Collaborative study for the validation of cell line assays for in-process toxicity and antigenicity testing of Clostridium septicum vaccine antigens - Part 2: Optimisation of cell line assays.

During the production of clostridial vaccines large numbers of mice are used for various in-process control tests. Replacement in vitro assays had been developed for the testing of the toxins and toxoids of several clostridial species, but none of these assays had been assessed in an international collaborative study. Under the common aegis of the European Partnership for Alternative Approaches to Animal Testing (EPAA) and of the European Directorate for the Quality of Medicines & HealthCare (EDQM), a project on clostridial vaccines for veterinary use was started as part of the EDQM-co-ordinated Biological Standardisation Programme (BSP). Within the framework of this project (coded BSP130) a collaborative study was organised to evaluate Vero cell-based alternative methods to the current mouse tests used to measure: i) the toxicity of Clostridium septicum toxin, ii) the absence of toxicity of C. septicum toxoid and iii) the antigenicity of C. septicum toxoid. The principal aims of the study were to determine the repeatability and reproducibility of the in vitro assays and to demonstrate concordance of the in vitro and current in vivo tests. The study results demonstrated good concordance, but the information gathered through the study (later on called Part 1) and the participants' workshop prompted the extension of the project in order to further optimise the in vitro protocols and improve their repeatability and reproducibility, which were comparable to but not better than those of the in vivo assays in Part 1. The 3 in vitro assays to be optimised in the extension of the BSP130 project were : i) the in vitro toxin neutralisation equivalence plus (TNE+), as a replacement for the in vivo minimum lethal dose (MLD) test for quantification of the toxicity of toxin; ii) the in vitro MLD, as a replacement for the in vivo MLD test for detection of residual toxicity associated with toxoid; iii) the in vitro total combining power (TCP), as a replacement for the in vivo TCP test for quantification of the antigenicity of toxoid. At this point, the Analytical Method Transfer Laboratory of Ceva-Phylaxia (Hungary), supported by the project management team, developed suitable SOPs for the 3 in vitro assays. These optimised methods were further assessed in BSP130 through a second international collaborative study (Part 2) aimed at defining repeatability and reproducibility in different laboratories and determining the levels of improvement compared with the original in vivo tests and the initial in vitro assays used in Part 1 of the project. Fourteen laboratories, comprising 4 public sector and 10 manufacturers' medicines control laboratories, from 11 countries participated in the collaborative Part 2 study, each testing 6 different C. septicum toxins and 6 C. septicum toxoids. Improved repeatability and reproducibility were observed for the optimised assays. The results of this study confirm the suitability of these assays for in-process control of C. septicum vaccines, with better repeatability and reproducibility than their in vivo equivalents. It is expected that, with appropriate minor changes and the use of relevant reagents, these optimised in vitro assays could be used not only for the assessment of C. septicum toxins and toxoids but for all cytotoxin-based clostridial antigens. The development and implementation of such in vitro assays would offer a great opportunity to significantly reduce animal usage, shorten the duration of QC test procedures and increase the precision of toxicity and antigenicity assays in clostridial veterinary vaccine in-process control. This would also provide more accurate and reproducible dosing of antigens in the final vaccine products, help to promote compendial acceptance and to proffer a basis for improved international harmonisation across this area of product testing.

Binding affinity independent contribution of peptide length to the stability of peptide-HLA-DR complexes in live antigen presenting cells.

The effect of peptide length on the stability of peptide-HLR-DR1 (DR1) complexes was analyzed using two peptide series of increasing length, each containing a 7mer core with five DR1-binding anchors, extended stepwise with Ala residues at the N- and C-terminus, respectively. The Ala extensions, although did not affect binding affinity, significantly increased the half lives of peptide-DR1 complexes (from 1.5 h up to 10 h) in live antigen presenting cells (APC). Flanking residues from position -2 to 0 and 8 to 11 were involved in the affinity-independent increase of complex stability. The shortest (8mer and 9mer) peptides, with in vivo half lives of <2.5 h, were unable to form stable complexes with DR1 in presence of HLA-DM (DM) molecules, and were poor competitors of antigen presentation. Longer peptides were resistant to DM-mediated unloading, and were efficient competitors of antigen presentation. Thus, DM appears to limit short peptides in establishing biologically relevant DR occupancy, despite their high binding affinity. In APC, stable complexes can form only with high affinity peptides of >9 residues, and the longevity of complexes seems to depend on full of occupation of the binding site.

Neonatal exposure of TCR BV8S2 transgenic mice to recombinant TCR BV8S2 results in reduced T cell proliferation and elevated antibody response to BV8S2, and increased severity of EAE.

Transgenic (Tg) mouse models are unique tools for investigating regulatory mechanisms of the immune system. Mice bearing a T cell receptor (TCR) BV8S2 transgene derived from an encephalitogenic T cell clone are highly susceptible to experimental autoimmune encephalomyelitis (EAE), a T cell-mediated neurological disorder. Although the pathogenesis of EAE is not yet fully understood, TCR-specific regulatory T cells seem to play a role in its remission and/or recovery process. In previous studies, we showed that immunization of BV8S2 Tg mice with recombinant BV8S2 protein induced TCR-specific T cells and protection against EAE, clearly indicating the persistence of a functional TCR regulatory network in spite of the highly skewed T cell repertoire. To further investigate the natural regulatory role of TCR-specific T cells, we evaluated the effect on EAE of inducing neonatal tolerance to heterologous (rat) and homologous BV8S2 proteins in Tg mice. Neonatal exposure to rat BV8S2 protein induced "split" tolerance, characterized by decreased T cell proliferation but increased antibody responses to both rat and mouse BV8S2 proteins that are known to be cross-reactive. When challenged as adults with an encephalitogenic emulsion, Tg mice tolerized with rat but not mouse BV8S2 protein developed more severe EAE compared to control mice. These results demonstrate that immunity to BV8S2 determinants in BV8S2 Tg mice is naturally induced and functions to limit the severity of EAE.

Glycoprotein B of Aujeszky's disease virus: topographical epitope mapping and epitope-specific antibody response.

A panel of 26 monoclonal antibodies (mAbs) against glycoprotein B (gB) of Aujeszky's disease (pseudorabies) virus (ADV), a glycoprotein complex consisting of three glycoproteins, gBa, gBb, and gBc, was produced by two research groups and was used for the topographical epitope mapping of gB. An epitope map was constructed in which the identified epitopes of gB were situated in 14 topologically distinct antigenic domains; ten antigenic domains represented by 22 mAbs were localized on gBc, while four antigenic domains represented by four mAbs resided on gBb of the gB complex. All the epitopes located on gBc appeared to be conformation-dependent, whereas all the epitopes on gBb were conformation-independent. The identified epitopes of gB were conserved among laboratory, vaccine and field ADV strains. Conformation-dependent epitopes were shown to contribute largely to the overall antibody response to gB in naturally infected swine and immunized mice. Moreover, it was found that most of the infected animals responded relatively weakly to the identified conformation-independent epitopes of gB, while a group of immunodominant epitopes that induced a strong antibody response was represented exclusively by conformation-dependent epitopes from different antigenic domains. The results clearly demonstrated that conformation-dependent epitopes of gBc play a crucial role in inducing the humoral immune response to gB of ADV during the natural infection of swine and immunization of mice. The application of mAbs of our panel as research and diagnostic tools is discussed.

Down-regulation of class II major histocompatibility complex molecules on antigen-presenting cells by antibody fragments.

Certain HLA class II-specific monoclonal antibodies (mAb) cause up to 90% decrease in the cell surface expression of class II molecules. This down-regulation is isotype-specific, i.e. DR-specific mAb do not affect the expression of DP and DQ molecules. However, antibodies binding to one DR allotype down-regulate both allotypes in heterozygous antigen-presenting cells (APC), indicating that the phenomenon is not a direct consequence of ligation. All down-regulating mAb identified recognize the first (peptide binding) domains of class II heterodimers, and strongly inhibit the activation of class II-restricted human T cells in vitro. Conversely, non-down-regulating mAb fail to inhibit T cell activation, and most of them (four out of five) recognize class II second domains. Down-regulating antibodies are cytotoxic for B lymphoblastoid cell lines and for a small proportion of normal activated B cells. Their F(ab')2 fragments mediate both down-regulation and cytotoxicity, whereas the monovalent Fab fragments are not cytotoxic, but retain the down-regulatory and T cell inhibitory properties. These findings raise the possibility of a class II major histocompatibility complex-specific, antibody-based immunosuppressive therapy without cytotoxic side effects.

Latent immunization to produce high-affinity monoclonal antibodies to progesterone.

A simple immunization method to obtain high-affinity monoclonal antibodies to progesterone is described in this article. The method is based on the theory of affinity maturation. A long interval between antigen priming and booster ("latent immunization") permits an undisturbed completion of affinity maturation, resulting in the accumulation of memory B lymphocytes with high-affinity Ig receptors, and consequently, in a higher rate of hybridoma clones producing high-affinity antibody after cell fusion. Antibodies obtained after hyperimmunization and latent immunization are compared in a homologous, direct, competitive ELISA. The average numbers of high-affinity antibodies per fusion were 1.3 and 5.7 in the hyperimmunized and latent immunized groups, respectively. There was no significant difference in the specificities between the two immunization groups.