None.
Coccidiosis, an infectious disease of poultry, swine, and cattle caused by the Apicomplexan protozoal parasite Eimeria, presents problems worldwide. Coccidiosis is among the top ten infectious diseases of poultry in terms of its economic impact on the poultry industry. Other members of the Apicomplexan family also cause disease, including Plasmodium, Cryptosporidium and Toxoplasma which are the causative agents of malaria, cryptosporidiosis and toxoplasmosis, respectively. The vaccines currently available against Eimeria are based on controlled low dosage of essentially fully virulent but drug-sensitive Eimeria parasites. Vaccination with current Eimeria-based vaccines produces substantial vaccine-reaction morbidity and economic losses in vaccinated flocks. Thus an effective low-virulence vaccine against Eimeria is needed. An effective vaccine for Eimeria may also prove useful as a vaccine against other Apicomplexan parasites.
A vaccine comprising a first polynucleotide sequence encoding a TRAP polypeptide or an immunogenic fragment thereof is disclosed. The TRAP polypeptide may comprise comprises SEQ ID NO:1, SEQ ID NO:2, or SEQ ID NO:3, or an immunogenic fragment thereof. The vaccines optionally further include a second polynucleotide sequence encoding a CD154 polypeptide capable of binding CD40. The CD154 polypeptides include fewer than 50 amino acids and comprise amino acids 140-149, or a homolog thereof.
Vaccines according to the present invention may be comprised within a vector, such as a virus, bacterium, or liposome. In one aspect, a vaccine comprising a Salmonella enteritidis comprising a first polynucleotide sequence encoding a TRAP polypeptide is provided.
In still another aspect, the invention includes methods of enhancing the immune response against an Apicomplexan parasite in a subject by administering a vaccine according to the present invention.
In a still further aspect, the invention includes methods of reducing morbidity associated with infection with an Apicomplexan parasite in a subject by administering a vaccine according to the present invention.
Recombinant DNA technologies enable relatively easy manipulation of many bacterial and viral species. Some bacteria and viruses are mildly pathogenic or non-pathogenic, but are capable of generating a robust immune response. These bacteria and viruses make attractive vaccines for eliciting an immune response to antigens. Bacterial or viral vaccines may mimic a natural infection and produce robust and long lasting mucosal immunity. Vaccines 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.
In one aspect, a vaccine comprising a first polynucleotide sequence encoding a TRAP polypeptide or an immunogenic fragment thereof is provided. The TRAP polypeptide may comprise SEQ ID NO:11 or an immunogenic fragment of SEQ ID NO:11. A vaccine includes any composition comprising a polynucleotide encoding an antigenic polypeptide that is capable of eliciting an immune response to the polypeptide. In another aspect, the use of vectors, such as bacterial vectors, for vaccination and generation of immune responses against Eimeria or other Apicomplexan parasites such as Plasmodium (the causative agent of malaria), Toxoplasma and Cryptosporidium is disclosed. Salmonella strains make suitable vectors because bacterial genes may be mutated or attenuated to create bacteria with low to no pathogenesis to the infected or immunized subject, while maintaining immunogenicity.
A high molecular mass, asexual stage antigen from Eimeria maxima (EmTFP250) was demonstrated to be a target for maternal antibodies produced by breeding hens infected with this protozoan parasite. Analysis of the amino acid sequence of the antigen revealed a novel member of the TRAP (thrombospondin-related anonymous protein) family, containing 16 thrombospondin type-1 repeats and 31 epidermal growth factor-like calcium binding domains. EmTFP250 or TRAP also contains two low complex, hydrophilic regions rich in glutamic acid and glycine residues, and a transmembrane domain cytosolic tail associated with parasite gliding motility that is highly conserved within apicomplexan microneme proteins. Several potential epitopes were selected and are identified in SEQ ID NO:1-3 and 11. Due to the conserved nature of this antigen, expression of these epitopes by a vector may induce protective immunity against multiple Apicomplexan parasites.
Salmonella may provide a useful vector because it can survive the gastrointestinal tract of the host and give rise to a mucosal immune response. Oral vaccines using a Salmonella vector produce a robust mucosal immune response and are relatively easy to administer to both animals and humans. However, many of the current Salmonella vaccine strains are not as effective in generating a strong protective immune response as compared to their more virulent counterparts. Virulent strains provide a robust immune response but may also cause significant morbidity to the vaccinated subject. A Salmonella strain that could be used for effective mucosal, e.g., oral, vaccination would provide a vector that could be used to readily vaccinate a subject against one or more pathogenic agents, such as Apicomplexan parasites.
A Salmonella enteritidis strain useful as a vector, and various recombinant vectors made using this strain, are described. Specifically, a Salmonella enteritidis 13A (SE13A) capable of expressing an exogenous TRAP polypeptide is provided. In addition, a vaccine and methods of enhancing an immune response in a subject by administering the vaccine comprising a TRAP polynucleotide sequence encoding a TRAP polypeptide and a CD154 polynucleotide sequence encoding a polypeptide of CD154 or a homolog thereof that is capable of binding to CD40 are disclosed. The vaccines may be used to enhance an immune response against Eimeria or another Apicomplexan parasite, such as Plasmodium, Toxoplasma or Cryptosporidium, or may be used to reduce the morbidity associated with an infection caused by an Apicomplexan parasite.
A wild-type isolate of Salmonella, Salmonella enteritidis 13A (SE13A) (deposited with the American Type Culture Collection (ATCC) on Sep. 13, 2006, deposit number PTA-7871), was selected based upon its unusual ability to cause mucosal colonization and sub-mucosal translocation in chickens, permitting robust presentation of associated antigens or epitopes in commercial chickens. Importantly, this wild-type Salmonella isolate causes no clinically detectable disease or loss of performance in commercial chickens, indicating little disease-causing potential of the wild-type Salmonella in vertebrate animals.
The SE13A isolate may be further attenuated by inactivating at least one gene necessary for sustained replication of the bacteria outside of laboratory or manufacturing conditions. Attenuated or variant Salmonella strains that can be used as vectors are described below. SE13A was used to generate attenuated Salmonella strains to develop vaccines and generate enhanced immune responses. SE13A is invasive, non-pathogenic for poultry and causes no measurable morbidity. These features result in an enhanced immune response as compared to non-invasive bacterial vectors. Attenuation of SE13A by mutation of genes that limit the ability of the bacterium to spread may increase the safety of the vaccine. SE13A strains with mutations in aroA or htrA retain the ability to generate an immune response, but have limited replication in the host. Thus, the attenuation increases the safety of the vector without compromising the immunogenicity.
Mutations may be made in a variety of other Salmonella genes including, but not limited to, cya, crp, asd, cdt, phoP, phoQ, ompR, outer membrane proteins, dam, htrA or other stress related genes, aro, pur and gua. As shown in the Examples, mutations in aroA and htrA were found to attenuate SE13A. The aro genes are enzymes involved in the shikimate biosynthesis pathway or the aromatase pathway and aro mutants are auxotrophic for the aromatic amino acids tryptophan, tyrosine and phenylalanine. htrA is a stress response gene that encodes a periplasmic protease that degrades aberrant proteins. Mutants in htrA are also attenuated and display increased sensitivity to hydrogen peroxide.
The mutations in aroA and htrA described in the Examples are deletion mutations, but the mutations can be made in a variety of ways. Suitably, the mutations are non-reverting mutations that cannot be repaired in a single step. Suitable mutations include deletions, inversions, insertions and substitutions. A vector may include more than one mutation, for example a vector may contain mutations in both aroA and htrA. Methods of making such mutations are well known in the art.
Polynucleotides encoding TRAP polypeptide antigens and other antigens from any number of pathogenic organisms may be inserted into the vector (e.g., SE13A) and expressed by the bacteria. The expression of these polynucleotides by the vector will allow generation of antigenic polypeptides following immunization of the subject. The polynucleotides may be inserted into the chromosome of the bacteria or encoded on plasmids or other extrachromosomal DNA. Those of skill in the art will appreciate that numerous methodologies exist for obtaining expression of polynucleotides in vectors such as Salmonella. The polynucleotides may be operably connected to a promoter (e.g., a constitutive promoter, an inducible promoter, etc.) by methods known to those of skill in the art. Suitably, polynucleotides encoding TRAP antigens are inserted into a bacterial polynucleotide that is expressed. Suitably, the bacterial polynucleotide encodes a transmembrane protein, and the polynucleotide encoding the TRAP antigen is inserted into the bacterial polynucleotide sequence to allow expression of the TRAP antigen on the surface of the bacteria. For example, the polynucleotide encoding TRAP may be inserted in frame into the bacterial polynucleotide in a region encoding an external loop region of a transmembrane protein such that the bacterial polynucleotide sequence remains in frame. See Example 1.
Alternatively, the first polynucleotide encoding TRAP antigen may be inserted into a polynucleotide encoding a secreted polypeptide. Those of skill in the art will appreciate that the polynucleotide encoding the TRAP antigen could be inserted in a wide variety of bacterial polynucleotides to provide expression and presentation of the TRAP antigen to the immune cells of a subject treated with the vaccine. In the Examples, a first polynucleotide encoding the TRAP polypeptide was inserted into loop 9 of the lamB gene of SE13A. The polynucleotide encoding the TRAP antigen may be included in a single copy or more than one copy. A bacterial vector containing multiple copies of the TRAP antigen inserted into loop 9 of lamB may also be generated. Alternatively, multiple copies of an epitope may be inserted into the bacterial vector at more than one location.
Suitably the first polynucleotide encodes a portion of the TRAP polypeptide or the entire TRAP polypeptide. The polynucleotide may be inserted into the vector. In the Examples, three polypeptides (SEQ ID NO:1-3) were incorporated into SE13A. Suitably, the portion of the TRAP polypeptide inserted into the vector is an immunogenic fragment. An immunogenic fragment is a peptide or polypeptide capable of eliciting a cellular or humoral immune response. Suitably, an immunogenic fragment of TRAP may be 6 or more consecutive amino acids, 10 or more amino acids, 15 or more amino acids or 20 or more amino acids of the full-length protein sequence.
Other suitable epitopes for inclusion in a vaccine having TRAP comprised within a vector include, but are not limited to, polynucleotides encoding other Eimeria-related polypeptides. One of skill in the art will appreciate that a variety of sequences may be used in combination with any other antigen and may also be used in conjunction with polypeptides encoding immune stimulatory peptides such as a polypeptide of CD 154.
As described in more detail below, a vaccine including a vector may include a CD 154 polypeptide that is capable of binding CD40 in the subject and stimulating the subject to respond to the vector and its associated antigen. Involvement of dendritic cells (DCs) is essential for the initiation of a powerful immune response as they possess the unique ability to activate naïve T cells, causing T cell expansion and differentiation into effector cells. It is the role of the DC, which is an antigen presenting cell (APC) found in virtually all tissues of the body, to capture antigens, transport them to associated lymphoid tissue, and then present them to naïve T cells. Upon activation by DCs, T cells expand, differentiate into effector cells, leave the secondary immune organs, and enter peripheral tissues. Activated cytotoxic T cells (CTLs) are able to destroy virus-infected cells, tumor cells or even APCs infected with intracellular parasites (e.g., Salmonella) and have been shown to be critical in the protection against viral infection. CD40 is a member of the TNF-receptor family of molecules and is expressed on a variety of cell types, including professional antigen-presenting cells (APCs), such as DCs and B cells. Interaction of CD40 with its ligand CD 154 is extremely important and stimulatory for both humoral and cellular immunity. Stimulation of DCs via CD40, expressed on the surface of DCs, can be simulated by anti-CD40 antibodies. In the body, however, this occurs by interaction with the natural ligand for CD40 (i.e. CD154) expressed on the surface of activated T-cells. Interestingly, the CD40-binding regions of CD154 have been identified. The CD40-binding region of CD 154 may be expressed on the surface of a vector, such as a Salmonella vector, and results in an enhanced immune response against a co-presented peptide sequence.
As described above, polynucleotides encoding CD154 polypeptides may be inserted into the chromosome of the vector or maintained extrachromosomally. A CD 154 polypeptide may be a portion of CD154 full-length protein or the entire CD154 protein. Suitably, the CD154 polypeptide is capable of binding CD40. One of skill in the art will appreciate that these polynucleotides can be inserted in frame in a variety of polynucleotides and expressed in different parts of the vector or may be secreted. The polynucleotide encoding a CD 154 polypeptide capable of enhancing the immune response to TRAP may also encode the TRAP antigen. The polynucleotide encoding a CD154 polypeptide may be linked to the polynucleotide encoding the TRAP antigen, such that in the vector, the CD 154 polypeptide and the TRAP antigen are present on the same polypeptide. In the Examples, a polynucleotide encoding a polypeptide of CD154 that is capable of binding to CD40 also encodes the TRAP antigen. See SEQ ID NOS: 1, 2, 3 and 11 in the attached sequence listing. In the Examples, the polynucleotides (SEQ ID NO:13-15) encoding the TRAP antigen and the polynucleotide encoding the CD154 polypeptide are both inserted in loop 9 of the lamB gene. Those of skill in the art will appreciate that bacterial polynucleotides encoding other transmembrane proteins and other loops of the lamB gene may also be used.
As discussed above, a CD 154 polynucleotide encoding a CD154 polypeptide that is capable of enhancing the immune response to the antigen may be included in the vaccine. Suitably, the CD 154 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 CD 154 sequence and CD40 binding region are not highly conserved among the various species. The CD154 sequences of chicken and human are provided in SEQ ID NO:10 and SEQ ID NO:4, 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:5, SEQ ID NO:6, SEQ ID NO:7, SEQ ID NO:8, and SEQ ID NO:9, respectively. Although there is variability in the sequences in the CD40 binding region between species, the human CD 154 polypeptide was able to enhance the immune response in chickens. Therefore, one may practice the invention using species specific CD 154 polypeptides or a heterologous CD 154 polypeptide.
In the Examples, several SE13A recombinant bacteria were generated. In each of the SE13A strains containing both the TRAP and CD154 polynucleotides, the TRAP polypeptide and the CD154 polypeptide were encoded on the same polynucleotide and were in frame with each other and with the Salmonella lamB polynucleotide in which they were inserted. In alternative embodiments, the CD 154 polypeptide and the TRAP polypeptide may be encoded by distinct polynucleotides. SE13A aroA htrA TRAP contains a deletion in aroA and htrA and encodes both the TRAP epitope (SEQ ID NO:1-3) and optionally the CD154 polypeptide (SEQ ID NO:4) inserted into loop 9 of lamB.
Compositions comprising an attenuated Salmonella strain and a pharmaceutically acceptable carrier are also provided. A pharmaceutically acceptable carrier is any carrier suitable for in vivo administration. Examples of pharmaceutically acceptable carriers suitable for use in the composition include, but are not limited to, water, buffered solutions, glucose solutions or bacterial culture fluids. Additional components of the compositions may suitably include, for example, 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 in a subject by administering a vaccine containing a TRAP polypeptide and a CD 154 polypeptide capable of binding to CD40 and activating CD40 are also provided. The vaccine comprising the polynucleotide encoding a CD154 polypeptide capable of binding to CD40 is administered to a subject in an amount effective to enhance the immune response of the subject to the vaccine. Suitably, the vaccine contains a polynucleotide encoding a polypeptide including amino acids 140-149 of the human CD 154 polypeptide (SEQ ID NO:4) or a homolog thereof. Therefore, a homologue of amino acid 140-149 derived from one species may be used to stimulate an immune response in a distinct species.
Several suitable polypeptides are identified herein. Suitably, the polynucleotide encodes a CD154 polypeptide from the same species as the subject. Suitably, a polynucleotide encoding the polypeptide of SEQ ID NO:5 is used in human subjects, a polynucleotide encoding the polypeptide of SEQ ID NO:6 is used in chickens, a polynucleotide encoding the polypeptide of SEQ ID NO:7 is used in ducks, a polynucleotide encoding the polypeptide of SEQ ID NO:8 is used in mice, and a polynucleotide encoding the polypeptide of SEQ ID NO:9 is used in cows. In the Examples, the human CD154 polypeptide (SEQ ID NO:5) was used in a chicken vaccine and was demonstrated to enhance the immune response to a foreign antigen. Thus other heterologous combinations of CD 154 polypeptides and subjects may be useful in the methods of the invention. The CD154 polypeptide may be used to enhance the immune response in the subject to any foreign antigen or antigenic polypeptide present in the vaccine in addition to the TRAP polypeptide. One of skill in the art will appreciate that the CD 154 polypeptide could be used to enhance the immune response to more than one antigenic polypeptide present in a vaccine.
The polypeptide from CD154 stimulates an immune response at least in part by binding to its receptor, CD40. The Examples used a polypeptide homologous to the CD 154 polypeptide which is expressed on immune cells of the subject and which is capable of binding to the CD40 receptor on macrophages and other antigen presenting cells. Binding of this ligand-receptor complex stimulates macrophage (and macrophage lineage cells such as dendritic cells) to enhance phagocytosis and antigen presentation while increasing cytokine secretions known to activate other local immune cells (such as B-lymphocytes). As such, molecules associated with the CD154 peptide are preferentially targeted for immune response and expanded antibody production.
Potential vectors for use in the methods include, but are not limited to, Salmonella (Salmonella enteritidis), Shigella, Escherichia (E. coli), Yersinia, Bordetella, Lactococcus, Lactobacillus, Bacillus, Streptococcus, Vibrio (Vibrio cholerae), Listeria, adenovirus, poxvirus, herpesvirus, alphavirus, and adeno-associated virus.
In addition, methods of enhancing an immune response against an Apicomplexan parasite and methods of reducing morbidity associated with subsequent infection with an Apicomplexan parasite are disclosed. Briefly, the methods comprise administering to a subject a vaccine comprising a first polynucleotide sequence encoding a TRAP polypeptide in an effective amount. The TRAP polypeptides may include SEQ ID NO:1-3 and 11. The insertion of the TRAP 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 BMC Biotechnol. 2007 September, 17: 7(1): 59, Scarless and Site-directed Mutagenesis in Salmonella enteritidis chromosome, which is incorporated herein by reference in its entirety. The vector may also be engineered to express the TRAP polypeptides in conjunction with other polypeptides capable of enhancing the immune response as discussed above, such as in SEQ ID NO:4 and SEQ ID NO:10. In particular, a polypeptide of CD154 capable of binding CD40 may be expressed by the vector to enhance the immune response of the subject to the TRAP polypeptide. Optionally, the vector is a bacterium, such as Salmonella enteritidis.
The useful dosage of the vaccine 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 sufficient to evoke an immune response. For bacterial vaccines, it is envisioned that doses ranging from 103 to 1010 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 are suitably viable prior to administration, but in some embodiments the bacteria may be killed prior to administration. In some embodiments, the bacteria may be able to replicate in the subject, while in other embodiments the bacteria 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. For chickens, the compositions may be administered in ovo.
Some embodiments of the invention provide methods of enhancing immune responses in a subject. Suitable subjects may include, but are not limited to, vertebrates, suitably mammals, suitably a human, and birds, suitably poultry such as chickens. 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. Specifically, enhancing an immune response may include, but is not limited to, enhanced production of antibodies, enhanced class switching of antibody heavy chains, maturation of antigen presenting cells, stimulation of helper T cells, stimulation of cytolytic T cells or induction of T and B cell memory.
It is envisioned that several epitopes or antigens from the same or different pathogens may be administered in combination in a single vaccine to generate an enhanced immune response against multiple antigens. Recombinant vaccines may encode antigens from multiple pathogenic microorganisms, viruses or tumor associated antigens. Administration of vaccine capable of expressing multiple antigens has the advantage of inducing immunity against two or more diseases at the same time. For example, live attenuated bacteria, such as Salmonella enteritidis 13A, provide a suitable vector for eliciting an immune response against multiple antigens.
Bacterial vaccines may be constructed using exogenous polynucleotides encoding antigens which may be inserted into the bacterial 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 that target the exogenous polynucleotide for secretory pathways. One example of a suitable transmembrane protein for insertion of polynucleotides is the lamB gene. In the Examples, TRAP and CD 154 polynucleotides were inserted into loop 9 of the lamB sequence.
Exogenous polynucleotides include, but are not limited to, polynucleotides encoding antigens selected from pathogenic microorganisms or viruses and include polynucleotides that are expressed in such a way that an effective immune response is generated. Such polynucleotides may be derived from pathogenic viruses such as influenza (e.g., M2e, hemagglutinin, or neuraminidase), herpesviruses (e.g., the genes encoding the structural proteins of herpesviruses), retroviruses (e.g., the gp160 envelope protein), adenoviruses, paramyxoviruses, coronaviruses and the like. Exogenous polynucleotides can also be obtained from pathogenic bacteria, e.g., genes encoding bacterial proteins such as toxins, and outer membrane proteins. Further, exogenous polynucleotides from parasites, such as other Apicomplexan parasites are attractive candidates for use of a vector vaccine.
Polynucleotides encoding polypeptides involved in triggering the immune system may also be included in a vector, such as a live attenuated Salmonella vaccine. The polynucleotides may encode immune system molecules known for their stimulatory effects, such as an interleukin, Tumor Necrosis Factor, an interferon, or another polynucleotide involved in immune-regulation. The vaccine may also include polynucleotides encoding peptides known to stimulate an immune response, such as the CD 154 polypeptide described herein.
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 plasmids were first maintained in TOP 10 E. coli cells (Invitrogen, Carlsbad, Calif., USA) unless described otherwise. Salmonella enteritidis 13A was used for introduction of mutations. Salmonella enteritidis strain 13A was a field isolate available from USDA/APHIS/NVSL and deposited with the ATCC as deposit number PTA-7871. Bacteria carrying plasmid pKD46 were grown at 30° C. Other bacteria were grown at 37° C. Plasmid curing was conducted at 37° C.
Luria-Bertani (LB) media was used for routine growth of cells, and SOC media (Invitrogen, Carlsbad, Calif., USA) was used for phenotypic expression after electroporation. When appropriate, the following antibiotics were added to the media: ampicillin (Amp) at 100 μg/ml, kanamycin (Km) at 50 μg/ml, and chloramphenicol (Cm) at 25 μg/ml.
Plasmids pKD46, pKD13, and pBC-1-SceI were described previously (Datsenko and Wanner, PNAS 2000, 97:6640-6645 and Kang et al., J Bacteriol 2004, 186:4921-4930, both of which are incorporated herein by reference in their entireties). Plasmid pKD46 encodes Red recombinase enzymes which mediate homologous recombination of incoming linear DNA with chromosomal DNA. This plasmid also contains the Ampicillin resistance gene and is temperature-sensitive so that it requires 30° C. for maintenance in the cell. Plasmid pKD13 served as a template for amplification of the Km resistance (Kmr) gene used in overlapping PCR. Plasmid pBC-1-SceI, which is maintained in the cell at 37° C., produces the I-SceI enzyme, which cleaves the following 18 base pair, rare recognition sequence: 5′-TAGGGATAACAGGGTAAT-3′ (SEQ ID NO:16). Plasmid pBC-1-SceI also contains the chloramphenicol resistance (Cmr) gene.
All primers used for PCR are listed in Table 1. Typically, PCR was performed using approximately 0.1 μg of purified genomic, plasmid or PCR-generated DNA (Qiagen, Valencia, Calif., USA), 1× cloned Pfu polymerase buffer, 5U Pfu polymerase (Stratagene La Jolla, Calif., USA), 1 mM dNTPs (GE Healthcare Bio-Sciences Corp., Piscataway, N.J.), and 1.2 μM of each primer in a total volume of 50 μL. The DNA engine thermal cycler (Bio-Rad, Hercules, Calif., USA) was used with the following amplification conditions: 94° C. for 2 minutes; 30 cycles of 94° C. sec for 30 sec, 58° C. for 60 sec, 72° C. for 90 sec per 1 kb; and 72° C. for 10 minutes for final extension. Each PCR product was gel purified (Qiagen, Valencia, Calif., USA) and either eluted in 25 μL EB buffer for preparation of templates used in overlapping extension PCR or in 50 μL EB buffer, ethanol precipitated and suspended in 5 μL of ddH2O for electroporation into S. enteritidis.
AGCGAATTTCCGGGGATCCGTCGA 3′ (SEQ ID NO: 21)
TCTTTGATATAGCC 3′ (SEQ ID NO: 27)
In Table 1, italicized nucleotides are complementary to either side of the lamB gene loop 9 insertion site, which corresponds to nucleotide 1257 using S. typhimurium as an annotated reference genome. Bold font nucleotides represent the I-SceI recognition site in the Km-f primer.
Transformation of pKD46 into S. enteritidis was the first step carried out so that Red recombinase enzymes could be used for mediating recombination of subsequent mutations. Plasmid pKD46 was harvested from E. coli BW25113 (Datsenko and Wanner, PNAS 2000, 97:6640-6645) using a plasmid preparation kit (Qiagen Valencia, Calif., USA). Then 0.5 μL of pKD46 DNA was used for transformation into S. enteritidis 13A which had been prepared for electroporation. (Datsenko and Wanner, PNAS 2000, 97:6640-6645). Briefly, cells were inoculated into 10-15 mL of 2×YT broth and grown at 37° C. overnight. Then 100 μL of overnight culture was re-inoculated into 10 mL fresh 2×YT broth at 37° C. for 3-4 hours. Cells to be transformed with pKD46 plasmid were heated at 50° C. for 25 minutes to help inactivate host restriction. Cells were washed five times in ddH2O water and resuspended in 60 μL of 10% glycerol. Cells were then pulsed at 2400-2450 kV for 1-6 ms, incubated in SOC for 2-3 hours at 30° C. and plated on LB media with appropriate antibiotics. S. enteritidis transformants with pKD46 were maintained at 30° C. When these transformants were prepared for additional electroporation reactions, all steps were the same except that 15% arabinose was added to induce Red recombinase enzymes one hour prior to washing, and cells did not undergo the 50° C. heat step.
Loop 9 up-I-SceI/Kmr-Loop 9 Down Construct
Introduction of I-SceI enzyme recognition site along with the Kmr gene into loop 9 of the lamB gene was done by combining the Red recombinase system (Datsenko and Wanner, PNAS 2000, 97:6640-6645, which is incorporated herein by reference in its entirety) and overlapping PCR (Horton et al., BioTechniques 1990, 8:528-535, which is incorporated herein by reference in its entirety). The insertion site corresponds to nucleotide 1257 of the lamB gene using Salmonella typhimurium LT2 (S. typhimurium) as an annotated reference genome. First, the upstream and downstream regions immediately flanking the loop 9 insertion site (loop 9 up and loop 9 down, respectively) were amplified separately. Primers used were lam-up-f and lam-up-r for loop 9 up and lam-dn-f and lam-dn-r for loop 9 down. Then the Kmr gene from pKD13 plasmid was amplified using primers Km-f and Km-r. Here, the I-SceI enzyme site was synthetically added to the 5′ end of Km-f primer then preceded by a region complimentary to the loop-up-r primer. Likewise, a region complimentary to the loop-dn-f primer was added to the 5′ end of Km-r primer. The complimentary regions allow all 3 PCR products to anneal when used as templates in one PCR reaction.
Loop 9 up-TRAP-CD154-Loop 9 Down Construct
The final overlapping PCR fragment, PCR-B, contained the added TRAP antigen in combination with CD 154 sequences flanked by loop 9 up and down regions (
To shorten the amount of steps for construction of the next fragment, the TRAP-CD154 sequence was synthetically added to the 5′ end of the lam-dn-f primer and preceded by the complimentary region to the loop-up-r primer. The previously used PCR product for loop 9 up could be used together with the newly constructed PCR product in which the TRAP-CD154s were incorporated at the 5′ end of loop 9 down to perform the final PCR reaction. However, for other insert sequences, an extra PCR step was needed, due to the longer lengths of insert sequences, to amplify loop 9 up with added nucleotides specific to insertion sequences connected to loop-up-r primer. The coding sequence for Gly (GGT) and Serine (TCC) as well as all other amino acids were chosen based on compiled data of the most frequently used codons in E. coli and Salmonella typhimurium proteins. See Table 1 for further details of primer design.
The first mutation step involved designing a PCR fragment, PCR-A, which would serve as the carrier of the I-SceI site/Kmr cassette to be inserted into the lamB site. PCR-A consisted of the I-SceI enzyme recognition site adjacent to the Kmr gene with approximately 200-300 bp of flanking DNA on each end homologous to the upstream and downstream regions of lamB loop 9 insertion site (loop 9 up and loop 9 down, respectively). The fragment was introduced into S. enteritidis cells expressing Red recombinase enzymes and Kmr colonies were selected. After screening a few colonies by colony PCR, positive clones were sequenced for the desired inserted I-SceI site/Kmr sequence, and the identified mutant was selected and designated as SE 164.
Genomic Replacement of I-SceI/Kmr with TRAP-CD154s
The second mutation step required constructing a PCR fragment, referred to as PCR-B and shown in
Attenuation of SE13A was achieved by deletion mutation of the aroA gene and/or the htrA gene. Mutation of the aroA gene, a key gene in the chorismic acid pathway of bacteria, results in a severe metabolic deficiency which affects seven separate biochemical pathways. Mutation of the htrA gene reduces the cell's ability to withstand exposure to low and high temperatures, low pH, and oxidative and DNA damaging agents and reduces the bacteria's virulence.
To achieve deletion mutations in SE13A, the target gene sequence in the bacterial genome of S. enteritidis was replaced with the Km resistant gene sequence. This was completed using overlapping extension PCR and electroporation of the PCR products as described above. The Km resistance gene was targeted into the genomic region containing the genes of interest (aroA or htrA) by flanking the Km resistance gene with 200-300 base pairs of sequences homologous to the genes of interest. Once Km resistant mutants were obtained, the aroA and htrA deletion mutations were confirmed by DNA sequencing. Analogous aroA- and htrA-Salmonella strains were deposited with the American Type Culture Collection on Sep. 13, 2006 (Deposit No. PTA-7872 and Deposit No. PTA-7873, respectively). The attenuated strains were previously tested in vivo with regards to clearance time. Both of the attenuated strains had quicker clearance times than did the wildtype 13A strain, but both were able to colonize the liver, spleen, and cecal tonsils of chickens after oral infection. Attenuated strains comprising the TRAP-CD154s and lacking both aroA and htrA were isolated.
Day-of-hatch chicks (n=280) were orally vaccinated with about 1×108 cfu of the Salmonella isolates comprising the three distinct polynucleotides encoding the TRAP polypeptides of SEQ ID NO:1-3 or saline control. At 21 days of age, the chicks were orally challenged with 104 sporulated oocysts of Eimeria maxima. The chicks were monitored daily post challenge. As depicted in
In a repeat experiment, mortality in the vaccinated bird (6/48) was significantly lower than the controls (17/50) and performance was better in the vaccinated chicks, but the difference was not significant.
In addition, serum was collected from immunized birds and an ELISA for TRAP performed. A robust TRAP specific antibody response was generated in the birds vaccinated with TRAP-US (SEQ ID NO:2).
To evaluate the efficacy of TRAP US-CD154 (SEQ ID NO:34) as a potential vaccine candidate, a similar study was completed to investigate morbidity associated with vaccination. Broiler chickens were orally vaccinated with 1×108 cfu/bird of the Salmonella vaccine with TRAP US and CD154 insert (SEQ ID NO:34) or sham vaccinated with saline. Coccidia challenge was performed with sporulated oocytes of Eimeria maxima (105 sporulated oocysts/bird) at three weeks post-vaccination. Body weight gain and lesions were evaluated 7 days post-challenge. Immunized birds showed a significant (p<0.01) improvement in performance. Immunized birds had about a 31% weight gain as compared to unvaccinated controls. Thus, vaccination with a Salmonella-based vaccine comprising a TRAP polypeptide and a CD154 polypeptide capable of binding CD40 may protect birds from morbidity and mortality associated with Eimeria infection.
This application claims priority to U.S. Provisional Application Ser. No. 60/984,612, filed Nov. 1, 2007, which is incorporated herein by reference in its entirety.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US08/82254 | 11/3/2008 | WO | 00 | 12/28/2010 |
Number | Date | Country | |
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60984612 | Nov 2007 | US |