Stéphane Demotz

Protection against Cutaneous Leishmaniasis in Outbred Vervet Monkeys, Using a Recombinant Histone H1 Antigen

Infection with Leishmania major parasites results in the development of cutaneous ulcerative lesions on the skin. We investigated the protective potential of a single, recombinant histone H1 antigen against cutaneous leishmaniasis in an outbred population of vervet monkeys, using Montanide adjuvant. Protection was assessed by challenging the animals with a mixture of vector sand fly salivary-gland lysate and a low dose of in vitro-derived parasites, thus more closely mimicking natural infection induced by L. major. The course of infection in immunized monkeys was compared with that of animals that had healed from a primary infection and were immune. The monkeys immunized with recombinant histone H1 showed a reduced development of lesion size, compared with controls. Our study therefore illustrates the potential use of histone H1 as a vaccine candidate against cutaneous leishmaniasis in humans.

Native-like, long synthetic peptides as components of sub-unit vaccines: practical and theoretical considerations for their use in humans.

Vaccines have been used as a successful tool in medicine by way of controlling many major diseases. In spite of this, vaccines today represent only a handful of all infectious diseases. Therefore, there is a pressing demand for improvements of existing vaccines with particular reference to higher efficacy and undisputed safety profiles. To this effect, as an alternative to available vaccine technologies, there has been a drive to develop vaccine candidate polypeptides by chemical synthesis. In our laboratory, we have recently developed a technology to manufacture long synthetic peptides of up to 130 residues, which are correctly folded and biologically active. This paper discusses the advantages of the molecularly defined, long synthetic peptide approach in the context of vaccine design, development and use in human vaccination.

Biotinylated Synthetic Chemokines: Their Use for the Development of Nonradioactive Whole-Cell Binding Assays

A chemokine binding assay on whole cells was developed using biotinylated synthetic CCL22 as a model ligand. CCL22 analogues were produced by a chemical route, resulting in > 97% homogeneous and defined polypeptides. First, the 5 biotinylated CCL22 analogues synthesized were captured by agarose-immobilized streptavidin, indicating that the biotin molecules introduced in positions G1, K27, K49, K61, and K66 of CCL22 were accessible for binding. Then, it was established using a migration assay that the biotinylated chemokines were at least as biologically active as the unmodified CCL22 form. Subsequently, the biotinylated chemokines were evaluated in an FACS-based whole-cell binding assay. Surprisingly, only the CCL22 analogue with the biotin in position K66 constituted a suitable staining reagent for CCR4-positive cells. Finally, binding characteristics and reproducibility of the binding assay were outlined for the CCL22 analogue with the biotin in position K66. These results exemplified that biotinylated synthetic chemokines constitute promising ligands for the development of chemokine receptor-binding assays on whole cells, provided the position of the biotin moiety introduced along the sequence is adequately chosen. (Journal of Biomolecular Screening 2003:316-323)

Release of DR molecules from complexes with invariant chain through the formation of a C-terminal 25 kDa invariant chain fragment☆

To investigate how class II major histocompatibility complex (MHC) molecules are released from complexes with invariant chain (Ii), we studied a 25 kDa Ii fragment (p25) detected by Western blotting in affinity chromatographed DR preparations. The p25 species corresponds to the non-transmembrane, C-terminal Ii fragment 107-232. It was determined by gel filtration chromatography that the p25 fragment has a relative molecular mass (M(r)) of 46 kDa, indicating that this Ii fragment is present as dimers in B cell lysate. Two independent approaches were followed to demonstrate that generation of the p25 fragment takes place shortly before, or concomitantly to, loading of class II MHC molecules with antigen fragments. First, it was shown that a fraction of the p25 molecules is resistant to endoglycosidase H digestion, indicating that the p25 polypeptide can exit the endoplasmic reticulum (ER) and is transported at least to the cis-Golgi compartment. Second, treatment of class II MHC-positive B cells with leupeptin blocks the formation of p25, further indicating that this Ii fragment is generated in the endosomal compartment. The role of the p25 Ii species in the assembly of complexes between peptides and DR molecules was then investigated. While the p25 fragment was totally unable to prevent binding of a synthetic tetanus toxin peptide to DR molecules, the full-length Ii species (p33/35) effectively inhibited peptide binding, indicating that, by contrast with the p33/35 species, the p25 fragment does not occlude the peptide binding site of DR molecules. We concluded that the p25 fragment, which is produced by proteolytic cleavage at the N-terminal side of Methionine 107, has a decreased affinity for DR molecules as compared with the p33/35 species. Dissociation of the p25 fragment from DR molecules exposes the peptide binding site, which is thus made accessible for antigen fragments. This model of the complexes between DR and antigen fragments proposes that a stretch of Ii prevents peptide binding by occluding the peptide binding site without directly occupying it.

Presentation of Self-Peptides: Consequences for Self Nonself Discrimination and Allorecognition

For T cells, “self” is defined by the set of peptides presented on self MHC molecules at concentrations sufficient to trigger a T cell Response. A key feature of MHC molecules is their high degree of polymorphism and in the last years it has become increasingly clear that different allelic forms have different peptide specificities. Thus the set of self peptides presented (i.e., “self”) depends on the allelic form of MHC molecules. We want to discuss here the consequences of MHC polymorphism on presentation of self peptides.