Lithium (Li) has long been known to have teratogenic effects on the development of many organisms, including sea urchin, Xenopus and Dictyostelium. In Li-treated Xenopus embryos, ventral blastmeres are respecified to develop into dorsal structures, leading to dorsalized embryos lacking ventral mesodermal tissues. In Dictyostelium, Li alters the fate of prespore cells to become prestalk cells instead. Besides teratogenic effects, Li is also known to be a most effective treatment of manic-depressive illness.!@Although several models have been proposed to explain Li action, the molecular mechanism has remained unclear. Recently, GSK (glycogen synthase kinase)-3b was proposed to be a target of Li, suggesting that Li affects the wnt signaling pathway. To understand the mechanism of Li action, I first examined the effect of Li on C. elegans embryogenesis. I inoculated N2 animals at the late L4 stage onto NG plates containing 20 mM LiCl, incubated them at 20 oC. The number of eggs produced by treated animals was reduced to about half of the untreated control. Although cell division seemed to proceed, no embryos hatched on Li plates. Treated-embryos developed to produce gut granules, but did not execute normal morphogenesis at later embryonic stages. To identify genes involved in the action of Li, I have begun to screen for Li-resistant mutants that propagated on Li-containing medium. Several mutants were isolated, and one of them was mapped on the left side of
unc-42 on chromosome V. On Li plates, the hatching rate of mutant eggs cross-fertilized by wild-type males was essentially the same as that for self-fertilized mutant eggs. On the contrary, no wild-type eggs cross-fertilized by mutant males hatched on Li-containing plates. So, this mutation appeared to be maternal. Further genetic analyses of the mutants and the observation on the cellular phenotype of Li-treated embryos are underway.