[
Nature,
1999]
Advances in human genetics have meant that the genes mutated in human diseases can be identified exclusively by their location in the genome. But how do we work out the cellular functions of the associated protein products? Reports on pages 383 and 386 of this issue begin to address this problem for two proteins - polycystin-1 (PKD1) and polycystin-2 (PKD2) - that are defective in human kidney disease. From their studies of the nematode worm Caenorhabditis elegans, Barr and Sternberg present evidence that homologues of the polycystins act together in a signal-transduction pathway in sensory neurons. Chen et al., by contrast, have used an oocyte-expression system in the from Xenopus laevis to show that a homologue of PKD2 is associated with the activity of a cation channel. These results support the hypothesis that polycystin-related proteins belong to a hitherto unknown class of signal-transduction molecules.
[
Science,
1996]
What 's the secret to long life? For the nematode Caenorhabditis elegans, it's slow, easy living, in which all life's events occur in a leisurely rhythm, according to work described on page 1010 of this issue. The new research, by Siegfried Hekimi and Bernard Lakowski of McGill University in Montreal, identifies four genes that, when mutated, can make these worms use energy more efficiently, feed and swim at a slower pace-and live many times their normal life-span. Some of the experimental nematodes lived for almost 2 months, far longer than their expected 9 days.
[
Science,
1996]
The one-cell animal embryo, or zygote, faces a daunting engineering task: implementing the architectural plans inscribed in its DNS for building a complex, multicelled body. So, like any sensible construction supervisor, the zygote swiftly divides the project into manageable chunks, assigning some of its progeny to build only gut, for example, and other to make only muscle or skin. Just how each early embryonic cell gets its orders is understood only for the fruit fly Drosophila melanogaster-an achievement that helped win 1995's Nobel Prize in medicine for three developmental biologists. Now, however, the communication lines governing embryonic development are emerging in another animal beloved of developmental researchers: the tiny worm known as Caenorhabditis elegans.