A Conserved Endocrine Mechanism Controls the Formation of Dauer and Infective Larvae in Nematodes

Under harsh environmental conditions Caenorhabditis elegans larvae undergo arrest and form dauer larvae that can attach to other animals to facilitate dispersal[1]. It has been argued that this phenomenon, called phoresy, represents an intermediate step towards parasitism[2, 3]. Indeed, parasitic nematodes invade their hosts as infective larvae, a stage that shows striking morphological similarities to dauer larvae[1]. While the molecular regulation of dauer entry in C. elegans involves insulin and TGF-ß signaling[4-8], studies of TGF-ß orthologues in parasitic nematodes did not provide evidence for a common origin of dauer and infective larvae[9-14]. To identify conserved candidate regulators between Caenorhabditis and parasitic nematodes we used an evolutionary approach involving Pristionchus pacificus as intermediate. We show by mutational and pharmacological analysis that Pristionchus and Caenorhabditis share the dafachronic acid-DAF-12 system as core endocrine module for dauer formation. One of the dafachronic acids, Δ7-DA, has a conserved role in the mammalian parasite Strongyloides papillosus where it controls entry into the infective stage. Application of Δ7-DA blocks formation of infective larvae and results in the generation of free-living animals. The conservation of this small molecule ligand represents a fundamental link between dauer and infective larvae and might provide a general strategy for nematode parasitism.