[
WormBook,
2005]
The C. elegans germ line proliferates from one primordial germ cell (PGC) set aside in the early embryo to over a thousand cells in the adult. Most germline proliferation is controlled by the somatic distal tip cell, which provides a stem cell niche at the distal end of the adult gonad. The distal tip cell signals to the germ line via the Notch signaling pathway, which in turn controls a network of RNA regulators. The FBF-1 and FBF-2 RNA-binding proteins promote continued mitoses in germ cells located close to the distal tip cell, while the GLD-1 , GLD-2 , GLD-3 , and NOS-3 RNA regulators promote entry into meiosis as germ cells leave the stem cell niche. In addition to these key regulators, many other genes affect germline proliferation.
[
1990]
Sex determination in the C. elegans germ line addresses two major problems of biological control. First, any regulation that directs male or female development in all tissues must rely on tissue-specific controls to specify a particular pathway of differentiation (e.g., sperm or oocyte) in a single tissue. The C. elegans germ line provides several technical advantages for analyzing sex determination in a single tissue, including powerful genetic selections (Kimble, 1988) and ease of micro-injection (Kimble et al., 1982). Second, the self-fertility of the C. elegans hermaphrodite depends upon its transient production of sperm in an otherwise female animal. Analysis of sex determination in the hermaphrodite germ line should therefore shed light on the evolution of hermaphrodites from females. Here, we review our efforts towards identifying the regulatory elements that control the C. elegans hermaphrodite germ line to produce sperm and
[
Methods Cell Biol,
1995]
DNA transformation assays in a whole organism provide experimental links between molecular structure and phenotype. Experiments with transgenic Caenorhabditis elegans start in general with the injection of DNA into the adult gonad. Effects on phenotype or gene expression patterns can be analyzed either in F1 progeny derived from the injected animals or in derived transgenic lines. Microinjection of C. elegans was first carried out by Kimble et al. (1982). Stinchcomb et al. (1985) then showed that injected DNA could be maintained for several generations in transgenic lines. The first selective methods for producing and maintaining transgenic lines were reported in 1986 (Fire, 1986). These methods have been considerably improved since then (Mello et al., 1991) , so that assays involving DNA transformation are now a standard part of the experimental repertoire for C. elegans.