Structure of immune stimulating complex matrices and immune stimulating complexes in suspension determined by small-angle x-ray scattering.

Immune stimulating complex (ISCOM) particles consisting of a mixture of Quil-A, cholesterol, and phospholipids were structurally characterized by small-angle x-ray scattering (SAXS). The ISCOM particles are perforated vesicles of very well-defined structures. We developed and implemented a novel (to our knowledge) modeling method based on Monte Carlo simulation integrations to describe the SAXS data. This approach is similar to the traditional modeling of SAXS data, in which a structure is assumed, the scattering intensity is calculated, and structural parameters are optimized by weighted least-squares methods when the model scattering intensity is fitted to the experimental data. SAXS data from plain ISCOM matrix particles in aqueous suspension, as well as those from complete ISCOMs (i.e., with an antigen (tetanus toxoid) incorporated) can be modeled as a polydisperse distribution of perforated bilayer vesicles with icosahedral, football, or tennis ball structures. The dominating structure is the tennis ball structure, with an outer diameter of 40 nm and with 20 holes 5-6 nm in diameter. The lipid bilayer membrane is 4.6 nm thick, with a low-electron-density, 2.0-nm-thick hydrocarbon core. Surprisingly, in the ISCOMs, the tetanus toxoid is located just below the membrane inside the particles.

In vivo activity of cationic immune stimulating complexes (PLUSCOMs).

A particulate vaccine delivery system consisting of cationic ISCOM derivatives (PLUSCOMs) was compared to classic anionic ISCOMs with regard to antigen attachment and ability to elicit in vivo T cell responses against a model protein antigen (ovalbumin [OVA]). ISCOMs did not incorporate hydrophilic OVA whilst OVA readily adsorbed onto PLUSCOMs with increasing adsorption at higher protein concentrations. The zeta-potential of PLUSCOMs significantly decreased with increasing protein load, suggesting neutralization of the cationic charge upon absorption of the anionic OVA. Antigen-specific CD8 T cell responses were demonstrated in mice vaccinated with either PLUSCOMs or ISCOMs. Ex vivo restimulation of harvested T cells demonstrated that cells isolated from PLUSCOM and ISCOM vaccinated mice responded to the secondary OVA challenge more efficiently than mice vaccinated with OVA in solution. Restimulated cells from the mice vaccinated with particulate vaccines produced significantly more INF-gamma. Therefore PLUSCOMs are as effective as classic ISCOMs in inducing antigen-specific CD8 T cell responses and have advantages with regard to the incorporation of purified anionic antigens.

On the preparation, microscopic investigation and application of ISCOMs.

ISCOM matrices constitute colloidal structures formed from Quillaja saponins, cholesterol and phospholipid. Addition of protein antigens to these matrices leads to the formation of ISCOMs. In this review we report on microscopic investigations of ISCOM matrices and ISCOMs as well as related colloidal structures, such as helices, worm-like micelles, ring-like micelles, and lamellae structures. We briefly outline the immunologic basis for the use of ISCOMs as vaccine delivery systems, and describe the various methods to form ISCOMs. Negative staining transmission electron micrographs of all colloidal structures are presented and described. On the basis of our microscopic investigations, different formation mechanisms of ISCOMS are discussed.

Hydration of lipid films with an aqueous solution of Quil A: a simple method for the preparation of immune-stimulating complexes.

Immune-stimulating complexes (ISCOMs) are stable colloidal complexes of the adjuvant Quil A, cholesterol and phospholipid, which are effective carriers for subunit vaccines. The techniques currently available for the preparation of ISCOMs from the constituent components are rather complex and are based on either centrifugation or dialysis. This note reports a new simple procedure for the preparation of ISCOM matrices based on hydration of a cholesterol/phospholipid film with an aqueous solution of Quil A. It is demonstrated that ISCOM matrices do not form in the absence of phospholipid when prepared by this method. Further, the ratio by weight of phospholipid to either cholesterol or Quil A must be greater than that required for preparation by either dialysis or centrifugation. Photon correlation spectroscopy, negative stain transmission electron microscopy and centrifugation through a sucrose gradient demonstrate that ISCOM matrices can be prepared from cholesterol/lipid films by hydration with an aqueous solution of Quil A when the ratio of phospholipid:cholesterol:Quil A by weight is 6:1:4, respectively. Lower ratios of phospholipid:cholesterol reduce the efficiency of ISCOM formation while higher ratios produce systems containing a mixture of ISCOMs together with liposomes.

Direct biophysical characterization of human apolipoprotein A-1 in ISCOMs.

Human apolipoprotein A-1 was formulated in "Immune Stimulating Complexes" (ISCOMs). The structure of the protein in ISCOMs was examined directly using several biophysical techniques including Fourier transform infrared (FTIR) spectroscopy, near UV circular dichroism (CD), and fluorescence spectroscopy. Amide I FTIR data indicate that human apolipoprotein A-1 displays a slightly increased alpha-helical content after its incorporation into ISCOMs. Near UV CD and tryptophan fluorescence data suggest that association with ISCOMs results in the tryptophan residues of the protein experiencing a relatively hydrophobic environment, motional restriction, and local electrostatic interactions. These observations are consistent with an increased order in the protein structure upon incorporation in ISCOMs. In addition, biomolecular interaction analysis (BIA), based on surface plasmon resonance (SPR) measurements, suggests that the binding affinity of human apolipoprotein A-1 to a monoclonal anti-human apolipoprotein A-1 antibody is moderately decreased (by 20%) after its incorporation into ISCOMs. This study demonstrates that these biophysical techniques can be used to noninvasively monitor integrity of or changes in secondary and tertiary structure of proteins within the ISCOM particles without the need for protein extraction.

[Iscom (Immuno Stimulating Complex)-vaccine of equine influenza virus--transmission electron microscopic investigation and literature review]. / Iscom (Immuno Stimulating Complex)-Vakzine des equinen Influenza-Virus--transmissionselektronenmikroskopische Chargenüberwachung und Literaturübersicht.

Vaccines on the base of immunostimulating complexes are very rare in human and veterinary practice. Until now, Iscom vaccines mainly have been developed for scientific experimental investigations. Synthesis and preparation of Iscom vaccines, mainly basing on the reviewed literature, as well as electron microscopical investigations of Iscom structures and the monitoring of vaccine fractions of Iscoms are described. The equine influenza Iscom vaccine, developed by the Mallinckrodt Veterinary GmbH, is one of the first commercial Iscom vaccine used in veterinary medicine. In comparison with other commercially used vaccines, depending on the high level of antigen presentation of Iscom structures, a ten times higher antibody response is to be expected by the use of Iscom vaccines.

Preparation and characterization of immunostimulating complexes (ISCOMs) of Japanese encephalitis virus.

ISCOMs (immunostimulating complexes) were prepared from envelope glycoprotein (Egp) of Japanese encephalitis (JE) virus. ISCOMs showed a single band of the viral Egp in SDS-PAGE, which reacted with polyclonal and monoclonal antibody (MAb) raised against Egp. Comparison between the epitopes exposed on JE virion and JE ISCOMs, by antigen capture ELISA, utilizing a panel of domain-specific MAbs, revealed identical epitopes exposed on the Egp incorporated in ISCOMs and the whole virion. Electron micrographs of ISCOMs showed spherical cage-like structures of 35 nm. ISCOMs with Egp were good immunogenes, which stimulated high titres of neutralizing antibodies, both in mice and rabbits.

Immunity against Yersinia enterocolitica by vaccination with Yersinia HSP60 immunostimulating complexes or Yersinia HSP60 plus interleukin-12.

Microbial heat shock proteins (HSP) are dominant antigens for the host immune response. Because of the high sequence homology between mammalian and microbial HSP, their value as component of a subunit vaccine has been the subject of controversy. Previous work from this laboratory, however, demonstrated for the first time that the adoptive transfer of HSP60-reactive CD4+ alphabeta T-cell clones confers protection against bacterial infection in mice but does not induce autoimmunity. In the present study, we have therefore evaluated the potential role of Yersinia HSP60 (Y-HSP60) as a vaccine in the Yersinia enterocolitica mouse infection model. For this purpose, immunostimulating complexes (ISCOM) which included Y-HSP60 were constructed. Parenteral administration of this vaccine induced high Y-HSP60-specific serum antibody responses as well as T-cell responses. This reaction was parallelled by immunity against a lethal challenge with Y. enterocolitica. In contrast, mucosal application of Y-HSP60-ISCOM failed to induce systemic Y-HSP60-specific T-cell responses and thus failed to induce immunity against yersiniae. Likewise, vaccination with purified recombinant Y-HSP60 induced antibody responses but only weak T-cell responses. Therefore, this vaccination protocol was not protective. However, when interleukin-12 was used as an adjuvant, purified Y-HSP60 induced significant Y-HSP60-specific T-cell responses and thus induced protection against subsequent challenge with yersiniae. These studies suggest that (i) microbial HSP might be promising candidates for the design of subunit vaccines and (ii) interleukin-12 is an efficient alternative adjuvant to ISCOM particles for induction of protective CD4 Th1-cell-dependent immune responses against bacterial pathogens.

Immunogenicity of influenza and HSV-1 mixed antigen ISCOMs in mice.

Immunostimulating complexes (ISCOMs) were prepared with mixtures of antigens from influenza A virus (A/PR/8/34 or A/Sichuan/2/87) and herpes simplex virus type 1 (HSV-1), and were characterised by enzyme linked immunosorbent assay (ELISA) and electron microscopy using double-labelling immunogold techniques employing monoclonal antibodies to influenza or HSV-1 glycoproteins. The immunogenicity of the mixed antigen ISCOMs was evaluated in mice, following administration by the subcutaneous route, by measuring the total and subclass IgG antibody responses. Protection of these animals against challenge with live influenza A/Sichuan virus or live HSV-1, was compared with that induced by immunization with aqueous mixed antigen preparations. It was found that relatively high humoral responses to both influenza and HSV antigens, and increased levels of protection to both influenza and HSV viruses were elicited in mice receiving the mixed antigen ISCOM preparation compared to those observed in animals receiving the mixed aqueous subunit preparation. The findings also indicate that antigens from more than one virus can be used in an ISCOM formulation to produce immunity and protection.

Delivery of pseudorabies virus envelope antigens enclosed in immunostimulating complexes (ISCOMs); elicitation of neutralizing antibody and lymphoproliferative responses in swine and protection in mice.

An experimental subunit vaccine that consisted of pseudorabies virus (PRV) envelope glycoproteins enclosed into immunostimulating complexes (PRVenv/ISCOM) was constructed, and evaluated in DBA/2 mice and inbred swine of the SLA haplotype c/c. Two to three weeks after the first vaccine dose, specific anti-PRV antibodies could be demonstrated by ELISA or virus neutralization (VN) assays. Booster PRVenv/ISCOM vaccinations resulted in rapid and significant increases in antibody titres in both mice and swine. In addition, a week after receiving the third PRVenv/ISCOM vaccine dose swine peripheral blood mononuclear cells exhibited significant proliferation in response to stimulation with PRV virion antigen. Moreover, two doses of vaccine sufficed to protect mice fully against lethal virus challenge. Therefore, the data presented here support the ISCOM as a viable antigen delivery system for subunit PRV vaccines.

Immune responses and protective effect in mice vaccinated orally with surface sporozoite protein of Eimeria falciformis in ISCOMs.

Immunostimulating complexes (ISCOMs) were built after treatment of a purified surface protein from Eimeria falciformis sporozoites with a palmitic acid derivation, leading to a high ratio (33-64%) of P27 incorporation in these cage-like structures. P27 kept its antigenicity after incorporation in ISCOMs, which induced, after iterative intubations by the oral route to groups of mice, a systemic IgG response, a local IgA response, and a local enhanced cellular response as demonstrated by lymphoproliferation of mesenteric lymph node cells upon in vitro stimulation with antigen. This immunization (120 micrograms in six oral doses at 2-day intervals) afforded mice a partial protection (60%) against a subsequent 400 oocyst challenge. The reduction in daily oocyst excretion was corroborated by significantly different weight losses between immunized and control mice on days 9 and 10 postinfection and the subsequent death of these control mice. These observations provide the first application of ISCOMs to parasitic intestinal diseases.

Antigenicity and immunogenicity of experimental equine influenza ISCOM vaccines.

A comparison of the antigenicity and immunogenicity of ISCOM vaccines prepared from equine influenza viruses H3N8 and H7N7 was made with inactivated whole-virus vaccines containing equivalent amounts of virus haemagglutinin. ISCOMs stimulated superior antibody responses in terms of both amount and duration. As with conventional whole-virus vaccines, the levels of antibody to virus haemagglutinin induced by ISCOMs correlated with protection.

Iscom immunization with synthetic peptides representing measles virus hemagglutinin.

Synthetic peptides representing the measles virus (MV) hemagglutinin (MVH) were incorporated into immunostimulating complexes (iscoms) and used for immunization of rabbits. Nine regions of MVH were selected on the basis of hydropathy and antigenicity profiles, by use of the known primary structure of MVH. Six linear and three branched types of peptides were synthesized and conjugated to palmitic acid before incorporation into the iscom structure. Five of the anti-peptide sera reacted by ELISA with the homologous peptide but did not react with MV in the native state, indicating that either the selected sites are not represented on the surface of MV, or they could be a conformational epitope. Human-anti MV and rabbit anti-MV did not react with the peptides.