In mammals, cyclic GMP and cGMP-dependent protein kinases (cGKs) have been
implicated in the regulation of many neuronal functions including long-term
potentiation and long-term depression of synaptic efficacy. To develop Cae
norhabditis elegans as a model system for studying the neuronal function of
the cGKs, we cloned and characterized the cgk-1 gene. A combination of app
roaches showed that cgk-1 produces three transcripts, which differ in their
first exon but are similar in length. Northern analysis of C. elegans RNA,
performed with a probe designed to hybridize to all three transcripts, con
firmed that a major 3.0 kb cgk-1 transcript is present at all stages of dev
elopment. To determine if the CGK-1C protein was a cGMP-dependent protein k
inase, CGK-1C was expressed in S/9 cells and purified. CGK-1C shows a K-a o
f 190 +/- 14 nM for cGMP and 18.4 +/- 2 muM for cAMP. Furthermore, CGK-1C u
ndergoes autophosphorylation in a cGMP-dependent manner and is inhibited by
the commonly used cGK inhibitor, KT5823. To determine which cells expresse
d CGK-1C, a 2.4-kb DNA fragment from the promoter of CGK-1C was used to dri
ve GFP expression. The CGK-1C reporter construct is strongly expressed in t
he ventral nerve cord and in several other neurons as well as the marginal
cells of the pharynx and intestine. Finally, RNA-mediated interference of C
GK-1 resulted in movement defects in nematode larvae. These results provide
the first demonstration that cGMP-dependent protein kinase is present in n
eurons of C.elegans and show that this kinase is required for normal motili
ty.