Lipopolysaccharide, lipid A, and liposomes containing lipid A as immunologic adjuvants

Numerous studies have demonstrated that most or all of the potent adjuvant activity of Gram-negative bacterial endotoxin resides in the lipid A moiety of lipopolysaccharide (LPS). Synthetic analogues of lipid A have provided insights into structure-activity relationships. Several cellular mechanisms of LPS and lipid A adjuvant activities have been identified. Activation of macrophages by LPS or lipid A results in cytokine secretions that enhance the immune response. LPS and lipid A cause recruitment of antigen-presenting cells, particularly macrophages. Liposomes containing lipid A serve as an in vivo adjuvant to recruit increased numbers of macrophages. Liposomal lipid A that has been phagocytized by cultured macrophages also serves as an "intracellular adjuvant" to cause increased immunologic presentation of liposomal antigen by the macrophages to specific T lymphocytes. Lipid A can abolish suppressor T cell activity, resulting in increased immune responses to polysaccharide antigens. Upon combination of lipid A or lipid A analogues with nonionic block polymers, modulation of murine antibody isotypes can be achieved with antibodies against a variety of antigens in vivo. Liposomes containing monophosphoryl lipid A (MPL) have been utilized in a phase I clinical trial of a proposed malaria vaccine in humans. The liposomal malaria vaccine resulted in very high levels of antibodies against the malarial antigen, and despite the presence of huge amounts of MPL (up to 2.2 mg), the liposomal lipid A was nonpyrogenic and safe for use in humans. Lipid A and lipid A analogues, and liposomes or other carriers containing lipid A, have shown considerable promise both as adjuvants for immunization of animals and for human vaccines.     

A Wnt signaling pathway controls hox gene expression and neuroblast migration in C. elegans

Immunization regimens that induce a broadly reactive cytolytic T lymphocyte (CTL) response specific for lentiviral antigens have emerged as the leading candidates in efficacy trials conducted in both animal modelshumans. To date, lentivirus vaccination strategies have overlooked one such immunization strategy, namely the use of particulate antigens. To evaluate the efficacy of targeting antigen into the phagocytic pathway to elicit a cell-mediated immune response to lentiviral antigens, we initiated the first study of a particulate-based vaccination protocol using a large animal model system. Gradient-purified equine infectious anemia virus (EIAV) was covalently coupled to glutaraldehyde-activated iron oxide beads. In vitro studies demonstrated the effectiveness of the inactivated whole virus particulate to prime antigen presenting cells for the activationexpansion of virus-specific CD8(+) CTL. The in vivo effectiveness of the particulate antigen was evaluated by experimental immunization of ponies. Ponies receiving the viral particulate vaccinechallenged with infectious EIAV had a delayed progression to diseasea reduced viral load compared with infected ponies that had not been vaccinated. Interestingly, in vitro virus-specific CTL activity was detected in only one of four immunized animals at the day of challenge. The beneficial effects of the particulate vaccine regimen were not clearly associated with any in vitro measurable parameters of the virus-specific cellular or humoral immune responses elicited by the vaccine at the day of challenge. However, within 3 weeks after virus challenge, anamnestic humoral responses characterized by a rapid emergence of neutralizing activity in the seruma predominance of conformationally dependent epitopes recognized by virus-specific antibodies were observed in the vaccinates. Taken together, further studies are clearly warranted in large animal model systems using a particulate-based vaccine regimen considering the beneficial effects of this regimen in our studythe protective effects of particulate antigen delivery in the murine model.     

The role of macrophages in the induction and regulation of immunity elicited by exogenous antigens

Different delivery vehicles may target to different antigen presenting cells (APC) because of their composition, size and/or physical properties. In this study, we examined the priming of cytotoxic T lymphocyte (CTL) responses to a soluble exogenous protein in vivo, using various delivery vehicles. In addition, we determined the role of macrophages as APC in vivo for each of these delivery vehicles by comparing the induction of antigen-specific CTL and serum antibodies in normal and macrophage-depleted mice. Influenza A virus-derived virosomes, liposomes and monophosphoryl lipid A/squalene (MPLSQ) efficiently induced antigen-specific CTL as well as antibody responses, of which virosomes proved to be the most efficient inducers. In mice that were immunized with cell-associated antigen, strong CTL responses but no antigen-specific antibodies were detectable, while aluminium hydroxide and aluminium phosphate elicited antigen-specific antibodies but no CTL responses. Elimination of macrophages in vivo before immunization abrogated CTL responses induced with liposomes and MPL/SQ, but did not affect induction of antigen-specific CTL with virosomes or cell-associated antigen. Importantly, serum antibody levels were not altered after macrophage depletion, regardless of the delivery vehicle used, suggesting that in the absence of macrophages, other APC may phagocytose the exogenous antigens for major histocompatibility complex (MHC) class II processing and presentation. These results suggest that soluble exogenous antigens delivered in different carrier systems may be processed differently by different APC in vivo for MHC class I- or class II-restricted presentation.     

Molecular genetic analysis of giant cell glioblastomas

Encapsulation of vaccines in biodegradable microspheres provides excellent mucosal immunogens with a high potential for immunization against bacterial infections. We tested the protective immunity elicited by intragastric vaccination with phosphorylcholine (PC) encapsulated in poly(DL-lactide-co-glycolide) (DL-PLG) microspheres against Salmonella typhimurium in a mouse model of invasive intestinal infection. We chose PC as the antigen because it was found to elicit an immune response after intestinal exposure of mice to PC-bearing S. typhimurium and because anti-PC immunity protects mice against Streptococcus pneumoniae, another PC-bearing microorganism. Mice were primed intragastrically on days 1, 2, and 3 and boosted on days 28, 29, and 30 with PC (280 microg) coupled to porcine thyroglobulin (PC-thyr) encapsulated in DL-PLG microspheres, free PC-thyr, or blank microspheres. A significant rise in anti-PC immunoglobulin A (IgA) titers, as measured by an enzyme-linked immunosorbent assay, was observed in the intestinal secretions after immunization with PC-loaded microspheres, compared to the titers of mice immunized with free PC-thyr or blank microspheres. This antibody response peaked 14 days after the last boost and correlated with a highly significant resistance to oral challenge by S. typhimurium C5 (P < 10(-3)). Control mice were primed intraperitoneally on day 1 with 15 microg of PC in complete Freund's adjuvant and boosted on days 10, 14, and 20 with the same dose without adjuvant but via the same route. In these mice, the levels of anti-PC IgA in intestinal secretions were equivalent to those of the mice intragastrically immunized with PC-loaded microspheres, but protection was significantly weaker, suggesting that either the IgAs were not functional or that other immune mechanisms are important in protection. Taken together, our results highlight the potential of antigen encapsulation in DL-PLG microspheres for eliciting protective immunity against invasive intestinal bacterial diseases and suggest that a similar strategy could be used against diseases caused by other PC-bearing microorganisms.     

Influence of cellular location of expressed antigen on the efficacy of DNA vaccination: cytotoxic T lymphocyte and antibody responses are suboptimal when antigen is cytoplasmic after intramuscular DNA immunization

We examined the role of the cellular localization of antigen on the immune response after DNA immunization of mice with three forms of ovalbumin (OVA). DNA encoding OVA which was secreted (sOVA) generated 10- to 100-fold higher IgG responses with 50-and 100-fold higher levels of IgG1 than the cytoplasmic (cOVA) or membrane bound (mOVA) forms. An IgG2a predominance was seen only in cOVA and mOVA immunized mice. Although the antibody response was CD4+ T cell dependent, the differences in the antibody response could not be compensated for by provision of excess CD4+ T cell help in TCR transgenic mice. Together with our hapten-carrier studies, this would indicate that membrane or intracellular localization limits the availability of antigen for B cell priming which affects the magnitude and form of the antibody response. Surprisingly, stronger cytotoxic T lymphocyte (CTL) responses were generated for sOVA or mOVA than for cOVA via intramuscular (i.m.) injection. Since a cytoplasmic antigen should have best access to the canonical class I pathway for antigen presentation, our results indicate that priming of CTL responses after i.m. DNA immunization is probably by cross-presentation of antigen by non-transfected professional antigen-presenting cells. In contrast, intradermal immunization with cOVA produced optimal CTL responses but, as with mOVA, suboptimal antibody responses. This, together with our ex vivo RT-PCR analysis showing similar mRNA levels from all three constructs 7 days post-immunization, argues against the differential CTL response for i.m. injection to be due to dose.     

Effectiveness of liposomes possessing surface-linked recombinant B subunit of cholera toxin as an oral antigen delivery system

Liposomes appear to be a promising oral antigen delivery system for the development of vaccines against infectious diseases, although their uptake efficiency by Peyer's patches in the gut and the subsequent induction of mucosal immunoglobulin A (IgA) responses remain a major concern. Aiming at targeted delivery of liposomal immunogens, we have previously reported the conjugation via a thioether bond of the GM1 ganglioside-binding subunit of cholera toxin (CTB) to the liposomal outer surface. In the present study, we have investigated the effectiveness of liposomes containing the saliva-binding region (SBR) of Streptococcus mutans AgI/II adhesin and possessing surface-linked recombinant CTB (rCTB) in generating mucosal (salivary, vaginal, and intestinal) IgA as well as serum IgG responses to the parent molecule, AgI/II. Responses in mice given a single oral dose of the rCTB-conjugated liposomes were compared to those in mice given one of the following unconjugated liposome preparations: (i) empty liposomes, (ii) liposomes containing SBR, (iii) liposomes containing SBR and coadministered with rCTB, and (iv) liposomes containing SBR plus rCTB. Three weeks after the primary immunization, significantly higher levels of mucosal IgA and serum IgG antibodies to AgI/II were observed in the rCTB-conjugated group than in mice given the unconjugated liposome preparations, although the latter mice received a booster dose at week 9. The antibody responses in mice immunized with rCTB-conjugated liposomes persisted at high levels for at least 6 months, at which time (week 26) a recall immunization significantly augmented the responses. In general, mice given unconjugated liposome preparations required one or two booster immunizations to develop a substantial anti-AgI/II antibody response, which was more prominent in the group given coencapsulated SBR and rCTB. These data indicate that conjugation of rCTB to liposomes greatly enhances their effectiveness as an antigen delivery system. This oral immunization strategy should be applicable for the development of vaccines against oral, intestinal, or sexually transmitted diseases.     

Long-term efficacy and immune responses following immunization with the RTS,S malaria vaccine

The malaria sporozoite vaccine candidate RTS,S, formulated with an oil-in-water emulsion plus the immunostimulants monophosphoryl lipid A and the saponin derivative QS21 (vaccine 3), recently showed superior efficacy over two other experimental formulations. Immunized volunteers were followed to determine the duration of protective immune responses. Antibody levels decreased to between one-third and one-half of peak values 6 months after the last dose of vaccine. T cell proliferation and interferon-gamma production in vitro were observed in response to RTS,S or hepatitis B surface antigen. Seven previously protected volunteers received sporozoite challenge, and 2 remained protected (1/1 for vaccine 1, 0/1 for vaccine 2, and 1/5 for vaccine 3). The prepatent period was 10.8 days for the control group and 13.2 days for the vaccinees (P < .01). Immune responses did not correlate with protection. Further optimization in vaccine composition and/or immunization schedule will be required to induce longer-lasting protective immunity.     

CTL responses induced by a single immunization with peptide encapsulated in biodegradable microparticles

A synthetic peptide representing a measles virus (MV) cytotoxic T cell epitope (CTL) when encapsulated in poly (D,L-lactide co-glycolide) (PLG) 50:50 microparticles induced a strong CTL response after a single intraperitoneal immunization of mice which was greater than that following administration of the peptide in Freund's complete adjuvant. A 100 micrograms dose of encapsulated peptide was shown to be more effective for CTL priming than 50 and 25 micrograms doses. A vaccine formulation prepared by simply mixing empty 50:50 PLG microparticles with the peptide resulted in the induction of CTL responses comparable to those induced by the encapsulated peptide. Moreover, a CTL response against MV-infected target cells was observed. These findings highlight the potential immunostimulatory effect of PLG microparticles for the induction of MV and peptide-specific CTL responses.     

Long-term evaluation of tamsulosin in benign prostatic hyperplasia: placebo-controlled, double-blind extension of phase III trial. Tamsulosin Investigator Group

The blood residence half-life and organ distribution of recombinant human tumor necrosis factor-alpha (TNF-alpha) encapsulated in sterically stabilized liposomes, were investigated in rats bearing a soft tissue sarcoma in the hind leg. We studied the decay in blood concentration of "empty" liposomes using the aqueous marker 67gallium-desferal, as well as the blood concentration of soluble TNF-alpha and liposome encapsulated TNF-alpha using l25I. Encapsulation efficacy of TNF-alpha was 24%. The pharmacokinetics of TNF-alpha were markedly altered after encapsulation in liposomes, with a 33-fold increase in mean residence time of TNF-alpha in the blood, and a concomitant 14-fold increase in the area under the plasma concentration vs. time curve for liposomal TNF-alpha. Although the liposomes exhibit Stealth characteristics, uptake by mononuclear phagocyte-rich organs (e.g., liver and spleen) was noticeable, especially at later time points. Encapsulation of TNF-alpha in sterically stabilized liposomes resulted in a marked increase in localization of the cytokine in tumor measured as total uptake over time. However, peak TNF-alpha concentration levels in tumor were not significantly enhanced compared with free TNF-alpha. Besides the augmented localization of TNF-alpha after encapsulation in sterically stabilized liposomes, a diminished toxicity was observed.     

Seasonality of meal patterns and hormonal correlates in red deer

A human MUC1-transfected mouse mammary adenocarcinoma cell line (GZHI) was used to develop both subcutaneous and intravenous tumor models. A vaccine formulation comprised of a 24 mer (human MUC1) synthetic peptide encapsulated with monophosphoryl lipid A adjuvant (MPLA) in multilamellar liposomes was tested for immunogenicity and anti-tumor activity. A low dose of the human MUC1 peptide (5 microg) administered in liposomes provided excellent protection of mice in both tumor challenge models. The protective antitumor activity mediated by the liposome formulation correlated with anti-MUC1-specific T-cell proliferation, gamma-interferon (IFN-gamma) production and IgG2a anti-MUC1 antibodies, suggesting a type 1 (T1) T-cell response. In contrast, lack of protection in mice immunized with negative control vaccines correlated with IgG1 anti-MUCI antibody formation, low or no anti-MUC1 IgG2a and low antigen-specific T-cell proliferation, consistent with a type 2 (T2) T-cell response to the tumor.     

The muramyl dipeptide analog GMTP-N-DPG preferentially induces cellular immunity to soluble antigens

GMTP-N-DPG (N-acetylglucosaminyl-N-acetylmuramyl-L-alanyl-D-isoglutamyl- L-alanyl-dipalmitoylpropylamide) is a lipophilic derivative of the immunologically active compound MDP and has adjuvant properties. GMTP-N-DPG was compared with other adjuvants in model vaccine systems using ovalbumin (OVA) and a synthetic peptide derived from pp89 of murine cytomegalovirus as antigens. When serum from C57/Bl mice immunized with OVA was tested for the presence of anti-OVA antibody, samples from mice immunized with OVA plus GMTP-N-DPG had ELISA optical density (O.D.) readings twice as high as those from mice immunized with antigen alone. In contrast, samples from mice immunized with the liposomal monophosphoryl lipid A (MPL) formulation exhibited ELISA O.D. readings tenfold higher than samples from mice immunized with antigen alone. Relative levels of specific antibody in serum samples from mice immunized with OVA plus the saponin adjuvant QS-21 were equal to the GMTP-N-DPG samples. When spleen cells from immunized mice were tested for their proliferative response to OVA, we found that liposomal MPL was again the optimal adjuvant, whereas the proliferative responses of cells from mice immunized with GMTP-N-DPG or QS-21 were no better than cells from mice immunized with OVA alone. In contrast to the relatively low antibody and proliferation levels, spleen cells from mice immunized with GMTP-N-DPG and OVA demonstrated the highest level of anti-OVA CTL activity. Spleen cells from mice immunized with the pp89 peptide plus GMTP-N-DPG also exhibited CTL activity. Using antibody and complement mediated cytotoxicity it was determined that the CTL were CD8+. Based on these results, we believe that GMTP-N-DPG may be an excellent candidate adjuvant in vaccines for diseases in which a strong cell-mediated response is desired.     

Oral administration of an antigenic synthetic lipopeptide (MAP-P3C) evokes salivary antibodies and systemic humoral and cellular responses

Parenteral immunization with a tetravalent multiple antigen peptide (MAP) containing a gp120 sequence coupled to a synthetic lipophilic moiety (MAP-P3C) has been previously found to produce systemic antibody and cellular responses in mice. This study demonstrates that oral administration of MAP-P3C induced IgA antibodies in mucosal secretions and protein-specific IgG in the sera of the immunized mice. Moreover, intragastric delivery of MAP-P3C generated systemic T-lymphocyte stimulation and specific cytotoxic T-lymphocyte (CTL) activity. The CTL response was eliminated by treatment with CD8-specific antibody plus complement and was MHC class I-restricted. Therefore, presentation of lipid-linked synthetic peptides to the intestinal mucosal surface is effective in initiating humoral and cellular immunity both at mucosal sites and systemically.     

Context-dependent immunogenicity of an S206G-substituted H-2Db-restricted simian virus 40 large T antigen epitope I variant

SV40 large tumor Ag (Tag) contains four H-2b-restricted (I, II/III, IV, and V) CTL epitopes. A hierarchy exists among these CTL epitopes. CTL directed against epitopes I, II/III, and IV are readily detected following immunization of H-2b mice with SV40, Tag-transformed syngeneic cells, or a vaccinia recombinant that expresses full-length Tag, while epitope V-specific CTL are not. The mechanisms that define this hierarchy remain unknown. Initial studies have shown that the locations of epitopes I and V within SV40 Tag do not determine the immunological potencies of these epitopes. Like the wild-type Tag, derivatives in which the locations of epitopes I and V were precisely reversed within Tag failed to induce epitope V-specific CTL, but did induce epitope I-specific CTL. The use of an S206G-substituted epitope I variant (GAINNYAQKL) revealed that the S206G variant sequence induced CTL when located within the native epitope I context, but failed to do so when located within the epitope V context of Tag. Mutagenesis of residues adjacent to the S206G-substituted epitope I variant revealed that the identity of the residue flanking the amino terminus of the S206G variant was critical when it resided within the epitope V location, but not within the epitope I location. These results demonstrate that effects imposed by both regional context and adjacent residues can modulate immunogenicity, but that the relative importance of such effects varies in an epitope-dependent manner.     

Liposomes as immunoadjuvants and vaccine carriers: antigen entrapment

Successful use of liposomes as immunological adjuvants in vaccines requires simple, easy to scale up technology capable of high-yield antigen entrapment. Recent work from this laboratory has led to the development of techniques that can generate liposomes of various sizes containing soluble antigens such as proteins or particulate antigens such as whole, live, or attenuated bacteria or viruses. Entrapment of proteins is carried out by the dehydration-rehydration procedure, which entails freeze-drying of a mixture of "empty" small unilamellar vesicles and free antigens. Upon rehydration, the large multilamellar vesicles that are formed incorporate up to 80% of the antigen used. When such liposomes are microfluidized in the presence of nonentrapped material, their size is reduced to about 100 nm in diameter, with much of the originally entrapped antigen still associated with the vesicles. A similar technique applied to the entrapment of particulate antigens (e.g., Bacillus subtilis spores) consists of freeze-drying giant vesicles (4-5 microns in diameter) in the presence of spores. On rehydration and sucrose gradient fractionation of the suspension, up to 27% of the spores used are associated with generated giant liposomes of similar mean size.     

Influence of immunoadjuvants and a promiscous T-cell determinant on the immunogenicity of RESA peptide antigen of P. falciparum

Synthetic peptide antigens representing the repeat sequences of malarial antigens showed poor immunogenicity and protection in clinical trials. In the present study, RESA, an asexual blood stage antigen, containing (EENVEHDA)2 and (DDEHVEEPTVA)2 sequences were chemically linked to a promiscous T-cell determinant (CS.T3) of the circumsporozoite protein of P. falciparum. The synthetic constructs either alone or coentrapped with immunoadjuvants (nor muramyl dipeptide/lauroyl tetrapeptide) were administered in liposomes to mice of varying genetic background and the immunogenicity of different formulations were compared under identical experimental conditions. The RESA peptide formulations containing the T-cell determinant and the adjuvants generated high titre and affinity antibodies in all the strains, as compared to peptide(s) alone. The booster immunization induced a strong anamnestic response in each group. Though the major IgG isotype is of IgG1 and IgG2b interestingly, formulations containing CS.T3 have a higher proportion of cytophilic IgG2b isotype. There was a significant fall in the levels of IgG2b isotype while IgG1 levels were maintained same in the third bleed (day 60, without booster immunization). The mixed peptide group preparation containing the adjuvant is found to be a better immunogen than that of respective peptides itself. The in vitro merozoite reinvasion inhibition assay showed 76-96% inhibition with the formulations containing RESA peptide(s)-CS.T3 and the adjuvant, while with peptides alone the inhibition was 50-56%. This study highlights the importance of an alternative approach for developing peptide based immunogen against malaria.     

Mucosal or targeted lymph node immunization of macaques with a particulate SIVp27 protein elicits virus-specific CTL in the genito-rectal mucosa and draining lymph nodes

The major routes of HIV transmission are through the rectal and cervico-vaginal mucosa. To prevent dissemination of HIV to the regional lymph nodes (LNs), an effective vaccine may need to stimulate CTL in the rectal or genital tract and the draining LNs. We report that mucosal immunization by the recto-oral and vagino-oral route or s.c. immunization targeting the iliac LNs with a particulate SIVp27:Ty-VLP vaccine elicits SIVgag-specific CTL in the regional LNs as well as in the spleen and PBMC. Targeted LN immunization with this vaccine elicited MHC class I-restricted CD8+ CTL responses, and the highest frequency of CTL was found in the iliac LNs. Moreover, SIVgag-specific CTL activity was detected in short term T cell lines established in mononuclear cells eluted from the rectal and cervico-vaginal mucosa. The relative frequency of CTL in short term cell lines prepared from the rectal mucosa (21/113 or 18.6%) was similar to that obtained from the cervico-vaginal mucosa (16/79 or 20.3%). Examination of the relative frequency of CTL to the T cell epitopes residing within SIVp27 showed a higher frequency in iliac LN cells to peptide aa 41-70 than in that to peptide aa 121-150, and this was significant after both recto-oral (chi-squared 6.500, p < 0.02) and vagino-oral (chi-squared = 10.391, p < 0.01) immunization. In contrast, the relative frequency of CTL in PBMC to peptide aa 41-70 (15.5%) was comparable to that elicited by peptide aa 121-150 (17.6%). This study provides novel evidence that mucosal or targeted LN immunization can generate anti-SIV CTL in the rectal and genital mucosa, in the draining LNs, and in the central lymphoid system.     

Immunogenicity of Plasmodium falciparum circumsporozoite protein multiple antigen peptide vaccine formulated with different adjuvants

Only low antibody levels were obtained from vaccinating human volunteers with single-chain peptide from the Plasmodium falciparum circumsporozoite protein (PfCSP). This resulted in modest protection against sporozoite challenge. In addition, HLA restriction limits the probability of synthesis of a vaccine effective for a diverse population. We report immunization studies with a multiple antigen peptide (MAP) system consisting of multiple copies of a B-cell epitope from the central repeat region of the PfCSP in combination with a universal T-cell epitope, the P2P30 portion of tetanus toxin. This MAP4(NANP)6P2P30 vaccine was highly immunogenic in four different strains of mice when used with various safe and nontoxic adjuvants. When this MAP vaccine was encapsulated in liposomes with lipid A and adsorbed to aluminium hydroxide and given three times at 4-week intervals, the resultant antibody prevented 100% of sporozoites from invading and developing into liver stage infection. This high degree of immunogenicity of MAP4(NANP)6P2P30 vaccine formulated in liposomes, lipid A and aluminum hydroxide provides the foundation for consideration of human trials with this formulation.     

B7-CD28 costimulation unveils the hierarchy of tumor epitopes recognized by major histocompatibility complex class I-restricted CD8+ cytolytic T lymphocytes

Immunization of mice with tumors genetically engineered to express the B7 costimulatory molecules amplifies the antitumor immune response mediated by CD8+ cytolytic T lymphocytes (CTL). In this report, we examined the effect of B7-CD28 costimulation on the hierarchy of tumor epitopes. Using a combination of affinity chromatography/reversed-phase high performance liquid chromatography and CTL cloning, we show that major histocompatibility complex (MHC) class I molecules from EL4 lymphoma cells can present at least six distinct CTL epitopes presented by MHC class I molecules. Nevertheless, mice immunized with wild-type B7-negative EL4 cells develop CTL only to one immunodominant epitope. In contrast, immunization with B7-transduced EL4 cells led to not only the amplification of the CTL response to this immunodominant epitope, but also to the recognition of five otherwise silent subdominant epitopes. The adoptive transfer of a CTL clone against such a subdominant epitope cured mice bearing EL4 lymphoma growing as an ascites tumor. The fact that CTL response can be spread to normally silent epitopes as a result of B7-CD28 costimulation suggests a novel approach to manipulate the hierarchy of CTL epitopes and offers an opportunity to explore novel targets for T cell-mediated cancer therapy.     

Comparative efficacy of experimental anthrax vaccine candidates against inhalation anthrax in rhesus macaques

The authors examined the efficacy of Bacillus anthracis protective antigen (PA) combined with adjuvants as vaccines against an aerosol challenge of virulent anthrax spores in rhesus macaques. Adjuvants tested included i) aluminum hydroxide (Alhydrogel), ii) saponin QS-21 and iii) monophosphoryl lipid A (MPL) in squalene/lecithin/Tween 80 emulsion (SLT). Animals were immunized once with either 50 micrograms of recombinant PA plus adjuvant, or with Anthrax Vaccine Adsorbed (AVA), the licensed human anthrax vaccine. The serological response to PA was measured by enzyme linked immunosorbent assay. Lymphocyte proliferation and serum neutralization of in vitro lethal toxin cytotoxicity were also assayed. In all vaccine groups, anti-PA IgM and IgG titers peaked at 2 weeks and 4-5 weeks postimmunization, respectively. Five weeks postimmunization, animals in all vaccine groups demonstrated PA-specific lymphocyte proliferation and sera that neutralized in vitro cytotoxicity. Six weeks after immunization, the animals were challenged by aerosol with approximately 93 LD50 of virulent anthrax spores. Animals were bled daily for 1 week to monitor bacteremia, and deaths were recorded. Anti-PA ELISA titers in all groups of immunized animals were substantially increased 2 weeks after challenge. One dose of each vaccine provided significant protection (> 90%) against inhalation anthrax in the rhesus macaques.