The model organism Caenorhabditis elegans mounts transcriptional defense responses against intestinal bacterial infections that elicit overlapping starvation and infection responses, the regulation of which is not well understood. Direct comparison of C. elegans that were starved or infected with Staphylococcus aureus revealed a large infection-specific transcriptional signature, which was almost completely abrogated by deletion of transcription factor hlh-30/TFEB, except for six genes including a flavin-containing monooxygenase (FMO) gene, fmo-2/FMO5. Deletion of fmo-2/FMO5 severely compromised infection survival, thus identifying the first FMO with innate immunity functions in animals. Moreover, fmo-2/FMO5 induction required the nuclear hormone receptor, NHR-49/PPAR-α, which controlled host defense cell non-autonomously. These findings reveal an infection-specific host response to S. aureus, identify HLH-30/TFEB as its main regulator, reveal FMOs as important innate immunity effectors in animals, and identify the mechanism of FMO regulation through NHR-49/PPAR-α during S. aureus infection, with implications for host defense and inflammation in higher organisms.
During bacterial infection, the host is confronted with multiple overlapping signals that are integrated at the organismal level to produce defensive host responses. How multiple infection signals are sensed by the host and how they elicit the transcription of host defense genes is much less understood at the whole-animal level than at the cellular level. The model organism Caenorhabditis elegans is known to mount transcriptional defense responses against intestinal bacterial infections that elicit overlapping starvation and infection responses, but the regulation of such responses is not well understood. Direct comparison of C. elegans that were starved or infected with Staphylococcus aureus revealed a large infection-specific transcriptional signature. This signature was almost completely abrogated by deletion of transcription factor hlh-30/TFEB, except for six genes including a flavin-containing monooxygenase (FMO) gene, fmo-2/FMO5. Deletion of fmo-2/FMO5 severely compromised infection survival, thus identifying the first FMO with innate immunity functions in animals. Moreover, the mechanism of fmo-2/FMO5 induction required the nuclear hormone receptor, NHR-49/PPAR-α, which induced fmo-2/FMO5 and host defense cell non-autonomously. These findings for the first time reveal an infection-specific host response to S. aureus, identify HLH-30/TFEB as its main regulator, reveal that FMOs are important innate immunity effectors in animals, and identify the mechanism of FMO regulation through NHR-49/PPAR-α in C. elegans, with important implications for innate host defense in higher organisms.
During bacterial infection, the host is confronted with multiple overlapping signals that are integrated at the organismal level to produce defensive host responses. How multiple infection signals are sensed by the host and how they elicit the transcription of host defense genes is much less understood at the whole-animal level than at the cellular level. The model organism Caenorhabditis elegans is known to mount transcriptional defense responses against intestinal bacterial infections that elicit overlapping starvation and infection responses, but the regulation of such responses is not well understood. Direct comparison of C. elegans that were starved or infected with Staphylococcus aureus revealed a large infection-specific transcriptional signature. This signature was almost completely abrogated by the deletion of transcription factor hlh-30/TFEB, except for six genes including a flavin-containing monooxygenase (FMO) gene, fmo-2/FMO5. Deletion of fmo-2/FMO5 severely compromised infection survival, thus identifying the first FMO with innate immunity functions in animals. Further, fmo-2/FMO5 was specifically induced by Gram-positive pathogens and Gram-positive natural microbiota of C. elegans. Moreover, the mechanism of fmo-2/FMO5 induction required the nuclear receptor, NHR-49/PPARα, which induced fmo-2/FMO5 and host defense cell non-autonomously. These findings for the first time reveal an infection-specific host response to S. aureus, identify HLH-30/TFEB as its main regulator, reveal that FMOs are important innate immunity effectors in animals, and identify the mechanism of FMO regulation through NHR-49/PPARα in C. elegans, with important implications for innate host defense in higher organisms.
Positive and negative regulators of innate immunity work together to maintain immune homeostasis. We previously discovered that HLH-30/TFEB is a critical transcription factor that positively regulates host defense genes upon S. aureus infection in C. elegans. However, repression of host defense genes and negative regulation of immunity remain poorly understood. In this study, we identified nhr-42 as a negative regulator of host defense genes functioning downstream of HLH-30/TFEB, with major implications in host survival and metabolism after infection. nhr-42 expression is induced in an HLH-30/TFEB dependent manner mostly in the pharynx upon infection. We find that animals lacking nhr-42 have higher expression of host defense genes, which enables enhanced survival after infection. Antimicrobials expressed in the pharynx such as abf-2, function downstream of nhr-42 to confer resistance to infection by mitigating pathogen burden. Furthermore, nhr-42 deficient animals are defective in lipid mobilization, having higher lipid stores compared to wild type animals after infection. nhr-42 therefore enables C. elegans to limit the host defense response and reallocate energy resources through lipid mobilization after infection. To our knowledge, this is the first report of a transcription factor that represses host defense genes in C. elegans.
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