Intracellular signaling regulators can be concentrated into membrane-free, higher ordered protein assemblies to initiate protective responses during stress - a process known as phase transition. Here, we show that a phase transition of the Caenorhabditis elegans Toll/interleukin-1 receptor domain protein (TIR-1), an NAD+ glycohydrolase homologous to mammalian sterile alpha and TIR motif-containing 1 (SARM1), underlies p38 PMK-1 immune pathway activation in C. elegans intestinal epithelial cells. Through visualization of fluorescently labeled TIR-1/SARM1 protein, we demonstrate that physiologic stresses, both pathogen and non-pathogen, induce multimerization of TIR-1/SARM1 into visible puncta within intestinal epithelial cells. In vitro enzyme kinetic analyses revealed that, like mammalian SARM1, the NAD+ glycohydrolase activity of C. elegans TIR-1 is dramatically potentiated by protein oligomerization and a phase transition. Accordingly, C. elegans with genetic mutations that specifically block either multimerization or the NAD+ glycohydrolase activity of TIR-1/SARM1 fail to induce p38 PMK phosphorylation, are unable to increase immune effector expression, and are dramatically susceptible to bacterial infection. Finally, we demonstrate that a loss-of-function mutation in nhr-8, which alters cholesterol metabolism and is used to study conditions of sterol deficiency, causes TIR-1/SARM1 to oligomerize into puncta in intestinal epithelial cells. Cholesterol scarcity increases p38 PMK-1 phosphorylation, primes immune effector induction in a manner that requires TIR-1/SARM1 oligomerization and its intrinsic NAD+ glycohydrolase activity, and reduces pathogen accumulation in the intestine during a subsequent infection. These data reveal a new adaptive response that allows a metazoan host to anticipate pathogen threats during cholesterol deprivation, a time of relative susceptibility to infection. Thus, a phase transition of TIR-1/SARM1 as a prerequisite for its NAD+ glycohydrolase activity is strongly conserved across millions of years of evolution and is essential for diverse physiological processes in multiple cell types.
Keywords: TIR-1/SARM1; caenorhabditis elegans; cholesterol; immunology; infectious disease; inflammation; intestinal epithelial immunity; microbiology; p38 pathway; phase transition; pseudomonas aeruginosa.
From worms to humans, animals have developed various strategies – including immune defences – to shield themselves from disease-causing microbes. A type of roundworm, called C. elegans, lives in environments rich in microbes, so it needs effective immune defences to protect itself. The roundworms share a key regulatory pathway with mammals that helps to control their immune responses. This so-called p38 pathway relies on proteins that interact with each other to activate protective immune defences. Proteins contain different regions or domains that can give them a certain function. For example, proteins with a region called TIR play important roles in immune defences in both animals and plants. One such protein, called SARM1, is unique among animal and plant proteins in that it is an enzyme, which cleaves an important metabolite in the cell. In C. elegans, the SARM1 homolog, TIR-1, controls the p38 pathway during infection, but how TIR-1 activates it is unclear. To find out more, Peterson, Icso et al. modified C. elegans to generate a fluorescent form of TIR-1 and infected the worms with bacteria. Imaging techniques revealed that infection caused TIR-1 in gut cells to cluster into organized structures, which increases the enzymatic activity of the protein to activate the p38 immune pathway. Moreover, stress situations, such as cholesterol nutrient withdrawal, activated the p38 pathway in the same way. This adaptive stress response allows the animal to defend itself against pathogen threats during times, when they are most susceptible to infections. Cells in the gut provide a primary line of defence against infectious bacteria and are important for maintaining a healthy gut immune system. When the mechanisms for pathogen sensing and immune maintenance are disrupted, it can lead to inflammation and higher risk of infection. Peterson, Icso et al. show how a key regulator of gut immunity, TIR-1, provides protection in C. elegans, which may suggest that SARM1 could have a similar role in mammals.
© 2022, Peterson et al.