Vaccination Strategies for the Prevention of Swine Dysentery.

Holden, James Anthony, jamesholden@netspace.net.au

January 2006

The SmpA outer membrane lipoprotein of B. hyodysenteriae has several characteristics that indicate the potential to protect against swine dysentery (SD). It localises to the outer membrane and antibodies directed against SmpA can prevent the growth of B. hyodysenteriae in vitro. There is some variation observed in the distribution and expression of the SmpA lipoprotein, suggesting that vaccination with SmpA may not provide protection against challenge with a heterologous B. hyodysenteriae strain. This study has characterised the variation at the smpA locus, and in the process has identified a novel gene, smpB. There is very low similarity between smpB and smpA, with the exception of an identical lipoprotein signal sequence. This suggests that SmpB may be translocated to the outer membrane of B. hyodysenteriae in a similar fashion to SmpA. The results described in this thesis indicate that strains of B. hyodysenteriae harbour either smpA or smpB, but not both, explaining the earlier results of Turner et al. (1991). The presumed outer membrane location of SmpB lead to further investigations into its potential to protect mice from infection with B. hyodysenteriae. Swine Dysentery is a inflammatory disease of the swine colon. Therefore it is believed that a mucosal immune response may provide increased protection against challenge. In this study, vaccination of mice with recombinant SmpB elicited high levels of serum antibodies, induced the production of Interleukin-4 producing T lymphocytes and decreased the observed histological effects after challenge with virulent B. hyodysenteriae. In efforts to increase the protected conferred by vaccination with SmpB, recombinant Salmonella typhimurium STM-1 vaccines were created to express SmpB or deliver DNA vaccines encoding SmpB. Vaccination with these recombinant Salmonella vectors did not induce a measurable SmpB specific immune response. Macrophage survival and plasmid stability studies indicated that this was due to instability of the expression plasmids in STM-1. Although SmpB will only ever protect against strains of B. hyodysenteriae harbouring smpB, these results indicate that with further research, SmpB (and SmpA) may contribute to protection from SD. Toxin production is an important aspect of the pathogenesis of many pathogenic bacteria. Vaccination with attenuated toxins is commonly used to prevent disease. In this study, the B. hyodysenteriae â-haemolysin HlyA was used to vaccinate mice to determine the protection induced after challenge. Vaccination of mice with recombinant HlyA induced significant levels of serum antibodies and lowered the observed pathological effects after challenge of vaccinated mice with virulent B. hyodysenteriae. In an attempt to increase the mucosal immune response and therefore the protection afforded after vaccination with HlyA, recombinant S. typhimurium STM-1 strains were created to express HlyA or deliver DNA vaccines encoding HlyA. Similar to the recombinant STM-1 vaccines expressing SmpB, a HlyA specific immune response was not observed by ELISA or ELISPOT analysis. Plasmid stability trials revealed that the inability to induce a detectable HlyA specific immune response by recombinant STM-1 vaccination may be due to ins tability of the plasmids. Outer membrane proteins are often important components of vaccines against bacterial and viral pathogens. Considering the variation observed in the smpA locus in this study resulting in the identification of smpB, further investigation into the distribution and conservation of outer membrane encoding genes in B. hyodysenteriae strains was undertaken. In particular, the blpAEFG, vspABCD and vspEFGH clusters were analysed for their distribution. It was demonstrated that genes that are B. hyodysenteriae specific (vspABCD and vspEFGH) displayed higher levels of polymorphism than those that are distributed amongst non-pathogenic species, such as B. innocens (which contains blpAEFG). This suggests that the variation in the vspABCD and vspEFGH clusters amongst B. hyodysenteriae strains may be a result of the exposure to the host immune system. Further investigation was undertaken by PFGE analysis and 2D-gel electrophoresis, to analyse genomic and proteomic variation at a global level. Although strains of B. hyodyse nteriae produced several different electrophoretic types (ET) upon PFGE analysis, only limited correlation between the PFGE ET, the polymorphisms in vspABCD and vspEFGH and the presence of smpA/smpB were observed. 2D-gel electrophoresis analysis of outer membrane preparations of two B. hyodysenteriae strain revealed several distinct differences in the outer membrane between B. hyodysenteriae strains. The observed differences in the proteins contained in the outer membrane of B. hyodysenteriae is important for vaccine design, as the induction of cross protection between strains of B. hyodysenteriae is essential for a effective vaccine.

brachyspira hydodysenteriae

smpA

smpB

HlyA

recombinant Salmonella vaccine

Exploitation of the Protein Tubulin For Controlling African Trypanosomiasis

ngiles@anhb.uwa.edu.au, Natalie Giles

January 2005

This thesis presents the results of an investigation into the structural protein, tubulin, as a potential target for anti-trypanosomatid drug discovery and vaccine development. Recombinant alpha- and beta- tubulin proteins from Trypanosoma brucei rhodesiense were expressed as soluble fusion proteins in an E. coli expression system. The recombinant alpha- and beta- tubulins were used to determine the nature of binding of novel trifluralin analogues EPL-AJ 1003, 1007, 1008, 1016 and 1017. Native tubulin from rats was used to determine the extent of binding to mammalian tubulin. The results of this study clearly demonstrate two important aspects of the binding of trifluralins to tubulin. Firstly, they have specific affinity for trypanosomal tubulin compared with mammalian regardless of the chemical composition of the trifluralin analogue tested. Secondly, they have a demonstrably stronger affinity for alpha-tubulin compared with beta-tubulin. In addition, compounds 1007, 1008, 1016 and 1017 have strong binding affinities for alpha-tubulin, with limited binding affinity for mammalian tubulin, which indicates that these compounds selectively bind to trypanosomal tubulin. The morphology of bloodstream forms of T. b. rhodesiense exposed to trifluralin analogues was studied using electron microscopy and immunofluorescence to determine the ultrastructural changes these compounds induce as a result of binding to tubulin. All compounds tested induced severe irreparable damage in T. b. rhodesiense, including perturbation of subpellicular microtubules, extensive cytoplasmic swellings, axoneme and paraflagellar rod malformation, disconfiguration around the flagellar pocket and membrane disintegration. These results suggest that the mechanism of action of these trifluralin analogues is through the disruption of polymerization of tubulin into microtubules as a result of binding to alpha-tubulin. The potential for recombinant trypanosomal tubulins to be used as vaccine candidates was assessed by monitoring parasitaemia and length of survival of mice immunised with the proteins and challenged with a lethal infection of T. b. rhodesiense. Although all the mice vaccinated with recombinant tubulin developed a patent parasitaemia and did not survive, they were partially protected because their patency period and length of survival were significantly greater than the control groups. Furthermore, plasma collected from mice immunised with recombinant trypanosomal tubulin contained antibodies that recognized tubulin in a soluble extraction from T. b. rhodesiense. The results of this thesis confirm the potential for the structural protein, tubulin, to be used as a target for anti-trypanosomatid drug discovery and vaccine development.

tubulin

trypanosomiasis

recombinant protein

drug discovery

vaccine discovery

Pseudomonas aeruginosa : development of a mucosal vaccine for respiratory infection

Thomas, Linda D., n/a

January 2001

Pseudomonas aeruginosa (P. aeruginosa) is a frequently isolated pathogen that causes septicaemia and chronic respiratory infection. It exhibits a higher mortality rate than other gram-negative bacteria and the need for effective immunotherapy is emphasised by the frequency of antibiotic resistance associated with this organism. Mucosal immunisation with a whole killed cell P. aeruginosa vaccine has previously demonstrated a significant immune response in both rodent studies and human trials. This study is a continuation of that research, with the major goal being the identification of a purified protein antigen that could form the basis of a mucosal vaccine against P. aeruginosa. Specifically, the aims of this study were the development of purification protocols for the isolation of previously untested protein antigens, assessment of the efficacy of these antigens to enhance bacterial clearance in an animal model of acute respiratory infection, determination of the immune parameters that are associated with the resolution of P. aeruginosa respiratory infection and finally, cloning of an identified antigen which demonstrated vaccine efficacy. Protocols were established to isolate proteins for use as antigens in immune response studies. The proteins purified in this study were Pa 13, Azurin, acyl carrier protein (ACP), Amidase, Aminopeptidase, KatA and Pa70. These proteins were used to immunise rats by intestinal intra-Peyer's patch (IPP) inoculation and intratracheal (IT) boost. The immunisation protocol employed was designed to target mucosal antigen-specific immune responses where the route of immunisation, Peyer's patch (PP) intestinal inoculation, is akin to the oral delivery of antigens to the gut-associated lymphoid tissue (96). Investigations of a previously uncharacterised antigen, Pa60, later identified this protein as the P. aeruginosa catalase, KatA. This study demonstrated enhanced bacterial clearance of both homologous and heterologous challenge following immunisation with KatA. The level of clearance demonstrated by KatA was promising when compared to that of killed whole cell immunisation. KatA was cloned and studies with the recombinant protein showed enhanced bacterial clearance commensurate with that of the native protein. Immunisations with other proteins identified four additional antigens which enhanced bacterial clearance; Pa13, Pa40, Pa45 and Pa70. Amino acid sequence analysis indicated that Pa13 may be a novel protein, whereas Pa40 was determined to be amidase and Pa45, aminopeptidase. Pa70 was not successfully sequenced. These proteins were effective in significantly enhancing bacterial clearance of homologous P. aeruginosa challenge. For KatA, Pa13 and Pa70, clearance was associated with a marked phagocytic cell recruitment. In contrast, amidase and aminopeptidase demonstrated clearance with a minimal cellular response. Proteins; azurin and ACP were non-protective, failing to clear a live P aeruginosa challenge. Analysis of the antigen-specific responses of these nonprotective proteins and comparison with those antigens which enhanced bacterial clearance were used to determine factors that may contribute to the resolution of an acute pulmonary infection. The study has demonstrated that mucosal immunisation using purified protein antigens can enhance the clearance of pulmonary infection with P. aeruginosa. It has also contributed to the understanding of immune responses to newfound antigens of P. aeruginosa and identified antigen-specific responses which confirm their potential as vaccine candidates.

pseudomonas aeruginosa

mucosal vaccine

chronic respiratory infection

immunotherapy

Immunomodulation in the context of developing a nontypeable Haemophilus influenzae vaccine

McGrath, John Francis, n/a

January 2007

One of the major challenges of vaccine development is the conservation of immunogenicity and protective efficacy through the stages of design, production, formulation and delivery. The critical issue is that how and in what form an antigen is taken up by antigen presenting cells for proteolytic processing and presentation to the immune system bound to MHC can have dramatic effects on the activation of Th cells to drive clonal responses and induction of immunological memory. Nontypeable Haemophilus influenzae (NTHi) is a pathogenic commensal of the human respiratory tract that causes diseases with enormous socioeoconomic burdens. There is no licensed vaccine, although the potential for vaccination with outer membrane components to reduce the incidence of disease caused by NTHi has recently been demonstrated in clinical trials. The issue of immunomodulation was explored in this thesis in the context of the further evaluation of a leading NTHi vaccine candidate, the outer membrane protein OMP26. The efficacy of recombinant OMP26 (rOMP26) against NTHi challenge has been previously demonstrated in mice, rats and chinchillas. In rats, efficacy was shown to be restricted to the precursor form (containing the signal peptide) and not the mature form of rOMP26. The immunodulatory effects of changes to the rOMP26 structure were further investigated in this thesis. A range of structural variants of rOMP26 were constructed in view of reducing extraneous plasmid-derived sequence from the antigen and to introduce a unique cysteine residue as a potential conjugate site for multivalent vaccine development (Chapter 2). It was demonstrated that minor structural changes to rOMP26 such as the addition, deletion, modification or relative positioning of a single amino acid or bulky group, designed to increase the efficiency of production or introduce (cysteine) conjugation sites, altered the expression of the protein in E. coli and the immunogenicity in Balb/C mice. Furthermore, in contradiction to the published report (El-Adhami et al. 1999) and a new study in rats (Chapter 3), there was no positive effect of the signal peptide in mice, with precursor and mature forms of rOMP26 equally immunogenic (Chapter 2). Following confirmation of the need to retain the signal peptide for the immunogenicity of rOMP26 in rats, a precursor form (rOMP26VTAL) in which the conserved n-region of the signal peptide was deleted, and shown to reduce the efficiency of the cleavage of the signal peptide by signal peptidase during protein overexpression in E. coli (Chapter 3). Not only did this deletion result in an increase the yield and stability of the purified precursor protein, but rOMP26VTAL was highly immunogenic and enhanced the clearance of NTHi from the lungs of challenged rats. The potential for signal peptides to be exploited as an immune-enhancing moiety in a proteinaceous vaccine is discussed. Following the development of rOMP26VTAL as a production optimised variant of rOMP26, the next step was to test the feasibility of rOMP26VTAL as a component of a multivalent vaccine (Chapter 4). Two chimeras were constructed with LB1(f)2,1,3, a trivalent synthetic B-cell epitope from the extracellular loop 3 region of the P5 fimbrin protein of NTHi, positioned at the N- or C-terminus of rOMP26VTAL. The solubility of rOMP26VTAL was affected by the fusion, with both chimera constructs expressed only in the insoluble fraction, thus requiring a denaturing protocol for purification. Although rLB1(f)2,1,3-OMP26VTAL was expressed and purified as a more stable protein and in greater yield than rOMP26VTAL-LB1(f)2,1,3, the relative positioning of the fusion was important and rOMP26VTAL-LB1(f)2,1,3 was significantly more immunogenic in rats than rLB1(f)2,1,3-OMP26VTAL. In addition, rOMP26VTALLB1( f)2,1,3, but not rLB1(f)2,1,3-OMP26VTAL induced a significant degree of bacterial clearance following pulmonary challenge with NTHi, in levels comparable to the highly efficacious rOMP26VTAL construct. In the third part of the thesis, bacterial ghosts were evaluated as a novel mucosal delivery technology for rOMP26VTAL and rOMP26VTAL-LB1(f)2,1,3, (Chapter 5). To mimic the natural presentation of OMP26 and P5 fimbrin antigens on the cell surface of NTHi, an OmpA� sandwich fusion surface display system was developed for the outer membrane expression of the OMP26 constructs in E. coli ghosts. Following gut immunisation, but not intranasal immunisation even when co-administered with the cholera toxin�derived adjuvant CTA1-DD, bacterial ghosts were successful at presenting OMP26VTAL and rOMP26VTAL-LB1(f)2,1,3 to the immune system for the induction of enhanced clearance of NTHi in the rat pulmonary challenge model. Although this study was the first to demonstrate enhanced bacterial clearance induced by heterologous antigens expressed in the outer membrane of bacterial ghosts, future studies with ghosts will require optimisation of the expression levels of the OmpA� fusion proteins possibly to avoid cross-reactive responses related to high doses of ghosts in the inoculum. This thesis presents data that both supports the further evaluation of rOMP26 constructs for clinical trials, and has demonstrated the significant effects of structural changes, method of production and delivery system can have on the immunogenicity of a candidate vaccine. Such knowledge will contribute to and provide some new approaches for enhancing the efficiency of vaccine development against a range of diseases including those caused by NTHi. Major Outcomes: 1. Demonstration that the immunogenicity of rOMP26 antigen constructs is affected by structural modifications and their positioning within the construct, and by the delivery system. 2. Development of rOMP26VTAL, an rOMP26 construct with the KNIAK sequence deletion of the signal peptide n-region. This protein retains the immunogenicity and protective efficacy of rOMP26, but is produced with reduced cleavage of the signal peptide, resulting in higher yields and a stable protein. Lacks extraneous plasmidderived multiple cloning site sequence, and is produced in high yield as a stable protein. 3. Construction of a NTHi rOMP26VTAL-LB1(f)2,1,3 chimera antigen that induced enhanced clearance of NTHi in an acute pulmonary challenge model in rats. 4. Development of an OmpA� surface display system for the expression of rOMP26 antigen constructs in the outer membrane of E. coli/bacterial ghosts 5. Bacterial ghosts were successful as delivery vehicles for rOMP26 candidate vaccine constructs when delivered in the gut.

vaccine development

Nontypeable Haemophilus influenzae

NTHi

bacterial ghosts

immunisation

Expression of stage-specific Fasciola proteases and their evaluation in vaccination trials

Jayaraj, Ramamoorthi, Jayaraj@menzies.edu.au

January 2008

The liver flukes Fasciola hepatica and F. gigantica cause infectious disease in ruminants and humans. The geographical range of these two parasite species (temperate and tropical respectively) ensures that infection can occur worldwide. Although anthelmintic treatment is effective against disease, emerging drug resistant strains leads to the development of a vaccine. However, despite several decades of research, there is no commercial vaccine available. The main challenge at present is to produce recombinant proteins in an immunologically active form using recombinant DNA technology. This is an essential step in Fasciola vaccine production. Cysteine proteases are probably the most important facilitators of virulence in flukes and are produced by all stages of the fluke life-cycle. Two classes of cysteine protease are found in the excretory and secretory material of liver flukes- these are cathepsin L and cathepsin B. As such, the major aims of this thesis were to investigate the expression and purification of Fasciola recombinant cysteine proteins, and characterisation by SDS-PAGE and immunoblotting using monoclonal and polyclonal antibodies. These studies demonstrate the production of functionally active cathepsin proteins in S. cerevisiae BJ3505 cells which will lead to vaccine candidate analysis. The second aim of this thesis was to determine the protective efficacy of stage specific target antigens against experimental infection. In addressing this issue, the protective efficacy of single and multivalent recombinant protein vaccinations of adult stage F. hepatica cathepsin L5, immature F. gigantica cathepsin L1g and juvenile F. hepatica cathepsin B were analysed in Sprague Dawley rats against F. hepatica infection. This study demonstrates that juvenile fluke target antigen-cathepsin B induces better immune protection than adult fluke antigen-cathepsin L5. Cocktails of juvenile and adult stage fluke recombinant proteins (cathepsin B and L5) elicited the highest protective immunity against experimental infection and this combination showed not only reduction in fluke recovery and size of flukes, but also marked diminution in the intensity of liver lesions in vaccinated rats. In order to assess the immunogenic property of an early infective stage fluke secreting cysteine protease as a vaccine candidate, DNA vaccination vectors encoding cathepsin B were analysed in BALB/c mice. In this study, the ability of four DNA vaccination strategies such as secretory, chemokine-activating, lymph node targeting vectors encoding cathepsin B were assessed by antibody titre, antibody avidity, western blotting and ELIPSOT assay. The results have further validated the immunoprophylactic potential of a cathepsin B vaccine against F. hepatica. In this study, we have expressed and attained high yields of F. gigantica cathepsin L1g from E. coli BL21, and compared this to a yeast-expressed system. This protease was over-expressed and formed insoluble inclusion bodies that were subsequently solubilised with urea or guanidine hydrochloride. In order to purify the urea-solubilised protein, step-wise urea gradient chromatography was used. For refolding of solubilised protein, a dilution and dialysis procedure was utilised. Proteolytic activity was confirmed by gelatin SDS-PAGE analysis. In conclusion, the determination of the immune potential of recombinant stage specific antigens allows the development of effective vaccines against Fasciola infection.

Fasciola hepatica

cathepsin proteases

stage-specific vaccine candidates

DNA vaccines

Heat shock proteins as vaccine adjuvants

Qazi, Khaleda Rahman

January 2005

<p>New efficient vaccines against infectious diseases are in demand. Some important factors impeding the vaccine development are the poor immunogenicity and the MHC restriction of the immune responses to a number of antigens. The use of novel vaccine adjuvants or carrier proteins, which are known to enhance the immunogenicity of the subunit antigens and provide T-cell help, can circumvent these problems. The potential of heat shock proteins (HSPs) to function as adjuvants when fused to or co-delivered with protein antigens, make them attractive vaccine candidates. In this thesis we have evaluated the potency of heat shock protein 70 (HSP70) as a possible vaccine adjuvant and studied the mechanisms behind the adjuvanticity.</p><p>The first article aims to evaluate the carrier effect of glutathione-S-transferase (GST) on a malarial antigen EB200 that induces a MHC restricted response in mice. Immunization of CBA and C57BL/6 mice, high and low responders to EB200, respectively, with the GST-EB200 fusion protein elicited EB200 specific antibody responses in both strains of mice, which indicated that MHC restriction was broken in C57BL/6 mice. However, the antibody affinity and the magnitude of the response were lower in the C57BL/6 mice compared with that in CBA. To improve the response, the efficacy of various adjuvants like alum, HSP70 from <i>Trypanosoma cruzi</i>, and the adjuvant combination (HSP70 and cholera toxin) was evaluated. The results indicated that cholera toxin and HSP70 act synergistically and improve the immunogenicity of EB200 antigen by increasing the affinity and magnitude of the response.</p><p>HSP belongs to a family of conserved molecules and the maximum homology lies on the N-terminal region of the protein, therefore there is a risk that use of a complete molecule would give rise to autoimmunity. Thus, in our second study we first evaluated the adjuvant effect of the less conserved portion of HSP70 derived from <i>Plasmodium falciparum</i> (Pf70C). We found that the Pf70C exhibited similar adjuvant properties as the whole molecule. We further analyzed the adjuvant potential of Pf70C against EB200 formulated as a chimeric DNA vaccine construct. These constructs alone failed to generate substantial levels of EB200 specific antibodies in mice. However, the DNA immunization efficiently primed the immune system. This was evident as the subsequent boosting with the corresponding recombinant fusion proteins Pf70C-EB200 elicited strong EB200 specific Th-1 antibody responses. In contrast, no such priming effect was observed for <i>ex vivo</i> IFN-γ production, however stimulation with the Pf70C-EB200 fusion protein induced an enhanced secretion of IFN-γ <i>in vitro</i>.</p><p>During the infection process, the synthesis of bacterial HSP is up-regulated, which is known to sensitize T cells in the infected host. Since a high degree of homology exists within the phylogenetic families of HSPs, we postulated that exposure of mice to microorganisms could prime the immune system for evolutionary diverse HSPs and for any antigen coupled to them. We tested this hypothesis by priming mice with different microorganisms such as BCG, <i>Mycobacterium vaccae</i> or <i>Chlamydia pneumoniae</i> and boosted with a recombinant fusion protein Pf70C-EB200 or with a panel of HSPs. We found that BCG and <i>M. vaccae</i> but not <i>C. pneumoniae</i> could provide priming of the immune system to induce secondary IgG responses to Pf70C as well as to other HSPs tested. The priming effect was also observed when the EB200 antigen was coupled to Pf70C. Analysis of the IgG1 and IgG2a profiles and IFN-g production induced against the HSPs revealed a mixture of Th1/Th2 type of responses. We also observed that HSP70 specific sera cross-reacted some extent with certain autoreactive antigens. However, no deposits were observed in the kidneys of HSP treated animals.</p><p>Finally, we investigated the role of TLR2 and TLR4 on HSP70-mediated adjuvanticity. We found that HSPs displayed different degrees of adjuvanticity regarding both the strength and the profile of the induced immune response. Also, they possessed different requirements for signaling through TLRs. While HSP70 from <i>T. cruzi</i> induced antigen-specific humoral responses in wild type as well as in both the TLR2 and TLR4 knockout mice, the response was diminished in the TLR4 knockout mice when both the whole and C-terminal fragment of HSP70 from <i>Mycobacterium tuberculosis</i> was used. However, the C-terminal fragment of <i>P. falciparum</i> HSP70 elicited responses only in wild type mice but not in TLR2 or TLR4 knockout mice indicating that the adjuvant function differ for phylogenetically related HSPs. Taken together our data suggest that HSPs can be promising candidates in future vaccines.</p>

Heat shock protein

vaccine

adjuvant

BCG

Immunology

Immunologi

Lipid based nanocarriers for chemotherapeutic drug docetaxel and vaccine delivery

Yanasarn, Nijaporn

04 August 2011

Nanoscale drug delivery systems have a great impact in current medical field. These carriers have the potential to improve the efficacy and reduce the toxicity of various medicinal products. A broad variety of different lipid based carriers had been developed and used as delivery systems in the past decades. This dissertation focused on the development of solid lipid nanoparticles (SLN) as delivery systems for a chemotherapeutic agent, docetaxel, and the use of liposomes as a carrier for recombinant protein vaccines. Docetaxel is a potent anticancer drug. However, there continues to be a need for alternative docetaxel delivery systems to improve its efficacy. Docetaxel nanoparticles comprised of lecithin as the main component were engineered using two methods, the emulsion precursor method and the solvent emulsification/evaporation method. Docetaxel in nanoparticles were more effective in killing tumor cells in culture than docetaxel solution. The intravenously injected docetaxel-nanoparticles increased the accumulation of docetaxel in tumors in mice. When administered by intravenous injection or oral routes, docetaxel-nanoparticles showed antitumor activity in tumor-bearing mice. The lecithin-based nanoparticles have the potential to be a novel biocompatible and efficacious delivery system for docetaxel. Liposomes, a well-known lipid based carrier, have been investigated extensively as a vaccine delivery system. The adjuvant activities of liposomes with different net surface charges (neutral, positive, or negative) were evaluated when simply admixed with protein antigens. Immunization study in mice after subcutaneously injection of different net charged liposomes showed different antibody responses, depending on the protein antigens. Antigens (OVA, PA) admixed with the negatively charged liposomes prepared with phospholipid, DOPA, induced a strong and functional antibody response comparable to the positively charged liposomes prepared with DOTAP lipid. The negatively charged DOPA liposomes admixed with OVA also induced OVA-specific CD8��� cytotoxic T lymphocyte responses and significantly delayed the growth of OVA-expressing B16-OVA melanoma in a mouse model. The adjuvant activity of the negatively charged liposomes may be related to the liposome's ability (i) to upregulate the expression of molecules related to the activation and maturation of antigen-presenting cells and (ii) to slightly facilitate the uptake of the antigens by antigen-presenting cells. Simply admixing certain negatively charged liposomes with certain protein antigens of interest may represent a novel platform for vaccine development. / Graduation date: 2012 / Access restricted to the OSU Community at author's request from Sept. 6, 2011 - Sept. 6, 2012

Lipid based nanocarriers

Liposomes

Solid lipid nanoparticles

Vaccine Adjuvant

Immunization of melanoma patients with tumor antigens recognized by T lymphocytes, using peptides and a recombinant protein encoded by MAGE-A3

Marchand, Marie

23 October 2006

Although melanoma accounts for only 4% of skin cancers, it is responsible for 80% of deaths from skin cancers and its incidence in Caucasians has been increasing steadily during the last 30 years. So far, no treatment - except surgery at the earliest stages of the disease - has been shown to significantly improve survival. New treatments are thus clearly needed. The interest of immunologists for melanoma is based on particular features of this tumor. Rare spontaneous regressions have been described, which are possibly mediated by immune responses. Moreover, melanoma cell lines are relatively easy to obtain, providing essential tools for laboratory studies. The first melanoma vaccines involved inoculations of patients with autologous or allogeneic melanoma cells, as well as a variety of immunological adjuvants. Since the beginning of the nineties, the identification of antigens recognized on human tumors by autologous T lymphocytes has opened the way for new vaccination strategies involving molecularly defined tumor antigens. An important group of antigens recognized by T lymphocytes is encoded by “cancer-germ line genes”, which are expressed in tumors of various histological types, but are silent in normal tissues, with the exception of testis germinal cells and placental trophoblast. Since the latter do not express the HLA molecules required to present these antigens to the T lymphocytes, cancer-germ line genes encoded antigens are only present on tumors, which should limit the risk of generating autoimmune diseases as a consequence of vaccination. Therefore, these widely shared tumor specific antigens should represent good targets for the development of cancer vaccines. Our clinical research program of therapeutic vaccinations focuses on antigens encoded by the MAGE family of cancer-germ line genes. Most of the patients included in our phase I/II immunization trials had measurable metastatic melanoma. Several MAGE peptides as well as a recombinant MAGE-3 protein have been tested, while several additional trials are ongoing, including immunizations with a recombinant poxvirus coding for 2 MAGE epitopes. No major toxicity was reported. Tumor regressions have been observed in a minority of patients, mainly those who had regional or distant metastases without visceral involvement. Some of these regressions have been complete and long lasting. Although the rate of objective tumor response observed is low, it is clearly higher than the rate of spontaneous tumor regression observed in melanoma. Other immunization modes against T-cell defined epitopes are currently being explored by several groups in human clinical trials. Vaccines include peptides presented by class I or class II HLA molecules, proteins given alone or mixed with immunological adjuvants or cytokines, recombinant viral or bacterial vectors, dendritic cells and DNA encoding the antigen. Adoptive transfer of T lymphocytes selected for their capacity to recognize defined epitopes presented by the tumor represents another type of approach aiming at the destruction of the tumor by the immune system. It is difficult to predict whether and when therapeutic vaccination against cancer will reach an efficacy that will be sufficient for a standard cancer treatment. Provided their low toxicity, these vaccines should be tested in an adjuvant setting, at earlier stages of the disease.

Cancer

Peptide

Cutaneous melanoma

MAGE-3

Vaccine

T lymphocyte

Protein

The efficacy of combined infectious bronchitis/Newcastle disease vaccines

Licata, Matthew J.

January 2007

Thesis (M.S.)--University of Delaware, 2007. / Principal faculty advisor: Jack Gelb, Dept. of Animal & Food Sciences. Includes bibliographical references.

Extensive investigation of reticuloendotheliosis virus in the endangered Attwater's prairie chicken

Bohls, Ryan Lanier

17 September 2007

Reticuloendotheliosis virus (REV) is a retrovirus that causes a neoplastic disease in a wide range of avian hosts including chickens, turkeys, and ducks. In 1993, REV was detected in the endangered Attwater's prairie chicken (Tympanachus cupido attwateri), a subspecies of Tympanachus cupido. Subsequent infections of this prairie chicken have been identified at captive breeding facilities throughout Texas. The implications of these infections have severely hindered repopulation efforts by these facilities. This study focused on investigating REV infection of captive Attwater'€™s prairie chicken in order to better understand the disease affecting these endangered birds. The overall objective was to develop a means of eliminating this threat to the repopulation of the Attwater's prairie chicken. Several aspects of virus infection were investigated. Reagents capable of recognizing prairie chicken IgY and viral gag polypeptides were developed for use in assays for detection of antibody responses and titration of viral concentrations. Sequencing data of genomes collected from isolates of Texas prairie chickens and domestic chickens, as well as three REV prototype viruses, were compared to determine relationships among strains and identify the potential origin of the REV infecting Attwater'€™s prairie chicken. Additionally, a flow cytometry technique of segregating the lymphocyte population from peripheral blood mononuclear cells (PBMC) using a pan leukocyte monoclonal antibody was developed to more accurately measure changes within lymphocyte populations. This technique combined with intracellular labeling was used to deduce the target cells of REV infection. A nested polymerase chain reaction (PCR) test was developed for greater sensitivity in detecting infection in birds than the previous method of single amplification PCR. This greater sensitivity results in earlier identification of the virus in infected birds, which allows for earlier removal of infected birds to minimize transmission of the virus throughout the flock. The sensitivity of the nested PCR diagnostic test was determined in a dose response pathogenesis study, which was conducted on hybrid greater/Attwater's prairie chicken to observe the experimental development of disease in these birds. Finally, a vaccine was developed using plasmid DNA with REV encoded genes and tested on naturally infected prairie chickens to determine its efficacy in reducing viral load. Although no reduction in viral load was detected, the vaccine may be effective in providing prophylactic protection in future studies.

phylogenetic analysis

pathogenesis

vaccine

reticuloendotheliosis virus

Attwater's prairie chicken