[
Nature,
2002]
The genomes of animals, plants and fungi seem to be relatively disorganized. Genes appear to be randomly distributed, with only a few exceptions: repeats of similar sequences caused by gene duplications, for example, and a limited number of ancient gene clusters containing functionally related genes (such as the Hox genes that are involved in control of animal development). Apart from these, the average gene is generally assumed to be independent of its neighbours, and genomes are constantly rearranged and shuffled. However, in one group of animals the nematodes (small, unsegmented worms) neighboring genes are occasionally assembled into regulatory units called operons. On page 851 of this issue, Blumenthal et al. now report the first whole-genome characterization of such operons in a mulicellular organism, an raise intriguing questions as to how (and why) they have evolved.
[
Science,
1991]
The millimeter-long roundworm Caenorhabditis elegans is amassing a sizable research following. As more and more people have joined teh confederation of research efforts loosely called the worm project (see Science, 15 June 1990, p. 1310), the community's biennial meeting has outgrown the traditional watering hole at Cold Spring Harbor. This year, the researchers moved inland for the Eighth International C. elegans Meeting, held June 1-5 on Lake Mendota at the University of Wisconsin, Madison. More than 500 "worm people" turned out to absorb progress reports on the sequencing of the C. elegans genome, the study of its developmental pathways-and some newer topics as well.