Intestinal Paneth cells limit bacterial invasion by secreting antimicrobial proteins including lysozyme. However, invasive pathogens can disrupt the Golgi apparatus, interfering with secretion and compromising intestinal antimicrobial defense. Here we show that during bacterial infection, lysozyme is rerouted through secretory autophagy, an autophagy-based alternative secretion pathway. Secretory autophagy was triggered in Paneth cells by bacteria-induced endoplasmic reticulum (ER) stress, required extrinsic signals from innate lymphoid cells, and limited bacterial dissemination. Secretory autophagy was disrupted in Paneth cells of mice harboring a mutation in autophagy gene Atg16L1 that confers increased risk for Crohn’s disease in humans. Our findings identify a role for secretory autophagy in intestinal defense and suggest why Crohn’s disease is associated with genetic mutations that impact both the ER stress response and autophagy.
Highlights d Skin microbiota induces epidermal RELMa, which kills bacteria via membrane disruption d RELMa-deficient mice have altered skin microbiota and are more susceptible to infection d Dietary vitamin A is required for RELMa expression d RELMa is required for vitamin-A-dependent resistance to skin infection
TMF/ARA160 is a Golgi-associated protein to which several cellular activities have been attributed. These include, trafficking of Golgi-derived vesicles and E3 ubiquitin ligase activity. Here we show that TMF/ARA160 is required for the onset of key processes which underlie the development of mature sperm in mammals. TMF/ARA160 is highly expressed in specific spermatogenic stages. While the protein is not detected in the spermatogenic progenitor cells - spermatogonia, it accumulates in the Golgi of spermatocytes and spermatids but then disappears and is absent from spermatozoa and epididymal sperm cells. Mice that are homozygous null for TMF develop normally are healthy and the females are fertile. However, the males are sterile and their spermatids suffer from several developmental defects. They lack homing of Golgi-derived proacrosomal vesicles to the perinuclear surface, resulting in spermatozoa and epididymal sperm cells which lack acrosome. In a later developmental stage, the cytoplasm is not properly removed, thus resulting in spermatids which bare the nucleus with tightly packed DNA, surrounded by a cytoplasm. Finally, the spermatozoa of TMF(-/-) mice also suffer from misshapen heads, tails coiling around the sperm heads, and lack of motility. Taken together our findings portray TMF/ARA160 as a key regulator which is essential for the onset of key events in the differentiation and maturation of mammalian sperm and whose absence severely compromises their ability to fertilize ova.
Significance
Our data demonstrate that a knockout of a single gene (tmf1) leads to the beneficial reprogramming of the gut resident microbiota. This reprogramming results in a diminished susceptibility of the genetically modified animals to induced colitis. Notably, the reprogrammed bacterial profile is transmissible, thereby conferring altered microbiome and reduced susceptibility to induced colitis in wild-type mice, when cohoused. Our findings open previously unreported avenues for unraveling regulatory factors that affect the gut homeostasis and mammalian sensitivity to the onset of inflammatory bowel diseases.
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