Slater L. Clay scite author profile

Salmonella infection is a globally important cause of gastroenteritis and systemic disease, and is a useful tool to study immune responses in the intestine. Although mechanisms leading to immune responses against Salmonella have been extensively studied, questions remain about how bacteria travel from the intestinal mucosa to the mesenteric lymph nodes (MLN), a key site for antigen presentation. Here, we used a mouse model of infection with Salmonella enterica serovar Typhimurium (STM) to identify changes in intestinal immune cells induced during early infection. We then used fluorescently-labelled STM to identify interactions with immune cells, from the site of infection, through migration in lymph, to the MLN. We show that viable STM can be carried in the lymph by any subset of migrating dendritic cells, but not by macrophages. Moreover, approximately half of the STM in lymph are not associated with cells at all, and travel autonomously. Within the MLN, STM associates with dendritic cells and B cells, but predominantly with MLN-resident macrophages. In conclusion, we describe the routes used by STM to spread systemically in the period immediately after infection. This deeper understanding of the infection process could open new avenues for controlling it.

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Fusobacterium nucleatum drives a pro-inflammatory intestinal microenvironment through metabolite receptor-dependent modulation of IL-17 expression

Brennan

Clay

Lavoie

et al. 2021

Gut Microbes

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Regulatory T cells control the dynamic and site-specific polarization of total CD4 T cells following Salmonella infection

et al. 2020

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FoxP3+ regulatory T cells (Tregs) control inflammation and maintain mucosal homeostasis, but their functions during infection are poorly understood. Th1, Th2, and Th17 cells can be identified by master transcription factors (TFs) T-bet, GATA3, and RORγT; Tregs also express these TFs. While T-bet+ Tregs can selectively suppress Th1 cells, it is unclear whether distinct Treg populations can alter Th bias. To address this, we used Salmonella enterica serotype Typhimurium to induce nonlethal colitis. Following infection, we observed an early colonic Th17 response within total CD4 T cells, followed by a Th1 bias. The early Th17 response, which contains both Salmonella-specific and non-Salmonella-specific cells, parallels an increase in T-bet+ Tregs. Later, Th1 cells and RORγT+ Tregs dominate. This reciprocal dynamic may indicate that Tregs selectively suppress Th cells, shaping the immune response. Treg depletion 1–2 days post-infection shifted the early Th17 response to a Th1 bias; however, Treg depletion 6–7 days post-infection abrogated the Th1 bias. Thus, Tregs are necessary for the early Th17 response, and for a maximal Th1 response later. These data show that Tregs shape the overall tissue CD4 T cell response and highlight the potential for subpopulations of Tregs to be used in targeted therapeutic approaches.

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Slater L. Clay

Colorectal cancer: the facts in the case of the microbiota

Salmonella enterica Serovar Typhimurium Travels to Mesenteric Lymph Nodes Both with Host Cells and Autonomously

Fusobacterium nucleatum drives a pro-inflammatory intestinal microenvironment through metabolite receptor-dependent modulation of IL-17 expression

Regulatory T cells control the dynamic and site-specific polarization of total CD4 T cells following Salmonella infection

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