adhesion was allowed to proceed overnight at 4° C., the plates were then washed and blocked with Superblock (Pierce) for 1 hour at room temperature. Plates were then incubated for 2 hours with a 1:50 dilution of the previously collected sera. The plates were rinsed again followed by incubation with a Peroxidase-labeled anti-chicken IgG secondary antibody (Jackson Immunolaboratories) for an additional hone After subsequent rinsing, the plates were developed using a peroxidase substrate kit (BD OptEIA, Fisher Scienfic) and absorbances were read on spectrophotometer at 450 nm. Each plate contained a positive control and negative control where a pooled sample from vaccinated chicks and pre-immune chicken serum, respectively, replaced the serum from the treatment groups. The absorbance obtained for the positive control, negative control and experimental samples were used to calculate Sample to Positive control ratios (S/P ratios) using the following calculation: (sample mean−negative control mean)/(positive control mean−negative control mean) (Brown et al. Detection of antibodies to Mycoplasma gallisepticum in egg yolk versus serum samples. J Clin Microbiol 1991;29(12):2901-3 and Davies et al. Evaluation of the use of pooled serum, pooled muscle tissue fluid (meat juice) and pooled faeces for monitoring pig herds for Salmonella, J Appl Microbiol 2003;95(5)1 016-25.). The ELISA method used for detection of sIgA was similar to the above described assay for serum immunoglobulin except we used goat anti-chicken IgA conjugated with horseradish peroxidase (GenTex) in place of the anti-chicken IgG antibody conjugate.
DNA Isolation and Quantitative PCR for C. jejuni
Total DNA extraction from ileal samples was achieved using the QIAmp DNA Stool Mini Kit (Qiagen). The manufacturer's included protocol was modified slightly in the following ways: ileal contents were removed to include the mucosal layer and diluted 1:5(w/v) with ice cold PBS+0.05% Tween 20; one ml of the slurry was added to of the included ASL Buffer in a 2.0 ml microcentrifuge tube, vortexed and heated to 70° C. for 5 minutes. Subsequently, the manufactures recommendations were followed to the last step when the DNA was eluted into a final volume of 50 l.
Quantitative determination of C. jejuni was accomplished using a previously published method with slight modifications (Skanseng et al. Comparison of chicken gut colonisation by the pathogens Campylobacter jejuni and Clostridium perfringens by real-time quantitative PCR. Mol Cell Probes 2006;20(5)269-7)9. The assay was optimized for use on the MX3005P (Agilent Technology) and Brilliant II QPCR master mix (Agilent Technologies) all other mixture components, primers, probe and cycling conditions remained as published.
A standard curve (
Statistical Analysis
Data were analyzed using Student's two-tailed t-test assuming unequal variances to compare the difference between groups and controls using JMP™ statistic software. A value of P<0.05 was considered significant.
Results
An excellent correlation of quantification of C. jejuni using conventional microbiological enumeration techniques verses the qPCR was found (
Salmonella vectored vaccine candidates or saline gavage.
Chickens were challenged with C. jejuni on day 21 post vaccination. Ileal mucosal samples were obtained on days 21 and 32 post vaccination (days 0 and 11 post challenge) and used for DNA sample preparation to enumerate C. jejuni within the gut as described above. Vaccination with vector candidates cj0420 and cj0982 caused an approximate 1 log and 2 log reduction (P<0.05), respectively, in the level of C. jejuni present in the ileal samples. Using the cj0113 vaccine candidate, there was a marked 4.8 log reduction (P<0.05) of C. jejuni in the ileum compared to the control birds (
In experiment 2, a repeat of the primary immunization study was done with only the vaccine candidate expressing cj0113. In this study, qPCR data revealed an approximate 5 log reduction of C. jejuni in cj0113 SE-vectored vaccine administered to birds when compared to the birds receiving saline only (Table III). Additionally, in experiment 3 vaccination with the cj0113 vector caused an approximate 4 log reduction, to below detectable levels, of C. jejuni as compared with the saline or Salmonella pare strain which contained no epitope insert (
Serum samples collected in each experiment on Days 21 and 32 post-vaccination were used to determine C. jejuni—specific IgG antibodies. In the first experiment all three vaccine candidates (cj0420, cj0113, cj0982) caused significantly higher antibody levels at both time points when compared to the group which received only saline (
Bacillus Vectored Vaccination Study
Production of Heterologous Proteins for Vegetative Cell Expression
Plasmid pHT10 purchased from MoBioTec/Bora Scientific, Boca Raton, Fla. (Nguyen et al., 2007) was transformed at the multiple cloning site b addition of a Bacillus subtilis codon optimized insertion sequence for cj0113 and HMGB1 (SEQ ID NO: 4 and 20, respectively). DNA sequencing was done to confirm correct sequence insertion. The newly modified plasmid was then transformed into Bacillus. Briefly, Bacillus cultures were grown overnight at 37° C. In HS media (Spizizen's medium supplemented with 0.5% glucose, 50 μg/ml DL-tryptophan, 50 μg/ml uracil, 0.02% casein hydrolysate, 0.1% yeast extract, 8 μg/ml arginine, 0.4 μg/ml histidine, 1 mM MgSO4). Inoculate 20 ml LS medium (Spizizert's medium supplemented with 0.5% glucose, 5 μg/ml DL-tryptophan, 5 μg/ml uracil, 0.01% casein hydrolysate, 0.1% yeast extract, 1 mM MgSO4, 2.5 mM MgCl2, 0.5 mM CaCl2) with 1 ml overnight culture and incubate with shaking for 3-4 hours at 30° C. Withdraw 1 ml of LS culture and add 10 μl of 0.1M EGTA and incubate at room temperature for 5 minutes. Add 1-2 μg plasmid DNA, shake for 2 hours at 37° C., and plate on LB plates with selective antibiotics. These transformed Bacillus spp. now produce heterologous epitope sequences from Campylobacter (cj0113) and HMGB1 when induced with 1 mM IPTG.
Vaccination Study
In the vaccination challenge, 100 day-of-hatch broiler chicks were obtained from a local commercial hatchery and randomly assigned to one of four treatment groups: saline only Bacillus vector alone (BSBB) or 106 or 108 Bacillus vaccine candidate, cj0113, (n=25/pen). Each treatment group was housed in an individual floor pen on fresh pine litter and provided water and feed ad libitum. On day-of-hatch, all chicks in each treatment group were inoculated via oral gavage with 0.25 mL of a solution containing approximately 106 cfu/mL of the backbone vector strain or the Cj0113 Bacillus vector. On day 10 birds received a booster vaccination of the same treatment they received on day of hatch. On day 21 post-hatch, all birds in each treatment group were challenged with C. jejuni, via oral gavage, with 0.25 mL of a solution containing 1×107 cfu/ml prepared as described above. On days 3, 11, 21 (prior to booster inoculation) and 32 post-hatch, 10-15 birds from each treatment group were humanely killed and their liver, spleen and cecal tonsils aseptically removed for the determination of organ invasion, colonization and clearance of the vaccine vector strains. Also, on days 21 and 36 post-hatch ileum sections were removed and processed for use in qRT-PCR. In addition, blood samples were collected from 15 birds per treatment group and the serum was used for determining antibody response on days 21 and 36 post-hatch.
Results
Serum samples collected on Day 36 post-vaccination were used to determine C. jejuni—specific IgG antibodies. Vaccination with the bacillus vector expressing the cj0113 polypeptide caused significantly higher antibody levels when compared to the group which received only saline or empty vector (
Chickens were challenged with C. jejuni on day 24 post vaccination. Ileal mucosal samples were obtained on days 24 and 36 post vaccination (days 0 and 11 post challenge) and used for DNA sample preparation to enumerate C. jejuni within the gut as described above. Vaccination with the Bacillus cj0113 vector caused an approximate 3 log reduction (P<0.05) in the level of C. jejuni present in the ileal samples (
Vaccination Study in Turkey Poults
Since the Salmonella-vectored j0 113 vaccine has been effective in reducing Campylobacter recovery after challenge in chickens we hypothesized that the vaccine may also work in poults. Therefore, to further evaluate the use of this epitope delivery system, an experiment was designed to test the effectiveness of the vaccine against C. coli challenge in turkey poults.
The ΔSE-c-j0113 vaccine was constructed as described above. Salmonella enteritidis phage type 13A (SE13A) was used as the backbone strain for this vaccine candidate. This isolate was double attenuated by irreversible gene deletions in the aroA and htrA genes as previously described. Recombinant strains containing these deletions were then modified further to incorporate the cj0113 insert and an immunostimulatory molecule, CD-154 (ΔSE-cj0113). These sequences were integrated as previously described.
In this experiment, 70 poults were obtained from a local hatchery. They were randomly assigned to one of two treatment groups and tagged. Thirty poults were orally gavaged with 108 cfu/poult ΔSE-cj0113 and the remaining poults were sham treated with saline. On day 21, poults were challenged with 1.5×108 cfu/poult of C. coli by oral gavage. Liver, spleen and cecal tonsils were aseptically removed on day 3 (N=10), day 21 (N=10) and day 35 (N=10) for detection of vector recovery by enrichment in tetrathionate broth and plating on Brilliant Green agar. On days 21 and 35, ingesta (N=10) and tissue (N=5) samples were collected for further analysis. Ingesta from the ileum of cultured poults were analyzed using qPCR for enumeration of C. coli. Tissue samples from the same region were collected and total RNA was extracted. Interferon gamma and TNF-alpha like vaccine responses were evaluated.
Results
As previously shown in chickens, the poults developed a significant immune response following vaccination with Salmonella-vectored Cj0113 vaccine. After challenge, there was a about a five-log reduction in Campylobacter coli in the ileum as compared to vector only controls (
This patent application is a national stage filing under 35 U.S.C. 371 of International Application No PCT/US2011/039832 filed Jun. 9, 2011, which claims the benefit of priority of U.S. Provisional Patent Application No. 61/353,039, filed Jun. 9, 2010, both of which are incorporated herein by reference in their entirety. A Sequence Listing accompanies this application and is incorporated herein by reference in its entirety. The Sequence Listing was filed with the application as a text file on Jun. 9, 2011.
This invention was made with government support under grant number 208-35-201-04-683, awarded by the USDA/NRI. The government has certain rights in the invention.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2011/039832 | 6/9/2011 | WO | 00 | 12/7/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/156619 | 12/15/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5683700 | Charles et al. | Nov 1997 | A |
5747309 | Allan et al. | May 1998 | A |
5962406 | Armitage et al. | Oct 1999 | A |
5981724 | Armitage et al. | Nov 1999 | A |
6087329 | Armitage et al. | Jul 2000 | A |
6190669 | Noriega et al. | Feb 2001 | B1 |
6264951 | Armitage et al. | Jul 2001 | B1 |
6290972 | Armitage et al. | Sep 2001 | B1 |
6306387 | Galan | Oct 2001 | B1 |
6410711 | Armitage et al. | Jun 2002 | B1 |
6479258 | Short | Nov 2002 | B1 |
6713279 | Short | Mar 2004 | B1 |
6902906 | Chatfield | Jun 2005 | B1 |
6923957 | Lowery et al. | Aug 2005 | B2 |
6923958 | Xiang et al. | Aug 2005 | B2 |
6936425 | Hensel et al. | Aug 2005 | B1 |
6969609 | Schlom et al. | Nov 2005 | B1 |
7087573 | Lazarus et al. | Aug 2006 | B1 |
7332298 | Kornbluth | Feb 2008 | B2 |
7371392 | Tripp et al. | May 2008 | B2 |
7405270 | Armitage et al. | Jul 2008 | B2 |
7495090 | Prussak et al. | Feb 2009 | B2 |
7842501 | Cai et al. | Nov 2010 | B2 |
7928213 | Prussak et al. | Apr 2011 | B2 |
20010021386 | Nuijten et al. | Sep 2001 | A1 |
20030165538 | Goldman et al. | Sep 2003 | A1 |
20040006006 | Armitage et al. | Jan 2004 | A9 |
20040047873 | Al-Shamkhani et al. | Mar 2004 | A1 |
20040053841 | Tracey et al. | Mar 2004 | A1 |
20040141948 | O'Keefe | Jul 2004 | A1 |
20040156851 | Newman | Aug 2004 | A1 |
20040203039 | Hensel et al. | Oct 2004 | A1 |
20050181994 | Chamberlain et al. | Aug 2005 | A1 |
20050226888 | Deisseroth et al. | Oct 2005 | A1 |
20060014248 | Marshall et al. | Jan 2006 | A1 |
20060078994 | Healey et al. | Apr 2006 | A1 |
20060121047 | Tracey | Jun 2006 | A1 |
20060233829 | Curtiss | Oct 2006 | A1 |
20060286074 | Tang et al. | Dec 2006 | A1 |
20070025982 | Ledbetter et al. | Feb 2007 | A1 |
20070082400 | Healey et al. | Apr 2007 | A1 |
20070128183 | Meinke et al. | Jun 2007 | A1 |
20070128223 | Tang et al. | Jun 2007 | A1 |
20070237779 | Ledbetter et al. | Oct 2007 | A1 |
20070249553 | Newell et al. | Oct 2007 | A1 |
20080004207 | Tsung et al. | Jan 2008 | A1 |
20080069821 | Yang et al. | Mar 2008 | A1 |
20080075728 | Newman | Mar 2008 | A1 |
20080124320 | O'Keefe | May 2008 | A1 |
20080305120 | Messmer et al. | Dec 2008 | A1 |
20090004194 | Kedl | Jan 2009 | A1 |
20100040608 | Wahren-Herlenius et al. | Feb 2010 | A1 |
20100047231 | Zabaleta Azpiroz et al. | Feb 2010 | A1 |
20100112002 | Lien et al. | May 2010 | A1 |
20100233152 | Bullerdiek | Sep 2010 | A1 |
20100291109 | Kedl | Nov 2010 | A1 |
20100292309 | Vile et al. | Nov 2010 | A1 |
20110020318 | Tracey et al. | Jan 2011 | A1 |
Number | Date | Country |
---|---|---|
WO 9308207 | Apr 1993 | WO |
WO 9514487 | Jun 1995 | WO |
WO 9626735 | Sep 1996 | WO |
WO 9640918 | Dec 1996 | WO |
WO 9927948 | Jun 1999 | WO |
WO 9932138 | Jul 1999 | WO |
WO 9959609 | Nov 1999 | WO |
WO 0063395 | Oct 2000 | WO |
WO 0063405 | Oct 2000 | WO |
WO 0142298 | Jun 2001 | WO |
WO 0156602 | Aug 2001 | WO |
WO 0236769 | May 2002 | WO |
WO 02092773 | Nov 2002 | WO |
WO 03026691 | Apr 2003 | WO |
WO 03099340 | Dec 2003 | WO |
WO 2004009615 | Jan 2004 | WO |
WO 2004046338 | Jun 2004 | WO |
WO 2004046345 | Jun 2004 | WO |
WO 2005025604 | Mar 2005 | WO |
WO 2005035570 | Apr 2005 | WO |
WO 2005058950 | Jun 2005 | WO |
WO 2005113598 | Dec 2005 | WO |
WO 2006012373 | Feb 2006 | WO |
WO 2006042177 | Apr 2006 | WO |
WO 2006046017 | May 2006 | WO |
WO 2006105972 | Oct 2006 | WO |
WO 2007011606 | Jan 2007 | WO |
WO 2007042583 | Apr 2007 | WO |
WO 2007054658 | May 2007 | WO |
WO 2007056266 | May 2007 | WO |
WO 2007103048 | Sep 2007 | WO |
WO 2007117682 | Oct 2007 | WO |
WO 2008036675 | Mar 2008 | WO |
WO 2008109825 | Sep 2008 | WO |
WO 2009059018 | May 2009 | WO |
WO 2009059298 | May 2009 | WO |
WO 2011091255 | Jul 2011 | WO |
Entry |
---|
Wyszynska et al., Vaccine, vol. 22, Issues 11-12, Mar. 29, 2004, pp. 1379-1389. |
Greenspan et al. (Nature Biotechnology 7: 936-937, 1999). |
Ellis (Vaccines, W.B. Saunders Company, Chapter 29, 1988, pp. 568-574). |
al-Ramadi, B. K. et al., “Induction of innate immunity by IL-2 expressing Salmonella confers protection against letal challenge,” Mol. Immunol. (2003) 39:763-770. |
al-Ramadi, B. K. et al., “Influence of vector-encoded cytokines on anti-Salmonella immunity: divergent effects of interleultin-2 and tumor necrosis factor alpha,” Infect. Immun. (2001) 69:3960-3988. |
Andersson, U. et al., “HMGB1 is a therapeutic target for sterile inflammation and infection,” Annu. Rev. Immunol. (2011) 29:139-162. |
Burnens, A. et al., “Identification and characterization of an immunogenic outer membrane protein of Campylobacter jejuni,” J. Clin. Microbiol. (1995) 33(11):2826-2832. |
De Zoete, M.R. et al., “Vaccination of chickens against Campylobacter,” Vaccine (2007). |
Dumitriu, I.E. et al., “HMGB1: guiding immunity from within,” Trends Immunol. (2005) 26(7):381-387. |
Kimura, R. et al., “Enhancement of antibody response by high mobility group box protein-1-based DNA immunization” J. of Immunol. Methods (2010) 361:21-30. |
Pawelec, D. et al., “Cloning and characterization of a Campylobacter jejuni 72Dz/92 gene encoding a 30 kDa immunopositive protein, component of the ABC transport system: expression of the gene in avirulent Salmonella typhimurium,” FEMS Immuno. Med. Microbiol. (1997) 19(2):137-50. |
Pawelec, D. et al., “Genetic diversity of the Campylobacter genes coding immunodominant proteins,” FEMS Microbiol. Lett. (2000) 185(1):43-49. |
Pisetsky, D.S. et al., “High-mobility group box protein 1 (HMGB1): an alarmin mediating the pathogenesis of rheumatic disease,” Arthritis Res. Ther. (2008) 10(3):209. |
Prokhorova: T. A. et al., “Novel surface polypeptides of Campylobacter jejuni as traveller's diarrhoea vaccine candidates discovered by proteomics,” Vaccine (2006) 24(40-41):6446-6455. |
Schrotz-King, P. et al., “Campylobacter jejuni proteomics for new travellers' diarrhoea vaccines,” Travel Med. Infect. Dis. (2007) 5(2):106-109. |
Sizemore, D.R. et al., “Live, attenuated Salmonella typhimurium vectoring Campylobacter antigens,” Vaccine (2006) 24(18):3793-3803. |
Ulloa, L. et al., “High-mobility group box 1 (HMGB1) protein: friend and foe,” Cytokine Growth Factor Rev. (2006) 17(3):189-201. |
Agterberg, M. et al., “Outer membrane protein PhoE as a carrier for the exposure of foreign antigenic determinants at the bacterial cell surface,” Antoine Van Leenwenhoek (1991) 59(4):249-262. |
Babu, U., et al., “Salmonella enteritidis clearance and immune responses in chickens following Salmonella vaccination and challenge,” Vet. Immunol. Immunopathol. (2004)101:251-257. |
Barr, T.A. et al., “A potent adjuvant effect of CD40 antibody attached to antigen,” Immunology (2003) 109:87-92. |
Barrow, P. A., et al., “Reduction in faecal excretion of Salmonella typhimurium strain F98 in chickens vaccinated with live and killed S. typhimurium organisms,” Epidemiol. Infect. (1990) 104:413-426. |
Blomfield, I.C. et al., “Allelic exchange in Escherichia coli using the Bacillus subtilis sacB gene and a temperature-sensitive pSC101 replicon,” Mol Microbiol (1991) 5(6):1447-1457. |
Charbit, A. et al., “Probing the topology of a bacterial membrane protein by genetic insertion of a foreign epitope; expression at the cell surface,” EMBO J (1986) 5(11):3029-3037. |
Charbit, A. et al., “Versatility of a vector for expressing foreign polypeptides at the surface of gram-negative bacteria,” Gene (1988) 70(1):181-189. |
Chatfield et al., “The development of oral vaccines based on live attenuated Salmonella strains,” FEMS Immunol. Med. Micrbiol. (1993) 7:1-7. |
Cole, K. et al., “Evaluation of a novel recombinant Salmonella vaccine for avian influenza,” Poultry Science (2007) 86(Supp. 1):585-586. |
Cox, M.M. et al., “Scarless and site-directed mutagenesis in Salmonella enteritidis chromosome,” BMC Biotech. (2007) 7(59):10 pages. |
Farnell, M.B. et al., “Upregulation of oxidative burst and degranulation in chicken heterophils stimulated with probiotic bacteria,” Poult. Sci. (2006) 85:1900-1906. |
Fecteau, J.F. et al., “CD40 Stimulation of Human Peripheral B Lymphocytes: Distinct Response from Naïve and Memory Cells,” J Immunol (2003) 171:4621-4629. |
Gares, S.L. et al., “Immunotargeting with CD154 (CD40 ligand) enhances DNA vaccine reponses in ducks,” Clin. Vaccine Immun. (2006) 13:958-965. |
Gast, R.K. et al., “The relationship between the magnitude of the specific antibody response to experimental Salmonella enteritidis infection in laying hens and their production of contaminated eggs,” Avian Diseases (2001) 45:425-431. |
Grangette, C. et al., “Protection against tetanus toxin after intragastric adminstration of two recombinant lactic acid bacteria: Impact and strain viability and in vivo persistence,” Vaccine (2002) 20:3304-3309. |
Grewal, L.S. et al., “CD40 and CD154 in cell-mediated immunity,” Annu. Rev. Immunology. (1998) 16:111-135. |
Harcourt, J.L. et al., “CD40 ligand (CD154) improves the durability of respiratory syncytial virus DNA vaccination in BALB/c mice,” Vaccine (2003) 21(21-22):2964-2979. |
Hayes, L.J. et al., “Chlamydia trachomatis major outer membrane protein epitopes expressed as fusions with LamB in an attenuated aro A strain of Salmonella typhimurium: their application as potential immunogens,” J. of General Microbiology (1991) 137:1557-1564. |
Holmgren, J. et al., “Mucosal immunity: implications for vaccine development,” Immunobiol. (1992) 184:157-179. |
Husseiny, M.L. et al., “Rapid method for the construction of Salmonella enterica serovar typhimurium vaccine carrier strains,” Infec. Immun. (2005) 73(3):1598-1605. |
Koch., F. et al., “High level IL-12 production by murine dendritic cells: upregulation via MHC class II and CD40 molecules and downregulation by IL-4 and IL-10,” J. Exp. Med. (1996) 184:741-746. |
Kotton, C.N. et al., “Enteric pathogens as vaccine vectors for foreign antigen delivery,” Infect. Immun. (2004) 72:5535-5547. |
Kwon, Y.M. et al., “Salmonella-based vaccines for infectious diseases,” Expert Review of Vaccines (2007) 6(2):147-152. |
Lavelle, E.C. et al., “Delivery systems and adjuvants for oral vaccines,” Expert Opin. Drug Deliv. (2006) 3(6):747-762. |
Layton, S.L., et al., “Vaccination of chickens with recombinant Salmonella expressing M2e and CD154 epitopes increases protection and decreases viral shedding after low pathogenic avian influenza challenge,” Poultry Science (2009) 88(11):2244-2252. |
Layton et al., Evaluation of Salmonella-vectored Campylobacter peptide epitopes for reduction of Campylobacter jejuni in broiler chickens, Clin. Vaccine Immunol. (2011) 18(3):449-454. |
Lee, J.S. et al., “Surface-displayed viral antigens on Salmonella carrier vaccine,” Nat. Biotechnol. (2000) 18:645-648. |
Li, W., “Synerigistic antibody induction by antien-CD40 ligand fusion protein as improved immunogen,” Immunology (2005) 115(2):215-222. |
Lowe, D.C. et al., “Characterization of candidate live oral Salmonella typhi vaccine strains harboring defined mutations in aroA, aroC, and htrA,” Infection and Immunity Feb. 1999:700-707. |
Mann, J.F. et al., “Delivery systems: a vaccine strategy for overcoming mucosal tolerance?” Expert Rev. Vaccines (2009) 8(1):103-112. |
Miga, A. et al., “The role of CD40-CD154 interactions in the regulation of cell mediated immunity,” Immunol. Invest. (2000) 29:111-114. |
Mohamadzadeh, M. et al., “Targeting mucosal dendritic cells with microbial antigens from probiotic lactic acid bacteria,” Expert Rev. Vaccines (2008) 7(2):163-174 (Abstract). |
Moyle, P.M. et al., “Mucosal immunisation: adjuvants and delivery systems,” Curr. Drug Deliv. (2004) 1(4):385-396 (Abstract). |
O'Callaghan, D. et al., “Immunogenicity of foreign peptide epitopes expressed in bacterial envelope proteins,” Research in Microbiology (1990) 141:963-969. |
Pasetti, M. et al., “Animal models paving the way for clinical trials of attenuated Salmonella enterica servoar Typhi live oral vaccines and live vectors,” Vaccine (2003) 21:401-418. |
Rabsch, W. et al., “Competitive exclusion of Salmonella enieritidis by Salmonella gallinarum in poultry,” Emerging Inf. Diseases (2000) 6(5):443-448. |
Rovere-Querini, P. et al., “HMGB1 is an endogenous immune adjuvant released by necrotic cells,” EMBO Rep. (2004) 5(8):825-830. |
Russmann, H. et al. “Delivery epitopes by the Salmonella type III secretion system for vaccine development,” Science (1998) 281(5376):565-568. |
Su, G.F. et al., “Construction of stable LamB-Shiga toxin B subunit hybrids: analysis of expression in Salmonella typhimurium aroA strains and stimulation of B subunit-specific mucosal and serum antibody responses,” Infect Immun (1992) 60(8):3345-3359. |
Swayne, D.E., “Vaccines for List A poultry diseases: emphasis on avian influenza,” Dev. Biol. (2003)114:201-212. |
Tregaskes, C.A. et al., “Conservation of biological properties of the CD40 ligand, CD154 in a non-mammalian vertebrate,” Dev. Comp. Immunol. (2005) 29:361-374. |
Vega, M.L. et al., “A Salmonella typhi OmpC fusion protein expressing the CD154 Trp140-Ser149 amino acid strand binds CD40 and activates a lymphoma B-cell line,” Immunol. (2003) 110:206-216. |
Verjans, G.M. et al., “Intracellular processing and presentation of T cell epitopes, expressed by recombinant Escherichia coli and Salmonella typhimurium, to human T cells,” Eur J immunol (1995) 25(2):405-410. |
Vierira-Pinto, M. et al., “Occurrence of Salmonella in the ileum, ileocolic lymph nodes, tonsils, mandibular lymph nodes and carcasses of pigs slaughtered for consumption,” J Vet Med B Infection Dis Vet Public Health (2005) 52(10):476-481. |
Wang, J. et al., “Immunogenicity of viral B-cell ephopcs inserted into two surface loops of the Escherichia coli K12 LamB protein and expressed in an attenuated aroA strain of Salmonella typhimurium,” Vaccine (1999) 17(1):1-12. |
Wyszynska, A. et al., “Oral immunization of chickens with avirulent Salmonella vaccine streain carring C. jejuni 72Dz/92 cjaA gene elicits specific hummoral immune response associated with protection against challenge with wild-type Campylobacter,” Vaccine (2004) 22(11-12):1379-1389. |
Xu, Y. et al., “The role of CD40-CD154 interaction in cell immunoregulation,” J. Biomed. Sci. (2004) 11:426-438. |
International Search Report and Written Opinion for Application No. PCT/US2011/039832 dated Nov. 23, 2011 (23 pages). |
Office Action for U.S. Appl. No. 12/441,851 dated Sep. 5, 2012 (12 pages). |
Office Action for U.S. Appl. No. 12/441,851 dated May 8, 2013 (8 pages). |
Buckley, A.M. et al., “Evaluation of live-attenuated Salmonella vaccines expressing Campylobacter antigens for control of C. jejuni in poultry,” (2010) Vaccine 28(4):1094-1105. |
Manoj, S. et al., “Targeting with Bovine CD154 enhances humoral immune responses induced by a DNA vaccine in sheep,” (2003) Journal of immunology 170:989-996. |
Mauriello, E.M.F. et al., “Display of heterologous antigens on the Bacillus subtilis spore coat using CotC as a fusion partner,” (2004) Vaccine 22(9-10):1177-1187. |
Nakajima, A. et al., “Antitumor effect of CD40 ligand: Elicitation of local and systemic antitumor responses by IL-12 and B7,” (1998) Journal of Immunology 161:1901-1907. |
Ochoa-Reparaz, J. et al., “Humoral immune response in hens naturally infected with Salmonella enteritidis against outer membrane proteins and other surface structural antigens,” (2004) Vet. Res. 35:291-298. |
Saenz, R. et al., “HMGB1-derived peptide acts as adjuvant inducing immune responses to peptide and protein antigen,” (2010) Vaccine 28(47):7556-7562. |
Number | Date | Country | |
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20130084304 A1 | Apr 2013 | US |
Number | Date | Country | |
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61353039 | Jun 2010 | US |