A Modified ELISA for Measurement of High-Avidity IgG Antibodies to Meningococcal Serogroup C Polysaccharide that Correlate with Bactericidal Titers.

This chapter describes a modified enzyme-linked immunosorbent assay (ELISA) employing assay conditions that ensure specificity of antibody binding and favor detection primarily of high-avidity serum IgG antibodies to meningococcal serogroup C polysaccharide (1). Antibody-binding assays such as the ELISA offer a convenient and reproducible method for quantifying anticapsular antibody responses to vaccination or disease. However, the results do not always correlate well with assays of antibody functional activity, such as bactericidal activity. For example, a standardized ELISA for measurement of antibody responses to meningococcal C polysaccharide has been described (2). When used to assay relatively homogenous populations of serum antibodies, for example in sera from immunized adults (3), or from younger individuals given a single vaccine (4), the results of the standard ELISA correlated well with serum bactericidal titers. In contrast, much lower correlations were observed when assaying heterologous populations of serum antibodies from vaccinated infants or toddlers (5,6), particularly from clinical studies comparing antibody responses of different age groups (6), or studies comparing responses to a polysaccharide and conjugate vaccines (7,8).

Antigen presentation and DNA vaccines.

There is reasonable evidence that both cross-priming and direct transfection of antigen-presenting cells (APCs) play a role in induction of immune responses by DNA vaccines. It is not known which mode is more important for priming cytotoxic T cell responses, but both are sufficient and neither alone is necessary. Hence, a rational strategy for increasing DNA vaccine potency would be to facilitate both pathways. With regard to cross-priming, a better understanding of the nature of the antigen transferred and the molecules/cells involved may suggest ways to design DNA vaccines to enhance this pathway. With respect to transfection of APCs, certain DNA formulations or delivery systems may be able to target APCs for increased DNA uptake. Other considerations include recruitment of APCs to the site of DNA injection and manipulation of these cells to ensure the proper activation state for priming immune responses. The burgeoning scientific literature in these areas indicates that much effort is currently being directed toward these goals.

Distribution of DNA vaccines determines their immunogenicity after intramuscular injection in mice.

Intramuscular injection of DNA vaccines elicits potent humoral and cellular immune responses in mice. However, DNA vaccines are less efficient in larger animal models and humans. To gain a better understanding of the factors limiting the efficacy of DNA vaccines, we used fluorescence-labeled plasmid DNA in mice to 1) define the macroscopic and microscopic distribution of DNA after injection into the tibialis anterior muscle, 2) characterize cellular uptake and expression of DNA in muscle and draining lymph nodes, and 3) determine the effect of modifying DNA distribution and cellular uptake by volume changes or electroporation on the magnitude of the immune response. Injection of a standard 50-microl dose resulted in the rapid dispersion of labeled DNA throughout the muscle. DNA was internalized within 5 min by muscle cells near the injection site and over several hours by cells that were located along muscle fibers and in the draining lymph nodes. Histochemical staining and analysis of mRNA expression in isolated cells by RT-PCR showed that the transgene was detectably expressed only by muscle cells, despite substantial DNA uptake by non-muscle cells. Reduction of the injection volume to 5 microl resulted in substantially less uptake and expression of DNA by muscle cells, and correspondingly lower immune responses against the transgene product. However, expression and immunogenicity were restored when the 5-microl injection was followed by electroporation in vivo. These findings indicate that distribution and cellular uptake significantly affect the immunogenicity of DNA vaccines.

Effect of individual conjugate dose on immunogenicity of type 6B pneumococcal polysaccharide-N. meningitidis outer membrane protein complex conjugate vaccines in infant rhesus monkeys.

A pneumococcal conjugate vaccine (PCV) has been developed consisting of capsular polysaccharide (Ps) coupled to the outer membrane protein complex of Neiserria meningitidis serogroup B. Experiments were conducted in infant rhesus monkeys to assess the potential to administer multiple Pn types in a single vaccine. A single type conjugate, 6B, was dosed from 0.025 to 25 microg Ps. Peak anti-6B Ps Ab titers were seen at lower doses of 0.025 and 0.25 microg Ps, while reduced titers of anti-6B Ps Ab were observed at the highest doses of conjugate administered, 2.5 and 25 microg Ps. By mixing free Ps, carrier, or another monovalent PCV with this 6B PCV, it was determined that reduced anti-6B Ps titers at high PCV doses were associated only with the quantity of type-specific Ps in the conjugate. Thus, increasing the amount of carrier protein or adding an additional monovalent conjugate did not significantly affect the response to type 6B Ps. These results suggest that, given an appropriately determined dose per individual pneumococcal Ps type, a multivalent PCV that includes many different types should have satisfactory clinical immunogenicity.

Plasmid DNA adsorbed onto cationic microparticles mediates target gene expression and antigen presentation by dendritic cells.

Dendritic cells (DC) play a key role in antigen presentation and activation of specific immunity. Much current research focuses on harnessing the potency of DC for vaccines, gene therapy, and cancer immunotherapy applications. However, DC are not readily transfected in vitro by traditional nonviral techniques. A novel DNA vaccine formulation was used to determine if DC are transfected in vitro. The formulation consists of plasmid DNA adsorbed on to cationic microparticles composed of the biodegradable polymer polylactide-co-glycolide (PLG) and the cationic surfactant, cetyltrimethylammonium bromide (CTAB). Using preparations of fluorescent-labeled plasmid DNA formulated on PLG-CTAB microparticles to study internalization by macrophages and dendritic cells in vitro and in vivo, we found that most, but not all, of the fluorescence was concentrated in endosomal compartments. Furthermore, uptake of plasmid DNA encoding HIV p55 gag adsorbed to PLG-CTAB microparticles by murine bone marrow-derived dendritic cells resulted in target gene expression, as detected by RT-PCR. The antigen was subsequently processed and presented, resulting in stimulation of an H-2kd-restricted, gag-specific T cell hybridoma. Activation of the hybridoma, detected by IL-2 production, was dose-dependent in the range of 0.1-20 microg DNA (10-2000 microg PLG) and was sustained up to 5 days after transfection. Thus, adsorption of plasmid DNA on PLG-CTAB microparticles provides a potentially useful nonviral approach for in vitro transfection of dendritic cells. Gene Therapy (2000) 7, 2105-2112.

Enhancement of DNA vaccine potency using conventional aluminum adjuvants.

The immunogenicity and protective efficacy of DNA vaccines have been amply demonstrated in numerous animal models of infectious disease. However, the feasibility of DNA vaccines for human use is not yet known. In order to investigate potential means of increasing the potency of DNA vaccines, conventional adjuvants such as aluminum salts were tested. Coadministration of these adjuvants with DNA vaccines substantially enhanced the ability of these vaccines to induce antibody responses up to 100-fold in mice and guinea pigs, and 5-10-fold in non-human primates. Effective formulations had no demonstrable effect on the levels of antigen expression in situ and consisted of adjuvants that did not form complexes with the plasmid DNA; rather they exerted their effects on antigen after expression in situ. Therefore, the potency of DNA vaccines both in laboratory rodents and in non-human primates can be substantially increased by simple formulation with conventional aluminum adjuvants.

DNA vaccines for viral diseases.

DNA plasmids encoding foreign proteins may be used as immunogens by direct intramuscular injection alone, or with various adjuvants and excipients, or by delivery of DNA-coated gold particles to the epidermis through biolistic immunization. Antibody, helper T lymphocyte, and cytotoxic T lymphocyte (CTL) responses have been induced in laboratory and domesticated animals by these methods. In a number of animal models, immune responses induced by DNA vaccination have been shown to be protective against challenge with various infectious agents. Immunization by injection of plasmids encoding foreign proteins has been used successfully as a research tool. This review summarizes the types of DNA vaccine vectors in common use, the immune responses and protective responses that have been obtained in animal models, the safety considerations pertinent to the evaluation of DNA vaccines in humans and the very limited information that is available from early clinical studies.

Dose dependence of CTL precursor frequency induced by a DNA vaccine and correlation with protective immunity against influenza virus challenge.

Intramuscular injection of BALB/c mice with a DNA plasmid encoding nucleoprotein (NP) from influenza virus A/PR/8/34 (H1N1) provides cross-strain protection against lethal challenge with influenza virus A/HK/68 (H3N2). CTL specific for the H-2Kd-restricted epitope NP147-155 are present in these mice and are thought to play a role in the protection. To assess the effectiveness of NP DNA immunization in comparison with influenza virus infection in the induction of CTL responses, we monitored the frequency of CTL precursors (CTLp) in mice following i.m. injection with NP DNA or intranasal infection with influenza virus and showed that the CTLp frequency in NP DNA-immunized mice can reach levels found in mice that had been infected with influenza virus. We also measured the CTLp frequency, anti-NP Ab titers, and T cell proliferative responses in mice that were injected with titrated dosages of NP DNA and documented a correlation of the CTLp frequency and the Ab titers, but not proliferative responses, with the injection dose. Furthermore, we observed a positive correlation between the frequency of NP147-155 epitope-specific CTLp and the extent of protective immunity against cross-strain influenza challenge induced by NP DNA injection. Collectively, these results and our early observations from adoptive transfer experiments of in vitro activated lymphocytes from NP DNA-immunized mice suggest a protective function of NP-specific CTLp in mice against cross-strain influenza virus challenge.

DNA vaccines for viral diseases

DNA plasmids encoding foreign proteins may be used as immunogens by direct intramuscular injection alone, or with various adjuvants and excipients, or by delivery of DNA-coated gold particles to the epidermis through biolistic immunization. Antibody, helper T lymphocyte, and cytotoxic T lymphocyte (CTL) responses have been induced in laboratory and domesticated animals by these methods. In a number of animal models, immune responses induced by DNA vaccination have been shown to be protective against challenge with various infectious agents. Immunization by injection of plasmids encoding foreign proteins has been used successfully as a research tool. This review summarizes the types of DNA vaccine vectors in common use, the immune responses and protective responses that have been obtained in animal models, the safety considerations pertinent to the evaluation of DNA vaccines in humans and the very limited information that is available from early clinical studies

DNA vaccines.

Immunization with plasmid DNA encoding antigenic proteins elicits both antibody and cell-mediated immune responses. This method of producing the protein antigens of interest directly in host cells can provide appropriate tertiary structure for the induction of conformationally specific antibodies, and also facilitates the induction of cellular immune responses. DNA immunization has provided effective protective immunity in various animal models. The immune responses induced by DNA vaccines may in some instances be preferable to those produced by immunization using conventional methods. DNA vaccination appears to be applicable to a variety of pathogens and is a useful method of raising immune responses. Thus this approach to vaccination has the potential to be a successful method of rapidly screening for antigens capable of inducing protective immunity, and of inducing protective immunity against pathogens of clinical importance.

Induction of MHC class I-restricted CTL response by DNA immunization with ubiquitin-influenza virus nucleoprotein fusion antigens.

DNA vaccines have been shown to be an effective means of inducing cytotoxic T-lymphocyte (CTL) responses in both young and aged mice. Better understanding of the pathways by which antigens encoded by DNA vaccines are processed and presented to CTL may allow for improvements in CTL responses in older animals. Since CTL recognize short peptides presented by MHC class I molecules, and since ubiquitin-dependent proteolysis is widely believed to be responsible for degradation of endogenously synthesized antigens and generation of these peptide ligands, we sought to use ubiquitin (Ub) conjugation to target influenza virus nucleoprotein (NP) antigen into the Ub-proteasome degradation pathway for MHC class I-restricted antigen processing and presentation. However, the addition of the Ub moiety did not affect the half-life of Ub-NP protein in transiently transfected human rhabdomyosarcoma (RD) cells. Moreover, the modifications of NP DNA vaccine with Ub conjugation did not affect their ability to induce a CTL response specific for the H-2Kd-restricted NP147-155 epitope, as assessed by both percent cytolysis in bulk CTL culture and by CTL precursor (CTLp) frequency in limiting dilution analysis (LDA). In contrast, the anti-NP antibody (Ab) responses were dramatically reduced in mice immunized with low doses (1 microgram) of Ub-NP constructs, compared with mice immunized with wild-type NP DNA. These results demonstrate that Ub conjugation alone does not guarantee targeting of endogenously synthesized antigens for rapid degradation by proteasomes. Furthermore, the ability of ubiquintination to reduce Ab responses to NP without affecting CTL responses suggests that the Ub modifications result in a lower availability of full-length NP from transfected cells in vivo. The implications of these data on antigen presentation and cross-priming are discussed.

Immunogenicity and efficacy of DNA vaccines encoding influenza A proteins in aged mice.

Influenza is a leading cause of morbidity and mortality in older persons. The current influenza vaccine is only modestly successful, in part because of an age-related decline in immunogenicity and also because it induces only type-specified immunity. To overcome this, we evaluated DNA vaccines encoding A/PR8/34 haemagglutinin (HA) and nucleoprotein (NP) in young and aged BALB/c mice. Control mice were given formalin-inactivated A/PR8/34, control DNA, or a non-lethal dose of PR8. Aged mice given HA DNA developed slightly lower anti-HA serum antibodies than young mice; however, both young and aged mice were protected from a homotypic PR8 challenge. Following vaccination with NP DNA, both young and aged mice developed anti-NP bulk cytotoxic T-lymphocyte (CTL) activity and pCTL frequency similar to control animals. When challenged with a low dose of A/HK/68 (H3N2) influenza virus, both young mice and aged mice showed significant protection as measured by inhibition of weight loss. When challenged with a relatively high dose of A/HR/68 (H3N2) influenza virus, however, the anti-NP vaccine only partially protected young mice and failed to protect aged mice. These data demonstrate that DNA-based vaccines are immunogenic in aged animals, but suggest that factors other than the age-related decline in CTL activity also contribute to the increased morbidity and mortality of influenza in the elderly.

Antibody responses to capsular polysaccharide backbone and O-acetate side groups of Streptococcus pneumoniae type 9V in humans and rhesus macaques.

Streptococcus pneumoniae is responsible for high rates of pneumococcal bacteremia, meningitis, pneumonia, and acute otitis media worldwide. Protection from disease is conferred by antibodies specific for the polysaccharide (Ps) capsule of the bacteria. Of the four types of group 9 pneumococci, types 9N and 9V cause the most disease, and both types are included in the polyvalent pneumococcal vaccine. The type 9V capsule consists of repeating pentasaccharide units linearly arranged, with an average of 1 to 2 mol of O-acetate side chains per mol of repeat units, added in a complex pattern in which not all repeat units are alike. alpha-GlcA residues may be O-acetylated in the 2 (17%) or 3 (25%) position and beta-ManNAc residues may be O-acetylated in the 4 (6%) or 6 (55%) position. Under certain conditions, the O-acetate side chains are subject to oxidation, which results in subsequent de-O-acetylation of a significant number of the repeat units. This de-O-acetylation could adversely affect the efficacy of a vaccine containing the 9V Ps. A study was undertaken to compare the relative contributions of O-acetate and Ps backbone epitopes in the immune response to S. pneumoniae 9V type-specific Ps. In both an infant rhesus monkey model and humans, antibodies against the non-O-acetylated 9V backbone as well as against O-acetylated 9V Ps were detected. Functional (opsonophagocytic) activity was observed in antisera in which the predominant species of antibody recognized de-O-acetylated 9V Ps. We concluded that the O-acetate side groups, while recognized, are not essential to the ability of the 9V Ps to induce functional antibody responses.

Protective CD4+ and CD8+ T cells against influenza virus induced by vaccination with nucleoprotein DNA.

DNA vaccination is an effective means of eliciting both humoral and cellular immunity, including cytotoxic T lymphocytes (CTL). Using an influenza virus model, we previously demonstrated that injection of DNA encoding influenza virus nucleoprotein (NP) induced major histocompatibility complex class I-restricted CTL and cross-strain protection from lethal virus challenge in mice (J. B. Ulmer et al., Science 259:1745-1749, 1993). In the present study, we have characterized in more detail the cellular immune responses induced by NP DNA, which included robust lymphoproliferation and Th1-type cytokine secretion (high levels of gamma interferon and interleukin-2 [IL-2], with little IL-4 or IL-10) in response to antigen-specific restimulation of splenocytes in vitro. These responses were mediated by CD4+ T cells, as shown by in vitro depletion of T-cell subsets. Taken together, these results indicate that immunization with NP DNA primes both cytolytic CD8+ T cells and cytokine-secreting CD4+ T cells. Further, we demonstrate by adoptive transfer and in vivo depletion of T-cell subsets that both of these types of T cells act as effectors in protective immunity against influenza virus challenge conferred by NP DNA.

Priming of cytotoxic T lymphocytes by DNA vaccines: requirement for professional antigen presenting cells and evidence for antigen transfer from myocytes.

BACKGROUND: MHC class I molecule-restricted cytotoxic T-lymphocyte (CTL) responses are induced following either intramuscular (i.m.) injection of a DNA plasmid encoding influenza virus nucleoprotein (NP) or transplantation of myoblasts stably transfected with the NP gene, the latter indicating that synthesis of NP by myocytes in vivo is sufficient to induce CTL. The present study was designed to investigate the role of muscle cells and involvement of professional antigen-presenting cells (APCs) in priming CTL responses following DNA vaccination. MATERIALS AND METHODS: Parent-->F1 bone marrow (BM) chimeric mice were generated whose somatic cells include muscle cells bearing both parental MHC haplotypes, while their professional APCs express only the donor MHC haplotypes. RESULTS AND CONCLUSIONS: Upon injection of NP DNA, or after infection with influenza virus, CTL responses generated in the chimeras were restricted to the donor MHC haplotype. Thus cells of BM lineage were definitively shown to be responsible for priming such CTL responses after infection or DNA immunization. Moreover, expression of antigen by muscle cells in BM chimeric mice after myoblast transplantation is sufficient to induce CTL restricted only by the MHC haplotype of the donor BM. This indicates that transfer of antigen from myocytes to professional APCs can occur, thus obviating a requirement for direct transfection of BM-derived cells.

Expression of a viral protein by muscle cells in vivo induces protective cell-mediated immunity.

Intramuscular injection of plasmid DNA expression vectors results in transfection of myocytes in situ. To determine whether expression of antigen by myocytes is sufficient to induce protective cell-mediated immunity, stably transfected myoblasts expressing influenza nucleoprotein (NP) were transplanted into mice. These animals produced high-titer anti-NP antibodies and MHC class I-restricted cytotoxic T lymphocytes, and were protected from a cross-strain lethal challenge with influenza A virus. Therefore, antigen expression by muscle cells in vivo is sufficient to confer protective cell-mediated immunity.

Further protection against antigenic drift of influenza virus in a ferret model by DNA vaccination.

Previously we showed that immunization of ferrets with DNA encoding the hemagglutinin (HA), nucleoprotein (NP), and matrix protein (M1) of influenza virus induced protective immune responses. A DNA vaccine encoding HA (from a 1991 strain), NP and M1 (from a 1989 strain) protected ferrets better against challenge with the antigenic drift variant A/Georgia/03/93 than did the inactivated vaccine from the 1992-93 influenza season. Here we report that the same DNA vaccine protected ferrets against a second, further divergent, drift variant (A/Johannesburg/33/94). Furthermore, the extent of protection provided by the DNA vaccine was equivalent to the homologous protection provided by an inactivated vaccine that exactly matched the challenge strain.

Protective cellular immunity: cytotoxic T-lymphocyte responses against dominant and recessive epitopes of influenza virus nucleoprotein induced by DNA immunization.

DNA immunization offers a novel means to induce cellular immunity in a population with a heterogeneous genetic background. An immunorecessive cytotoxic T-lymphocyte (CTL) epitope in influenza virus nucleoprotein (NP), residues 218 to 226, was identified when mice were immunized with a plasmid DNA encoding a full-length mutant NP in which the anchor residues for the immunodominant NP147-155 epitope were altered. Mice immunized with wild-type or mutant NP DNA were protected from lethal cross-strain virus challenge, and the protection could be adoptively transferred by immune splenocytes, indicating the role of cell-mediated immunity in the protection. DNA immunization is capable of eliciting protective cellular immunity against both immunodominant and immunorecessive CTL epitopes in the hierarchy seen with virus infection.