Abstract
Early life experiences such as malnutrition can affect development and adult disease risk, but the molecular basis of such protracted effects is poorly understood. In the nematode C. elegans, extended starvation during the first larval stage causes the development of germline tumors and other abnormalities in the adult gonad, limiting reproductive success. Insulin/IGF signaling (IIS) acts through WNT signaling and lipid metabolism to promote starvation-induced gonad abnormalities, but IIS-independent modifiers have not been identified. The tumor suppressor daf-18/PTEN inhibits IIS to suppress starvation-induced abnormalities, but we show that it also acts independently of IIS via lin-35/Rb, another tumor suppressor, to suppress such abnormalities. We found that lin-35/Rb and the rest of the DREAM complex repress transcription of the Hedgehog (Hh) signaling homologs ptr-23/PTCH-related, wrt-1/Hh-like, and wrt-10/Hh-like, which promote starvation-induced abnormalities. These Hh-related genes transcriptionally activate several genes associated with innate immunity in adults, which also promote starvation-induced gonad abnormalities. Surprisingly, we found that in addition to causing developmental abnormalities, early-life starvation induces an innate immune response later in life, leading to increased resistance to bacterial and intracellular pathogens. This work identifies a critical tumor-suppressor function of daf-18/PTEN independent of IIS, and it defines a regulatory network, including lin-35/Rb and DREAM, Hh-related signaling, and innate immunity pathways, that affects development of tumors and other developmental abnormalities resulting from early life starvation. By revealing that early-life starvation increases immunity later in life, this work suggests a fitness tradeoff between pathogen resistance and developmental robustness.