Engineering a Novel Bivalent Oral Vaccine against Enteric Fever.

Enteric fever is a major global healthcare issue caused largely by Salmonella enterica serovars Typhi and Paratyphi A. The objective of this study was to develop a novel, bivalent oral vaccine capable of protecting against both serovars. Our approach centred on genetically engineering the attenuated S. Typhi ZH9 strain, which has an excellent safety record in clinical trials, to introduce two S. Paratyphi A immunogenic elements: flagellin H:a and lipopolysaccharide (LPS) O:2. We first replaced the native S. Typhi fliC gene encoding flagellin with the highly homologous fliC gene from S. Paratyphi A using Xer-cise technology. Next, we replaced the S. Typhi rfbE gene encoding tyvelose epimerase with a spacer sequence to enable the sustained expression of O:2 LPS and prevent its conversion to O:9 through tyvelose epimerase activity. The resulting new strain, ZH9PA, incorporated these two genetic changes and exhibited comparable growth kinetics to the parental ZH9 strain. A formulation containing both ZH9 and ZH9PA strains together constitutes a new bivalent vaccine candidate that targets both S. Typhi and S. Paratyphi A antigens to address a major global healthcare gap for enteric fever prophylaxis. This vaccine is now being tested in a Phase I clinical trial (NCT04349553).

Cell-intrinsic regulation of murine dendritic cell function and survival by prereceptor amplification of glucocorticoid.

Although the inhibitory effects of therapeutic glucocorticoids (GCs) on dendritic cells (DCs) are well established, the roles of endogenous GCs in DC homeostasis are less clear. A critical element regulating endogenous GC concentrations involves local conversion of inactive substrates to active 11-hydroxyglucocorticoids, a reduction reaction catalyzed within the endoplasmic reticulum by an enzyme complex containing 11ß-hydroxysteroid dehydrogenase type 1 (11ßHSD1) and hexose-6-phosphate dehydrogenase (H6PDH). In this study, we found that this GC amplification pathway operates both constitutively and maximally in steady state murine DC populations and is unaffected by additional inflammatory stimuli. Under physiologic conditions, 11ßHSD1-H6PDH increases the sensitivity of plasmacytoid DCs (pDCs) to GC-induced apoptosis and restricts the survival of this population through a cell-intrinsic mechanism. Upon CpG activation, the effects of enzyme activity are overridden, with pDCs becoming resistant to GCs and fully competent to release type I interferon. CD8α(+) DCs are also highly proficient in amplifying GC levels, leading to impaired maturation following toll-like receptor-mediated signaling. Indeed, pharmacologic inhibition of 11ßHSD1 synergized with CpG to enhance specific T-cell responses following vaccination targeted to CD8α(+) DCs. In conclusion, amplification of endogenous GCs is a critical cell-autonomous mechanism for regulating the survival and functions of DCs in vivo.

Immune regulation by CTLA-4--relevance to autoimmune diabetes in a transgenic mouse model.

BACKGROUND: The importance of cytotoxic T lymphocyte antigen-4 (CTLA-4) in immune regulation is unquestioned, yet a precise understanding of which cells express it, and how it mediates immune inhibitory function, is lacking. Regulatory T cells are known to constitutively express CTLA-4 intracellularly, whereas conventional T cells require activation to trigger CTLA-4 expression. However comparative analysis of CTLA-4 trafficking in regulatory and conventional subsets has not been performed. METHODS: Here we assess CTLA-4 expression in antigen-specific conventional and regulatory cells responding to immunizing antigen in vivo and analyse the membrane trafficking of CTLA-4 using an in vitro recycling assay. We assess the expression of CTLA-4 on Treg infiltrating the pancreas in the DO11×RIP-mOVA diabetes model and the role of CTLA-4 in Treg function. RESULTS: Regulatory T cells show an enhanced capacity to traffic CTLA-4 following stimulation compared with conventional T cells. Treg infiltrating the pancreas in DO11×RIP-mOVA mice show high expression of CTLA-4. Furthermore CTLA-4-deficient Treg fail to control diabetes in an adoptive transfer model of diabetes, even in situations where they outnumber the disease-inducing conventional T cells. CONCLUSIONS: These data show that not only do regulatory T cells express higher levels of intracellular CTLA-4 than conventional T cells, but they also show an increased capacity to traffic CTLA-4 to the cell surface following stimulation. CTLA-4 is strongly upregulated in regulatory T cells infiltrating the target tissue in a mouse model of type 1 diabetes and expression of this protein is critical for effective regulation.