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Assessment of rabies virus (RABV) neutralizing antibodies in subjects vaccinated or injected with anti-RABV immunoglobulins is central in determination of rabies protection. The rapid fluorescent focus inhibition test (RFFIT) is used for assessment of anti-RABV activity in serum. The current anti-RABV polyclonal preparations on the market pose difficulties in production and vary in quality. RABV neutralizing monoclonal antibodies (MAbs) are being evaluated as replacements. Different anti-RABV MAbs may neutralize different RABV isolates, thus two or more MAbs directed against different epitopes on the RABV glycoprotein are needed. It is therefore important to ensure neutralizing activity against all RABV isolates in sera of subjects injected with an anti-RABV MAb product consisting of two or more MAbs. The RFFIT, utilizing CVS-11 as challenge virus, cannot discriminate between the activities of different anti-RABV MAbs. We developed and validated two RFFIT methods enabling specific assessment of two different anti-RABV MAbs (CR57 and CR4098) in using two mutant CVS-11 strains resistant to either CR57 or CR4098 neutralization. The validation results demonstrate that both RFFIT assays using MAb resistant RABV are precise, accurate, linear, specific, and stable within the linear range of 0.025 IU/mL to 1.0 IU/mL. This method design can, therefore, be used to determine MAb specific anti-RABV activity in human serum samples.

To investigate the immunological function of cells in normal and diseased skin under conditions approximating the in vivo situation, it is necessary to maintain the structural integrity of the tissue. To achieve this, freshly isolated skin has to be cultured ex vivo, or an in vitro-constructed complete skin equivalent may be used. Different skin organ culture systems have been described. Basically two systems prevail: submerged or air-exposed skin organ cultures. The former model has been used for measuring cytokine secretion by skin cells in the medium, and the latter to study the expression of cell membrane proteins in situ and the kinetics of epidermal Langerhans cells. Here we present a modified ex vivo skin organ culture system which approaches the in vivo situation by maintaining the normal skin architecture without spontaneous induction of the regenerative maturation markers. This method allowed the expression of cell membrane proteins in situ to be measured, and the cytokine secretion by skin cells in the culture medium to be quantitated in the same experiment. In this system, both general and specific stimuli (LPS and IL-1beta) upregulated the expression of skin-derived cytokines IL-8 and IL-6 in the medium and different markers (ICAM-1, CD40 and CD86) on cells in the tissue in a 24-hour culture-formed. Elevation of both cytokine and cell marker expression could be blocked by dexamethasone and by IL-1ra which acts specifically on IL-1beta-mediated responses. The system presented here is both quick and simple and can be used as a model to study the behaviour of skin cells in their natural microenvironment.

Previously, we have shown the potency of recombinant Adenovirus serotype 35 viral vaccines (rAd35) to induce strong immune response against the circumsporozoite protein (CS) of the plasmodium parasite. To further optimize immunogenicity of Ad35-based malaria vaccines we formulated rAd35.CS vaccine with aluminium phosphate adjuvant (AlPO 4). In contrast to the conventional protein based vaccines no absorption to aluminium adjuvant was observed and rAd35 viral in vitro infectivity in mammalian cells was preserved. Immunization with Ad35.CS formulated with AlPO 4 resulted in significantly higher CS specific T and B cell responses in mice upon either single or prime-boost vaccination regimens as compared to rAd35.CS alone. With these results we report for the first time the feasibility of using an AlPO 4 adjuvant to increase the potency of a live adenovirus serotype 35-based vaccine.

Previous studies have shown that the immunogenicity of rodent malaria parasite-derived circumsporozoite protein (CS) can be improved by deleting the glycosyl-phosphatidyl-inositol (GPI) signal sequence. To study whether GPI signal sequence deletion would also improve immunogenicity of CS derived from the major plasmodium species causing mortality in humans (P. falciparum), we tested different variants of theP. falciparumCS protein in the context of a live vector-based vaccine carrier (rAd35). We demonstrate that deletion of the GPI signal sequence from CS did not result in altered expression or secretion. In contrast, cellular localization was clearly altered, which perhaps helps to explain the significant improvement of anti-CS antibody and T-cell responses observed in mice using deletion variants in the context of the rAd35 carrier. Our results show that rational design of antigens is warranted for further development of malaria vaccines.

Previous studies have shown that the immunogenicity of rodent malaria parasite-derived circumsporozoite protein (CS) can be improved by deleting the glycosyl-phosphatidyl-inositol (GPI) signal sequence. To study whether GPI signal sequence deletion would also improve immunogenicity of CS derived from the major plasmodium species causing mortality in humans ( P. falciparum), we tested different variants of the P. falciparum CS protein in the context of a live vector-based vaccine carrier (rAd35). We demonstrate that deletion of the GPI signal sequence from CS did not result in altered expression or secretion. In contrast, cellular localization was clearly altered, which perhaps helps to explain the significant improvement of anti-CS antibody and T-cell responses observed in mice using deletion variants in the context of the rAd35 carrier. Our results show that rational design of antigens is warranted for further development of malaria vaccines.