John Cooper Cox

Adjuvants—a classification and review of their modes of action

Since early this century, various substances have been added to vaccines and certain formulations have been devised in an attempt to render vaccines more effective. Despite a plethora of options, only aluminium salts have gained acceptance as human vaccine adjuvants and even veterinary vaccines are largely dependent upon the use of aluminium salts. Currently, many new vaccines are under development and there is a desire to simplify vaccination schedules both by increasing the number of components per vaccine and decreasing the number of doses required for a vaccine course. New, more effective adjuvants will be required to achieve this.

ISCOMs and other saponin based adjuvants

Saponins are chemically a heterogeneous group of sterol glycosides and triterpene glycosides which are common constituents of plants. One source of triterpenoid saponins obtained from the bark of Quillaia saponaria Molina (the soap bark tree) have been known to cause substantial enhancement of immune responses since the 1920s. Despite their use in animal vaccines, the development of saponin-based formulations for human vaccines has been impeded by their complexity and concerns about toxicity. This review briefly covers the use of saponins for animal vaccines but focuses mainly on the development of these adjuvants for use in man. Important aspects include preparation of purified or highly defined saponin fractions, improved understanding of the relationships between adjuvant activity, toxicity and structure of saponins and formulation of saponins into structures with reduced toxicity such as ISCOMs. Recent developments in the understanding of cellular interactions, cytokine induction and the in vivo localisation of saponin containing formulations will also be reviewed.

ISCOMs: an adjuvant with multiple functions

Aluminum salts are currently the only widely used adjuvant for human vaccines. Over the past 10–15 years, a large research effort has attempted to find novel adjuvants with ability to induce abroad range of immune responses, including cell‐mediated immunity. The immunostimulating complex or ISCOM is one adjuvant with multiple adjuvant properties. ISCOMs are open cage‐like complexes typically with a diameter of about 40 nm that are built up by cholesterol, lipid, immunogen, and saponins from the bark of the tree Quillaia saponaria Molina. ISCOMs have been demonstrated to promote antibody responses and induce T helper cell as well as cytotoxic T lymphocyte responses in a variety of experimental animal models, and have now progressed to phase I and II human trials. This review describes recent developments in the understanding of the structure, composition, and preparation of ISCOMs and will cover important aspects of the understanding of the adjuvant functions of ISCOMs and how they act on the immune system. J. Leukoc. Biol. 64: 713–723; 1998.

Characterization of Hepatitis C Virus Core-Specific Immune Responses Primed in Rhesus Macaques by a Nonclassical ISCOM Vaccine

Current therapies for the treatment of hepatitis C virus (HCV) infection are only effective in a restricted number of patients. Cellular immune responses, particularly those mediated by CD8+ CTLs, are thought to play a role in the control of infection and the response to antiviral therapies. Because the Core protein is the most conserved HCV protein among genotypes, we evaluated the ability of a Core prototype vaccine to prime cellular immune responses in rhesus macaques. Since there are serious concerns about using a genetic vaccine encoding for Core, this vaccine was a nonclassical ISCOM formulation in which the Core protein was adsorbed onto (not entrapped within) the ISCOMATRIX, resulting in ∼1-μm particulates (as opposed to 40 nm for classical ISCOM formulations). We report that this Core-ISCOM prototype vaccine primed strong CD4+ and CD8+ T cell responses. Using intracellular staining for cytokines, we show that in immunized animals 0.30–0.71 and 0.32–2.21% of the circulating CD8+ and CD4+ T cells, respectively, were specific for naturally processed HCV Core peptides. Furthermore, this vaccine elicited a Th0-type response and induced a high titer of Abs against Core and long-lived cellular immune responses. Finally, we provide evidence that Core-ISCOM could serve as an adjuvant for the HCV envelope protein E1E2. Thus, these data provide evidence that Core-ISCOM is effective at inducing cellular and humoral immune responses in nonhuman primates.

Intranasal vaccination with ISCOMATRIX adjuvanted influenza vaccine.

Mucosal delivery of inactivated vaccines that are able to elicit protective immune responses against respiratory diseases has been a long time goal of vaccinologists. Such vaccines would enable a more appropriate means of vaccination against respiratory diseases than those currently delivered by a parenteral route. The intranasal delivery of inactivated influenza vaccine plus the ISCOMATRIX (IMX) adjuvant, simply mixed together, was able to induce serum haemagglutination inhibition (HAI) titres in mice far superior to those obtained with unadjuvanted vaccine delivered subcutaneously. Furthermore, the IMX adjuvanted vaccine delivered intranasally induced mucosal IgA responses in the lung, nasal passages and large intestine, together with high levels of serum IgA. Intranasal delivery of IMX adjuvanted influenza vaccine in sheep gave antibody responses in both serum and nasal secretions that surpassed the levels obtained with unadjuvanted vaccine administered subcutaneously. These observations suggest that it may be possible to induce effective immunity to influenza in humans by intranasal vaccination with an IMX adjuvanted inactivated vaccine.

Uptake and adjuvant activity of orally delivered saponin and ISCOM™ vaccines

Saponins are a highly heterogenous group of glycosides which are common in plants and have been known to have adjuvant properties since the 1920s. The immunostimulating complex or ISCOM is a particulate adjuvant/antigen delivery system. ISCOMs are open cage-like complexes typically with a diameter of about 40 nm which are built up by cholesterol, lipid, immunogen and saponins from the bark of Quillaia saponaria Molina (soap bark tree). ISCOMs and saponins are used as adjuvants in some commercial veterinary vaccines and have been examined as adjuvants in a large number of human experimental vaccines. This review describes the current status and potential of saponin and ISCOMs as adjuvants for orally-administered vaccines with special reference to the induction of local and systemic immune responses and interactions with the intestinal epithelium. The structure and composition of saponins and ISCOMs will also be reviewed.

Intranasal immunisation with influenza-ISCOM induces strong mucosal as well as systemic antibody and cytotoxic T-lymphocyte responses.

Intranasal administration of vaccines is preferred for induction of mucosal immune responses. In this study, mice were immunised intranasally and subcutaneously with influenza-immuno stimulating complexes (influenza-ISCOM). The intranasal dose was 15-times the subcutaneous dose. All mice dosed with influenza-ISCOMs survived challenge with live virus and comparable serum antibody and splenic cytotoxic T-lymphocyte responses were detected in both groups. Induction of mucosal IgA was significantly higher with intranasal immunisation and was comparable to responses induced with the heat labile enterotoxin of Escherichia coli as adjuvant. These findings demonstrate that intranasal administration of high dose influenza-ISCOM results in potent systemic and mucosal immune responses.

Cytotoxic T cell polyepitope vaccines delivered by ISCOMs

CD8 alphabeta cytotoxic T lymphocyte (CTL) polyepitope or polytope vaccines have traditionally been delivered using recombinant vector or DNA based delivery modalities. Here we show the delivery of polytope vaccines in the form of either synthetic polypeptides or recombinant polytope proteins by ImmunoStimulatory COMplexes (ISCOMs(R)). Induction of multiple protective CTL responses by these polytope-ISCOM formulations were comparable to viral vector or DNA based delivery modalities as assessed by IFNgamma ELISpot, chromium release and viral challenge assays. Measurement of CTL responses specific for the different epitopes revealed immunodominance patterns, which were largely independent of the vaccine vector or the order of the epitopes in the polytope. ISCOMs thus emerge as a viable human delivery modality for protein-based polytope vaccines.

Studies on experimental adjuvanted influenza vaccines: comparison of immune stimulating complexes (Iscoms™) and oil-in-water vaccines

Detergent-disrupted influenza virus vaccines, formulated as Iscoms, or oil-in-water (o/w) emulsions, were administered parenterally to mice and evaluated for immunogenicity and protective efficacy. Both formulations enhanced both primary and secondary serum antibody responses. The magnitude of these responses with o/w emulsions was further enhanced by the addition of the non-ionic block copolymer L121 in the emulsion. Four weeks after primary immunization, mice were challenged by exposure to an aerosol containing infectious virus. Resistance to challenge in terms of survival rate and weight change correlated well with serum antibody titre for all formulations. Two major differences were observed between the adjuvant formulations. Iscom vaccines, formulated with Quil-A or the less toxic Quillaia saponin preparation Iscoprep 703, induced specific cytotoxic T-lymphocyte responses, whereas the o/w-based vaccines did not. In addition, dose-site reactivity studies in sheep showed that Iscom vaccines were less reactive than o/w-based vaccines, the degree of reactivity of the latter increasing sharply with increasing L121 concentration. On the basis of these studies, Iscoms were chosen for development as a potential adjuvant for human influenza vaccines.

A novel format for a rapid sandwich EIA and its application to the identification of snake venoms

A rapid sandwich enzyme immunoassay format is described where conjugate is lyophilised within the well in which the test reaction will occur. The format is straight forward to manufacture, has a prolonged shelf life, and eliminates one incubation and wash step from the usual test procedure. The technology has been applied to the development of a rapid assay for the identification of snake venom in clinical specimens. The resultant assay was specific and sensitive, provided rapid results and was appropriate for field use.