Single-cell resolution of the adult zebrafish intestine under conventional conditions and in response to an acute Vibrio cholerae infection.

Vibrio cholerae is an aquatic bacterium that causes severe and potentially deadly diarrheal disease. Despite the impact on global health, our understanding of host mucosal responses to Vibrio remains limited, highlighting a knowledge gap critical for the development of effective prevention and treatment strategies. Using a natural infection model, we combine physiological and single-cell transcriptomic studies to characterize conventionally reared adult zebrafish guts and guts challenged with Vibrio. We demonstrate that Vibrio causes a mild mucosal immune response characterized by T cell activation and enhanced antigen capture; Vibrio suppresses host interferon signaling; and ectopic activation of interferon alters the course of infection. We show that the adult zebrafish gut shares similarities with mammalian counterparts, including the presence of Best4+ cells, tuft cells, and a population of basal cycling cells. These findings provide important insights into host-pathogen interactions and emphasize the utility of zebrafish as a natural model of Vibrio infection.

Immune regulation of intestinal-stem-cell function in Drosophila.

Intestinal progenitor cells integrate signals from their niche, and the gut lumen, to divide and differentiate at a rate that maintains an epithelial barrier to microbial invasion of the host interior. Despite the importance of evolutionarily conserved innate immune defenses to maintain stable host-microbe relationships, we know little about contributions of stem-cell immunity to gut homeostasis. We used Drosophila to determine the consequences of intestinal-stem-cell immune activity for epithelial homeostasis. We showed that loss of stem-cell immunity greatly impacted growth and renewal in the adult gut. In particular, we found that inhibition of stem-cell immunity impeded progenitor-cell growth and differentiation, leading to a gradual loss of stem-cell numbers with age and an impaired differentiation of mature enteroendocrine cells. Our results highlight the importance of immune signaling in stem cells for epithelial function in the adult gut.

A cell atlas of microbe-responsive processes in the zebrafish intestine.

Gut microbial products direct growth, differentiation, and development in animal hosts. However, we lack system-wide understanding of cell-specific responses to the microbiome. We profiled cell transcriptomes from the intestine, and associated tissue, of zebrafish larvae raised in the presence or absence of a microbiome. We uncovered extensive cellular heterogeneity in the conventional zebrafish intestinal epithelium, including previously undescribed cell types with known mammalian homologs. By comparing conventional to germ-free profiles, we mapped microbial impacts on transcriptional activity in each cell population. We revealed intricate degrees of cellular specificity in host responses to the microbiome that included regulatory effects on patterning and on metabolic and immune activity. For example, we showed that the absence of microbes hindered pro-angiogenic signals in the developing vasculature, causing impaired intestinal vascularization. Our work provides a high-resolution atlas of intestinal cellular composition in the developing fish gut and details the effects of the microbiome on each cell type.

Imaging flow cytometry and confocal microscopy-based examination of F-actin and phosphoinositide dynamics during leukocyte immune-type receptor-mediated phagocytic events.

Cells of the innate immune system rapidly detect and eliminate invading microbes using surface-expressed immunoregulatory receptors that translate extracellular binding events into potent effector responses. Channel catfish (Ictalurus punctatus) leukocyte immune-type receptors (IpLITRs) are a family of immunoregulatory proteins that have been shown to regulate several innate immune cell effector responses including the phagocytic process. The mechanisms by which these receptors regulate phagocytosis are not entirely understood but we have previously shown that different IpLITR-types use ITAM-dependent as well as ITAM-independent pathways for controlling target engulfment. The main objective of this study was to develop and use imaging flow cytometry and confocal microscopy-based assays to further examine both F-actin and phosphoinositide dynamics that occur during the different IpLITR-mediated phagocytic pathways. Results show that the ITAM-dependent IpLITR-induced phagocytic response promotes canonical changes in F-actin polymerization and PI(4,5)P2 redistributions. However, the ITAM-independent IpLITR phagocytic response induced unique patterns of F-actin and PI(4,5)P2 redistributions, which are likely due to its ability to regulate alternative signaling pathways. Additionally, both IpLITR-induced phagocytic pathways induced target internalization into PI(3)P-enriched phagosomes indicative of a maturing phagosome compartment. Overall, this imaging-based platform can be further applied to monitor the recruitment and distribution of signaling molecules during IpLITR-mediated phagocytic processes and may serve as a useful strategy for functional examinations of other immunoregulatory receptor-types in fish.

Teleost leukocyte immune-type receptors activate distinct phagocytic modes for target acquisition and engulfment.

Channel catfish (Ictalurus punctatus) IpLITRs belong to the Ig superfamily and regulate innate immune cell effector responses. This study tested the hypothesis that ITAM-dependent and ITAM-independent phagocytic pathways are engaged by different subtypes of the IpLITR family. When stably expressed in RBL-2H3 cells, the ITAM-containing fusion-construct IpLITR 2.6b/IpFcRγ-L stimulated phagocytic responses that were abrogated at suboptimal incubation temperatures and by pharmacological inhibitors of the classic signaling components of the mammalian FcR-dependent phagocytic pathway. Interestingly, the ITIM-containing receptor IpLITR 1.1b also induced phagocytosis through an actin-dependent mechanism, but this process was insensitive to the pharmacological inhibitors tested and remained functional at temperatures as low as 22°C. The IpLITR 1.1b also displayed a unique target-acquisition phenotype that consisted of complex, membranous protrusions, which captured targets in phagocytic cup-like structures but often failed to completely engulf targets. Taken together, these findings suggest that teleost immunoregulatory receptors that associate with ITAM-containing adaptors can engage conserved components of the phagocytic machinery to engulf extracellular targets akin to the classic FcR-mediated response in mammals. Alternatively, IpLITR 1.1b displays a stalled phagocytic phenotype that is likely dependent on the selective recruitment of the minimal molecular machinery required for target capture but results in incomplete target engulfment. Overall, this study demonstrates that IpLITRs can selectively engage distinct components of the phagocytic process and provides important new information regarding the target acquisition as well as internalization mechanisms involved in controlling phagocytic responses across vertebrates.