[
J Mol Evol,
1996]
Transmembrane 4 superfamily (TM4SF) molecules are predominantly mammalian cell surface glycoproteins that are thought to transduce signals mediating cell development, activation, and motility. Analysis of the Genpept sequence database reveals YKK8, a novel member of the TM4SF in the nematode, Caenorhabditis elegans. YKK8 is a putative 27.4-kDa protein encoded by a gene on chromosome III of the C. elegans genome. The assignment of YKK8 to the TM4SF is justified by three criteria: statistical comparison of protein sequences, conserved TM4SF protein sequence motifs, and conserved TM4SF intron/exon boundaries in the genomic sequence. The discovery of a TM4SF molecule in the nematode extends this superfamily to a more primitive branch of the phylogenetic tree and suggests a fundamental role for TM4SF molecules in biology.
[
Nature,
1997]
Genetic analyses of the nematode Caenorhabditis elegans have identified three core components of the cell-death apparatus. CED-3 and CED-4 promote, whereas CED-9 inhibits cell death. Recent studies indicate that CED-4 might interact independently with CED-3 and CED-9, forming the crux of a multicomponent death complex. But except for its role as an adaptor molecule, little is known about CED-4 function. A clue came with the observation that mutation of the phosphate-binding loop (P-loop) of CED-4 disrupts its ability to induce chromatin condensation in yeast. Further, a P-loop mutant of CED-4 (CED-4K165R) fails to process CED-3 in vivo, both in insect and mammalian cells (unpublished). We now confirm that CED-4 induces CED-3 activation and subsequent apoptosis, and that the process requires binding of ATP.
[
ACS Chem Biol,
2012]
Entomopathogenic nematodes survive in the soil as stress-resistant infective juveniles that seek out and infect insect hosts. Upon sensing internal host cues, the infective juveniles regurgitate bacterial pathogens from their gut that ultimately kill the host. Inside the host, the nematode develops into a reproductive adult and multiplies until unknown cues trigger the accumulation of infective juveniles. Here, we show that the entomopathogenic nematode Heterorhabditis bacteriophora uses a small-molecule pheromone to control infective juvenile development. The pheromone is structurally related to the dauer pheromone ascarosides that the free-living nematode Caenorhabditis elegans uses to control its development. However, none of the C. elegans ascarosides are effective in H. bacteriophora, suggesting that there is a high degree of species specificity. Our report is the first to show that ascarosides are important regulators of development in a parasitic nematode species. An understanding of chemical signaling in parasitic nematodes may enable the development of chemical tools to control these species.