Immunotoxicity of phosphamidon following subchronic exposure in albino rats

Effect of subchronic doses of phosphamidon exposure on humoral and cell mediated immune (CMI) responses were studied in male albino rats using SRBC, ovalbumin and KLH as antigens. Humoral immune responses were assessed by estimating antibody titre against antigen and splenic plaque forming cells (PFC) assay. CMI responses were studied by using leucocyte migration inhibition (LMI), macrophage migration inhibition (MMI) and delayed type hypersensitivity (DTH) response. Results obtained in the present study revealed marked suppression of humoral and CMI responses in a dose dependent pattern. Hence, suppression of immune responses by phosphamidon even at subchronic doses is clearly an important aspect for its safety evaluation.     

Effect of plasmid DNA vaccine design and in vivo electroporation on the resulting vaccine-specific immune responses in rhesus macaques

Since human immunodeficiency virus (HIV)-specific cell-mediated immune (CMI) responses are critical in the early control and resolution of HIV infection and correlate with postchallenge outcomes in rhesus macaque challenge experiments, we sought to identify a plasmid DNA (pDNA) vaccine design capable of eliciting robust and balanced CMI responses to multiple HIV type 1 (HIV-1)-derived antigens for further development. Previously, a number of two-, three-, and four-vector pDNA vaccine designs were identified as capable of eliciting HIV-1 antigen-specific CMI responses in mice (M. A. Egan et al., Vaccine 24:4510-4523, 2006). We then sought to further characterize the relative immunogenicities of these two-, three-, and four-vector pDNA vaccine designs in nonhuman primates and to determine the extent to which in vivo electroporation (EP) could improve the resulting immune responses. The results indicated that a two-vector pDNA vaccine design elicited the most robust and balanced CMI response. In addition, vaccination in combination with in vivo EP led to a more rapid onset and enhanced vaccine-specific immune responses. In macaques immunized in combination with in vivo EP, we observed a 10- to 40-fold increase in HIV-specific enzyme-linked immunospot assay responses compared to those for macaques receiving a 5-fold higher dose of vaccine without in vivo EP. This increase in CMI responses translates to an apparent 50- to 200-fold increase in pDNA vaccine potency. Importantly, in vivo EP enhanced the immune response against the less immunogenic antigens, resulting in a more balanced immune response. In addition, in vivo EP resulted in an approximate 2.5-log(10) increase in antibody responses. The results further indicated that in vivo EP was associated with a significant reduction in pDNA persistence and did not result in an increase in pDNA associated with high-molecular-weight DNA relative to macaques receiving the pDNA without EP. Collectively, these results have important implications for the design and development of an efficacious vaccine for the prevention of HIV-1 infection.     

Dendritic cells as a conduit to improve HIV vaccines

Many potential HIV vaccine strategies are being explored in both animal model and human settings. The success of any vaccine relies on relevant antigenic determinants being presented to the immune system for the activation of broad and long-lasting immunity. Effective immunity against HIV infection will likely require both the cellular and humoral arms of the immune system, where HIV-specific killer cells eradicate infected targets and neutralizing antibody responses contribute by preventing the initial infection of host cells. As the most potent antigen presenting cell of the immune system, the dendritic cell (DC) orchestrates the activation of adaptive immune responses as well as contributing to the early innate responses to a pathogen, which may also aid in the initial control of infection. It follows therefore, that the efficiency of a vaccine antigen would be greatly enhanced if targeted to the appropriate DCs to ensure optimal presentation to and subsequently activation of the immune system. This review will discuss (i) the current status of DC biology, covering distinct DC subsets and stages of activation and how these influence the types of immune responses that are induced, (ii) how DCs can be exploited to improve the efficacy of HIV vaccine strategies currently under investigation, (iii) what has been learned from in vivo model systems using DCs, and (iv) future considerations to advance HIV vaccinology.     

Pseudovirion particle production by live poxvirus human immunodeficiency virus vaccine vector enhances humoral and cellular immune responses

Live-vector-based human immunodeficiency virus (HIV) vaccines are an integral part of a number of HIV vaccine regimens currently under evaluation. Live vectors that carry an intact gag gene are capable of eliciting HIV pseudovirion particle formation from infected host cells. The impact of pseudovirion particle formation on the immune response generated by live HIV vaccine vectors has not been established. In this study, a canarypox HIV vaccine candidate vector expressing HIV gag and env genes, vCP205, was modified by the introduction of a glycine-to-alanine coding change in the N-terminal myristylation site of gag to create Myr- vCP205. This substitution effectively eliminated particle formation without altering the level of protein production. vCP205 and Myr- vCP205 were then directly compared for the ability to induce HIV-specific immune responses in mice. The particle-competent vector vCP205 elicited higher levels of CD8+ T-cell responses, as indicated by gamma interferon enzyme-linked immunospot (ELISPOT) assay and intracellular cytokine staining. Humoral responses to Gag and Env were also markedly higher from animals immunized with the particle-competent vector. Furthermore, HIV-specific CD4+ T-cell responses were greater among animals immunized with the particle-competent vector. Using a human dendritic cell model of antigen presentation in vitro, vCP205 generated greater ELISPOT responses than Myr- vCP205. These results demonstrate that pseudovirion particle production by live-vector HIV vaccines enhances HIV-specific cellular and humoral immune responses.     

Role of liposomes in the presentation of HIV envelope glycoprotein and the immune response in mice

The role of antigen presentation in the induction of humoral as well as cell-mediated immune responses has been investigated by anchoring HIV-1 envelope glycoprotein (gp 160/120) into the phospholipidic bilayer of preformed liposomes to produce HIV-Immunosomes. HIV-Immunosomes induced high titres of HIV-specific antibodies when tested by ELISA, IFA and neutralization, whereas equal amounts of purified glycoprotein alone produced lower antibody response. Similarly, HIV-Immunosomes induced antigen-specific Interleukin-2 production and blastogenic response upon restimulation with the same antigen, in animals vaccinated with HIV-Immunosomes, whereas no secondary response was observed in animals vaccinated with equal amounts of purified gp 160/120. Taken together, these results underline the importance of antigen presentation in the establishment of an adequate immune status and show the potential of HIV-Immunosomes as vaccine against AIDS.     

Immune responses elicited by vaccinations with Candida albicans ribosomes in cyclophosphamide treated animals

This study describes humoral and cell mediated immune (CMI) responses detected in cyclophosphamide (CY) treated animals who were vaccinated with Candida albicans ribosomes and were protected against systemic candidiasis (previous study).Mice treated with CY and vaccinated with C. albicans ribosomes revealed CMI responses towards the ribosomes as measured in vivo by the foot pad swelling test and in vitro by the lymphocyte transformation assay. Both reactions were higher in CY treated and ribosome vaccinated mice than in controls (mice that were only vaccinated). Humoral immune responses were measured by the enzyme linked immunosorbent assay (ELISA). Anti ribosomal antibody titer contrary to the CMI responses was lower in CY treated animals than in non treated controls.These data point to a possible explanation of the mechanisms underlying the ribosomal vaccinations in CY treated hosts, and show the potential of such vaccinations in compromised individuals.     

Sendai virus fusion protein mediates simultaneous induction of MHC class I/II-dependent mucosal and systemic immune responses via the nasopharyngeal-associated lymphoreticular tissue immune system

Nasal administration of Ags using a novel hybrid Ag delivery vehicle composed of envelope glycoproteins of Sendai virus on the surface of liposome membranes (fusogenic liposome) efficiently delivered Ags to Ag-sampling M cells in nasopharyngeal-associated lymphoreticular tissue. Additionally, fusogenic liposomes also effectively delivered the Ags into epithelial cells and macrophages in nasopharyngeal-associated lymphoreticular tissue and nasal passages. In vitro Ag presentation assays clearly showed that fusogenic liposomes effectively presented encapsulated Ags via the MHC class II-dependent pathway of epithelial cells as well as macrophages. Fusogenic liposomes also have an adjuvant activity against mucosal epithelial cells to enhance MHC class II expression. According to these high delivery and adjuvant activities of fusogenic liposomes, nasal immunization with OVA-encapsulated fusogenic liposomes induced high levels of OVA-specific CD4(+) Th1 and Th2 cell responses. Furthermore, Ag-specific CTL responses and Ab productions were also elicited at both mucosal and systemic sites by nasal immunization with Ag-encapsulated fusogenic liposomes. These results indicate that fusogenic liposome is a versatile and effective system for the stimulation of Ag-specific immune responses at both mucosal and systemic compartments.     

Liposomes in Host Defense Mechanism: A Key Role for Macrophages

Abstract

Liposomes can be used as carriers for antigens, immunomodulators and cytotoxic drugs. Such liposomes may serve as a tool to manipulate immune and non-immune host defense mechanisms. In most cases their effects are mediated by macrophages. Macrophages seem to be involved in humoral (antibody) responses and in cytotoxic T-lymphocyte responses. They are also important in non-immune defense mechanisms against foreign invaders and altered self. Which macrophages can be influenced by the liposome encapsulated molecules depends on the administration route of the liposomes. The macrophages ingest the liposomes. Once within the cell, lysosomal phospholipases disrupt the phospholipid bilayers. In this way, encapsulated molecules are released in the cell. Such liposome delivered molecules can be processed (antigens), activate the macrophage (immunomodulators) or disturb the metabolism of the cells (cytotoxic drugs). That the latter inhibition of macrophage functions may result in immunopotentiation is explained by the fact that certain macrophages are regulating immune functions by suppression.     

Replicating rather than nonreplicating adenovirus-human immunodeficiency virus recombinant vaccines are better at eliciting potent cellular immunity and priming high-titer antibodies

A major challenge in combating the human immunodeficiency virus (HIV) epidemic is the development of vaccines capable of inducing potent, persistent cellular immunity and broadly reactive neutralizing antibody responses to HIV type 1 (HIV-1). We report here the results of a preclinical trial using the chimpanzee model to investigate a combination vaccine strategy involving sequential priming immunizations with different serotypes of adenovirus (Ad)/HIV-1(MN)env/rev recombinants and boosting with an HIV envelope subunit protein, oligomeric HIV(SF162) gp140deltaV2. The immunogenicities of replicating and nonreplicating Ad/HIV-1(MN)env/rev recombinants were compared. Replicating Ad/HIV recombinants were better at eliciting HIV-specific cellular immune responses and better at priming humoral immunity against HIV than nonreplicating Ad-HIV recombinants carrying the same gene insert. Enhanced cellular immunity was manifested by a greater frequency of HIV envelope-specific gamma interferon-secreting peripheral blood lymphocytes and better priming of T-cell proliferative responses. Enhanced humoral immunity was seen in higher anti-envelope binding and neutralizing antibody titers and better induction of antibody-dependent cellular cytotoxicity. More animals primed with replicating Ad recombinants mounted neutralizing antibodies against heterologous R5 viruses after one or two booster immunizations with the mismatched oligomeric HIV-1(SF162) gp140deltaV2 protein. These results support continued development of the replicating Ad-HIV recombinant vaccine approach and suggest that the use of replicating vectors for other vaccines may prove fruitful.     

Comparative Study of the Adjuvanticity of FIA and Phosphatidylcholine Liposomes for Purified Mycobacterial RNA

Abstract

In the present study, RNA isolated from Mycobacterium t ubercu losis H,_Ra cells was further purified on sepharose CL-'tB which yielded three fractions i.e. F., F and F,. Out of these, F, was major fraction containing least amount of protein contamination (2.3%). A comparative study of the immunoreactivity of these three fractions indicated that F. and F2 were more immunoreactive than F,. Animals immunized with F. fraction emulsified with FIA or encapsulated in egg phosphatidylcholine (EPC) liposomes induced comparable humoral and cell mediated immune (CMI) responses. Further, immunization with this fraction resulted in significant protection as revealed by high survival rate and decreased bacterial load in the infected organs as compared to nonimmunized animals on challenge with Mt uberculosi s H. Rv. Protection provided by F. using FIA and liposomes as adjuvants was quite comparable, indicating that liposomes can replace FIA for mycobacterial antigens.     

Deletion of Specific Immune-Modulatory Genes from Modified Vaccinia Virus Ankara-Based HIV Vaccines Engenders Improved Immunogenicity in Rhesus Macaques

Modified vaccinia virus Ankara (MVA) is a safe, attenuated orthopoxvirus that is being developed as a vaccine vector but has demonstrated limited immunogenicity in several early-phase clinical trials. Our objective was to rationally improve the immunogenicity of MVA-based HIV/AIDS vaccines via the targeted deletion of specific poxvirus immune-modulatory genes. Vaccines expressing codon-optimized HIV subtype C consensus Env and Gag antigens were generated from MVA vector backbones that (i) harbor simultaneous deletions of four viral immune-modulatory genes, encoding an interleukin-18 (IL-18) binding protein, an IL-1β receptor, a dominant negative Toll/IL-1 signaling adapter, and CC-chemokine binding protein (MVAΔ4-HIV); (ii) harbor a deletion of an additional (fifth) viral gene, encoding uracil-DNA glycosylase (MVAΔ5-HIV); or (iii) represent the parental MVA backbone as a control (MVA-HIV). We performed head-to-head comparisons of the cellular and humoral immune responses that were elicited by these vectors during homologous prime-boost immunization regimens utilizing either high-dose (2 × 10⁸ PFU) or low-dose (1 × 10⁷ PFU) intramuscular immunization of rhesus macaques. At all time points, a majority of the HIV-specific T cell responses, elicited by all vectors, were directed against Env, rather than Gag, determinants, as previously observed with other vector systems. Both modified vectors elicited up to 6-fold-higher frequencies of HIV-specific CD8 and CD4 T cell responses and up to 25-fold-higher titers of Env (gp120)-specific binding (nonneutralizing) antibody responses that were relatively transient in nature. While the correlates of protection against HIV infection remain incompletely defined, our results indicate that the rational deletion of specific genes from MVA vectors can positively alter their cellular and humoral immunogenicity profiles in nonhuman primates.     

Modifications of the human immunodeficiency virus envelope glycoprotein enhance immunogenicity for genetic immunization

In this study, we have investigated the effect of specific mutations in human immunodeficiency virus type 1 (HIV-1) envelope (Env) on antibody production in an effort to improve humoral immune responses to this glycoprotein by DNA vaccination. Mice were injected with plasmid expression vectors encoding HIV Env with modifications in regions that might affect this response. Elimination of conserved glycosylation sites did not substantially enhance humoral or cytotoxic-T-lymphocyte (CTL) immunity. In contrast, a modified gp140 with different COOH-terminal mutations intended to mimic a fusion intermediate and stabilize trimer formation enhanced humoral immunity without reducing the efficacy of the CTL response. This mutant, with deletions in the cleavage site, fusogenic domain, and spacing of heptad repeats 1 and 2, retained native antigenic conformational determinants as defined by binding to known monoclonal antibodies or CD4, oligomer formation, and virus neutralization in vitro. Importantly, this modified Env, gp140 Delta CFI, stimulated the antibody response to native gp160 while it retained its ability to induce a CTL response, a desirable feature for an AIDS vaccine.     

TLR7 imidazoquinoline ligand 3M-019 is a potent adjuvant for pure protein prototype vaccines

Cancer vaccines, while theoretically attractive, present difficult challenges that must be overcome to be effective. Cancer vaccines are often poorly immunogenic and may require augmentation of immunogenicity through the use of adjuvants and/or immune response modifiers. Toll-like receptor (TLR) ligands are a relatively new class of immune response modifiers that may have great potential in inducing and augmenting both cellular and humoral immunity to vaccines. TLR7 ligands produce strong cellular responses and specific IgG2a and IgG2b antibody responses to protein immunogens. This study shows that a new TLR7 ligand, 3M-019, in combination with liposomes produces very strong immune responses to a pure protein prototype vaccine in mice. Female C57BL/6 mice were immunized subcutaneously with ovalbumin (OVA, 0.1 mg/dose) weekly 4x. Some groups were immunized to OVA plus 3M-019 or to OVA plus 3M-019 encapsulated in liposomes. Both antibody and cellular immune responses against OVA were measured after either two or four immunizations. Anti-OVA IgG antibody responses were significantly increased after two immunizations and were substantially higher after four immunizations in mice immunized with OVA combined with 3M-019. Encapsulation in liposomes further augmented antibody responses. IgM responses, on the other hand, were lowered by 3M-019. OVA-specific IgG2a levels were increased 625-fold by 3M-019 in liposomes compared to OVA alone, while anti-OVA IgG2b levels were over 3,000 times higher. In both cases encapsulation of 3M-019 in liposomes was stronger than either liposomes alone or 3M-019 without liposomes. Cellular immune responses were likewise increased by 3M-019 but further enhanced when it was encapsulated in liposomes. The lack of toxicity also indicates that this combination may by safe, effective method to boost immune response to cancer vaccines.     

Inhibition of specific immune responses by feeding protein antigens. IV. Evidence for tolerance and specific active suppression of cell-mediated immune responses to ovalbumin.

We studied the effect of a single intragastric administration of ovalbumin (OVA) on the subsequent development of OVA-specific cell-mediated immune (CMI) responses in BDF1 mice. In animals fed OVA 7 days before subcutaneous sensitization with OVA-CFA, we observed a concomitant dose-dependent decrease in both the humoral and CMI responses specific for OVA. The CMI tolerance was found to be antigen-specific when assayed in vivo by ear swelling or in vitro by an antigen-induced T cell proliferation assay because OVA-fed mice responded normally to sensitization with horse gamma-globulin. It was also shown that either spleen or lymph node cells, but not serum, from OVA-fed donors transferred suppression to normal recipients. The transfer was mediated by antigen-specific suppressor T cells (Ts) that appeared to inhibit the induction phase (afferent limb) of the CMI response, since the Ts were only effective when transferred before or shortly after the onset of sensitization.     

Interactions of human lymphoblasts with targeted vesicles containing Sendai virus envelope proteins

We have studied the internalization of targeted fusogenic liposome content to leukemic T cells (CEM) in vitro. We describe a method for the covalent coupling of T101 antibody to the surface of liposomes and the incorporation of fusogenic viral protein into the liposome membrane. Hygromycin B, an impermeant inhibitor of protein synthesis, was encapsulated in the targeted fusogenic liposomes and delivered directly to the cytoplasm of leukemic T cells by fusion between the two membranes. The cytotoxic effect was measured by [3H]thymidine incorporation. We show that CEM are rapidly and specifically killed by the drug encapsulated in the targeted fusogenic liposomes. This effect is due to the binding of the liposome by means of the antibody and then to the fusion of the liposome with the targeted cell membrane, mediated by F protein.     

Fusogenic potential of prokaryotic membrane lipids. Implication in vaccine development.

Development of protective immunity against many pathogens, particularly viruses, requires fine orchestration of both humoral- and cell mediated-immunity. The immunization of animals with soluble antigens usually leads to the induction of humoral immune responses. In contrast, the activation of a cell-mediated immune response against exogenous antigens has always been a challenge, requiring special strategies to expose them to the proteasome, a multifunctional protease complex in the cytosol of the target cells. The degradation of the protein by the cytosolic proteolytic system forms a cardinal step for the induction of cytotoxic T lymphocytes (CTLs). In the present study, we report that a potent primary CTL response against a soluble protein, ovalbumin, can be induced in mice by encapsulating it in the liposomes comprised of Escherichia coli membrane lipids. These lipids were shown to induce strong membrane-membrane fusion as evident from resonance energy transfer and content mixing assays. Furthermore, the fusion of these liposomes with living cells (J774 A1) was demonstrated to result in effective transfer of a fluorescent lipid probe to the plasma membrane of the cells. Moreover, ricin A, a protein synthesis inhibitor that does not cross plasma membrane, was demonstrated to gain access to the cytosol when it was encapsulated in these liposomes. Finally, the liposomes were demonstrated to behave like efficient vehicles for the in vivo delivery of the antigens to the target cells resulting in the elicitation of antigen reactive CD8+ T cell responses.     

Limited Contribution of Mucosal IgA to Simian Immunodeficiency Virus (SIV)-Specific Neutralizing Antibody Response and Virus Envelope Evolution in Breast Milk of SIV-Infected,Lactating Rhesus Monkeys

Breast milk transmission of human immunodeficiency virus (HIV) remains an important mode of infant HIV acquisition. Interestingly, the majority of infants remain uninfected during prolonged virus exposure via breastfeeding, raising the possibility that immune components in milk prevent mucosal virus transmission. HIV-specific antibody responses are detectable in the milk of HIV-infected women and simian immunodeficiency virus (SIV)-infected monkeys; however, the role of these humoral responses in virus neutralization and local virus quasispecies evolution has not been characterized. In this study, four lactating rhesus monkeys were inoculated with SIVmac251 and monitored for SIV envelope-specific humoral responses and virus evolution in milk and plasma throughout infection. While the kinetics and breadth of the SIV-specific IgG and IgA responses in milk were similar to those in plasma, the magnitude of the milk responses was considerably lower than that of the plasma responses. Furthermore, a neutralizing antibody response against the inoculation virus was not detected in milk samples at 1 year after infection, despite a measurable autologous neutralizing antibody response in plasma samples obtained from three of four monkeys. Interestingly, while IgA is the predominant immunoglobulin in milk, the milk SIV envelope-specific IgA response was lower in magnitude and demonstrated more limited neutralizing capacity against a T-cell line-adapted SIV compared to those of the milk IgG response. Finally, amino acid mutations in the envelope gene product of SIV variants in milk and plasma samples occurred in similar numbers and at similar positions, indicating that the humoral immune pressure in milk does not drive distinct virus evolution in the breast milk compartment.Breastfeeding is an important component of the maternal-infant immune system, providing the infant with passive maternal immunity and protection against infectious pathogens. In fact, non-breast-fed infants in developing nations experience higher mortality due to respiratory and diarrheal illnesses (45). However, breastfeeding is also a mode of infant human immunodeficiency virus (HIV) acquisition, contributing to a large proportion of infant HIV infections in areas of high HIV prevalence. Therefore, development of feeding strategies that promote HIV-free survival of infants born to HIV-infected mothers in developing nations poses a major public health challenge.Interestingly, in the absence of antiretroviral prophylaxis, HIV is transmitted via breast milk to only 10% of infants chronically exposed to the virus via breastfeeding (19, 25). This low rate of HIV transmission suggests that antiviral immune factors in milk may protect the majority of infants from mucosal HIV acquisition. HIV envelope-specific antibody responses have been identified in milk, but the magnitude of these responses is similar in women who transmit the virus via breast milk and women whose infants remain uninfected throughout breastfeeding (3, 11, 23). Likewise, the magnitude of simian immunodeficiency virus (SIV) envelope-specific antibody responses in the milk of SIV-infected, lactating rhesus monkeys did not differ in those mothers that did and did not transmit the virus to their suckling infant (1, 42). Proposed mechanisms for HIV-specific breast milk antibody function include virus neutralization and impairment of virus transcytosis through an epithelial cell layer (3, 7, 17). Therefore, the function, rather than the magnitude, of the HIV-specific breast milk antibody response may be the critical feature in protection against infant mucosal transmission. Importantly, passive transfer of broadly neutralizing HIV-specific antibody to neonatal monkeys protected the infants against oral simian-human immunodeficiency virus (SHIV) challenge, indicating that passively transferred humoral immunity can protect infants from virus transmission through breastfeeding (18, 41).Vertically transmitted HIV variants, including those transmitted via breast milk, have been reported to be resistant to neutralization by systemic maternal antibody responses (9, 38). However, HIV-specific neutralizing antibody responses in breast milk have not been characterized. In fact, the ability of mucosal IgA to neutralize HIV remains an important question in the HIV field. While an HIV-specific mucosal IgA response in the genital tracts of exposed-uninfected individuals has been described, the role of mucosal IgA in protection against mucosal transmission of HIV is unclear and controversial (5, 8-10). Furthermore, the contribution of locally replicating virus at mucosal surfaces to the divergence of the systemic and mucosal antibody responses is unknown. Similarly, the role of mucosal antibody in the shaping of mucosal virus quasispecies evolution is not well characterized. Delineation of the function and role of mucosal antibody responses in defining the pool of transmitted virus will be crucial for the design of immunologic interventions to reduce breast milk transmission of HIV.SIV infection of lactating rhesus monkeys provides an excellent model to characterize virus-specific immune responses and virus evolution in milk, as the sequence of the virus inoculum, the timing of the infection, and the virus-specific immunodominant responses are well defined in this model. Furthermore, SIV-infected, lactating rhesus monkeys transmit the virus to their suckling infants via breastfeeding (1). We have developed a pharmacologic protocol to induce lactation in nonpregnant rhesus monkeys, facilitating these studies without reliance on breeder monkeys. Moreover, the milk produced by hormone-induced, lactating monkeys has immunoglobulin content and a lymphocyte phenotype similar to that produced by naturally lactating monkeys (35). In this study, we characterized the neutralizing potency of the SIV envelope-specific IgG and IgA responses in milk and their role in shaping the SIV envelope gene evolution of local virus variants.     

A novel vaccine delivery system using immunopotentiating fusogenic liposomes.

We previously reported the preparation and characterization of fusogenic liposomes (FLs), which have two highly immunogenic glycoproteins of the Sendai virus on their surface. In this report, we investigated the capacity of FLs to enhance antigen-specific humoral immunity in mice. FLs function as a lymphocyte mitogen with high immunogenicity consistent with viral envelope proteins. Markedly increased levels of anti-ovalbumin (OVA) antibody were detected in serum from mice immunized with OVA encapsulated in FLs compared to sera from mice immunized with free OVA or OVA encapsulated in plain liposomes. An anti-OVA antibody response was not observed in mice immunized with OVA simply mixed with empty FLs. These results indicate that FLs function as a novel immunoadjuvant in inducing antigen-specific antibody production.     

Phenotypic and functional analysis of immune CD8+ T cell responses induced by a single injection of a HIV DNA vaccine in mice

HIV DNA vaccines are potent inducers of cell-mediated immune (CMI) response in mice but elicit poor HIV-specific IFN-gamma-producing T cells in monkeys and humans. In this study, we performed kinetic analyses on splenocytes of BALB/c mice that were immunized by a single injection with a unique DNA vaccine. Using IFN-gamma-ELISPOT and multiparametric FACS analysis, we characterized the induced CMI response. We found that the response was detectable for at least 63 wk. ELISPOT detection of IFN-gamma-producing T cells showed a profile with two waves separated by a long period of minimal response. Multiparametric FACS analysis showed two populations of CD3(+)CD8(+) T cells that were specific for all HIV Ags. These cells had similar robust proliferation abilities and contained granzyme B. However, only a few produced IFN-gamma. Both IFN-gamma-producing and non-IFN-gamma-producing HIV-specific CD8(+) T cells were detected in the early stage (week (W)1 and W2 postimmunization (PI)), in the prolonged intermediate period of minimal response (W4-W26 PI), and in the final late phase of increased response (W30-W63 PI). Our longitudinal characterization showed that both subsets of cells underwent expansion, contraction, and memory generation/maintenance phases throughout the lifespan of the animal. Altogether, these findings bring insight to the heterogeneity of the immune T cell response induced by a single immunization with this DNA and strengthen the concept that used of the IFN-gamma-ELISPOT assay alone may be insufficient to detect critical T cell responses to candidate HIV vaccines.