The highly conserved co-chaperone DnaJ/Hsp40 family proteins are known to interact with molecular chaperone Hsp70, and can regulate many cellular processes including protein folding, translocation and degradation. In studies of C. elegans locomotion mutants, we identified a gain-of-function (gf) mutation in
dnj-17 closely linked to the widely used
e156 null allele of C. elegans GAD (glutamic acid decarboxylase)
unc-25.
dnj-17 encodes a DnaJ protein orthologous to human DNAJA5. In C. elegans DNJ-17 is a cytosolic protein and is broadly expressed in many tissues.
dnj-17(gf) causes a single amino acid substitution in a conserved domain, and behaves as a hypermorphic mutation. The effect of this
dnj-17(gf) is most prominent in mutants lacking GABA synaptic transmission. In a seizure model caused by a mutation in the ionotropic aceytylcholine receptor
acr-2(gf),
dnj-17(gf) exacerbates the convulsion phenotype in conjunction with absence of GABA. Null mutants of
dnj-17 show mild resistance to aldicarb, while
dnj-17(gf) is hypersensitive. These results highlight the importance of DnaJ proteins in regulation of locomotor circuit, and provide insights to the possible roles of DnaJ proteins in human disease.