Dendritic cells, loaded with recombinant bacteria expressing tumor antigens, induce a protective tumor-specific response.

Dendritic cells (DCs) are considered the most potent antigen-presenting cells and probably the only ones able to prime naive T cells. Indeed, DCs are distributed in tissues that interface the external environment, where they act as sentinels for incoming bacteria, viruses, and fungi. We have previously analyzed the capacity of DCs to interact with bacteria, and we have shown that bacteria can act as "Trojan horses," delivering heterologous proteins to DCs in a processed form that allows extremely efficient loading of both MHC class I and class II molecules. In this study, we have optimized the usage of recombinant bacteria as an antigen delivery system for DCs, with the aim to develop a new DC vaccination strategy in antitumor immunity. We have focused on a low immunogenic antigen, the tyrosinase-related protein-2 (Trp-2), a self-antigen expressed in mouse and human melanoma for which induction of antitumor immunity has proven to be very ineffective. We have given mice injections of either Trp-2/recombinant bacteria-loaded DCs or with bacteria alone engineered to express the Trp-2 melanoma antigen. We have shown that only DCs loaded with recombinant bacteria, but not with wild-type bacteria, were able to induce Trp-2-specific CTLs and immunity against the B16 tumor. Immunity was obtained in experiments of tumor vaccination as well as in experiments of tumor therapy. When therapy with bacteria-loaded DCs was performed in B16 tumor-bearing mice, 60% of the treated mice were tumor free 2 months after the initial tumor growth.

Dendritic cells express tight junction proteins and penetrate gut epithelial monolayers to sample bacteria.

Penetration of the gut mucosa by pathogens expressing invasion genes is believed to occur mainly through specialized epithelial cells, called M cells, that are located in Peyer's patches. However, Salmonella typhimurium that are deficient in invasion genes encoded by Salmonella pathogenicity island 1 (SPI1) are still able to reach the spleen after oral administration. This suggests the existence of an alternative route for bacterial invasion, one that is independent of M cells. We report here a new mechanism for bacterial uptake in the mucosa tissues that is mediated by dendritic cells (DCs). DCs open the tight junctions between epithelial cells, send dendrites outside the epithelium and directly sample bacteria. In addition, because DCs express tight-junction proteins such as occludin, claudin 1 and zonula occludens 1, the integrity of the epithelial barrier is preserved.

Dendritic cells shuttle microbes across gut epithelial monolayers.

Understanding the mechanisms governing the type of induced immune response after microbial invasion, could be of crucial importance for the rational design of a bacteria-based vaccine. Targeting a vaccine directly to dendritic cells (DCs), which are considered the most powerful antigen presenting cells, could be extremely effective. Here we describe that CD11b+CD8alpha- dendritic cells are involved in the direct bacterial uptake across mucosal surfaces. DCs are widely spread in the lamina propria of the gut and are recruited at the site of infection. DCs open the tight junctions between epithelial cells, send dendrites outside of the epithelium and sample bacteria. Moreover, the integrity of the epithelial barrier is preserved because DCs express tight junction proteins, such as occludin, claudin 1 and Junctional Adhesion Molecule (JAM) and can establish tight junctions-like structures with neighbouring epithelial cells.

Fas engagement induces the maturation of dendritic cells (DCs), the release of interleukin (IL)-1beta, and the production of interferon gamma in the absence of IL-12 during DC-T cell cognate interaction: a new role for Fas ligand in inflammatory responses.

Ligation of the Fas (CD95) receptor leads to an apoptotic death signal in T cells, B cells, and macrophages. However, human CD34(+)-derived dendritic cells (DCs) and mouse DCs, regardless of their maturation state, are not susceptible to Fas-induced cell death. This resistance correlates with the constitutive expression of the Fas-associated death domain-like IL-1beta-converting enzyme (FLICE)-inhibitory protein (FLIP) ligand. We demonstrate a new role of Fas in DC physiology. Engagement of Fas on immature DCs by Fas ligand (FasL) or by anti-Fas antibodies induces the phenotypical and functional maturation of primary DCs. Fas-activated DCs upregulate the expression of the major histocompatibility complex class II, B7, and DC-lysosome-associated membrane protein (DC-LAMP) molecules and secrete proinflammatory cytokines, in particular interleukin (IL)-1beta and tumor necrosis factor alpha. Mature DCs, if exposed to FasL, produce even higher amounts of IL-1beta. Importantly, it is possible to reduce the production of IL-1beta and interferon (IFN)-gamma during DC-T cell interaction by blocking the coupling of Fas-FasL with a Fas competitor. Finally, during cognate DC-T cell recognition, IL-12 (p70) could not be detected at early or late time points, indicating that Fas-induced, IFN-gamma secretion is independent of IL-12.

Glutamate synthase: identification of the NADPH-binding site by site-directed mutagenesis.

To contribute to the understanding of glutamate synthase and of beta subunit-like proteins, which have been detected by sequence analyses, we identified the NADPH-binding site out of the two potential ADP-binding regions found in the beta subunit. The substitution of an alanyl residue for G298 of the beta subunit of Azospirillum brasilense glutamate synthase (the second glycine in the GXGXXA fingerprint of the postulated NADPH-binding site) yielded a protein species in which the flavin environment and properties are unaltered. On the contrary, the binding of the pyridine nucleotide substrate is significantly perturbed demonstrating that the C-terminal potential ADP-binding fold of the beta subunit is indeed the NADPH-binding site of the enzyme. The major effect of the G298A substitution in the GltS beta subunit consists of an approximately 10-fold decrease of the affinity of the enzyme for pyridine nucleotides with little or no effect on the rate of the enzyme reduction by NADPH. By combining kinetic measurements and absorbance-monitored equilibrium titrations of the G298A-beta subunit mutant, we conclude that also the positioning of its nicotinamide portion into the active site is altered thus preventing the formation of a stable charge-transfer complex between reduced FAD and NADP(+). During the course of this work, the Azospirillum DNA regions flanking the gltD and gltB genes, the genes encoding the GltS beta and alpha subunits, respectively, were sequenced and analyzed. Although the Azospirillum GltS is similar to the enzyme of other bacteria, it appears that the corresponding genes differ with respect to their arrangement in the chromosome and to the composition of the glt operon: no genes corresponding to E. coli and Klebsiella aerogenes gltF or to Bacillus subtilis gltC, encoding regulatory proteins, are found in the DNA regions adjacent to that containing gltD and gltB genes in Azospirillum. Further studies are needed to determine if these findings also imply differences in the regulation of the glt genes expression in Azospirillum (a nitrogen-fixing bacterium) with respect to enteric bacteria.