[
Methods Cell Biol,
1995]
The genetics of Caenorhabditis elegans provides a convenient experimental entry point into many developmental processes and a powerful tool that can be exploited to characterize interactions among a set of genes regulating a particular pathway. Eventually, though, the study of developmental processes becomes a molecular study of gene regulation. At this level, the determination of the on/off state of a gene requires an understanding of not only its transcriptional state, but also post-transcriptional, translational, and post-translational control mechanisms. Although the vertebrate literature is rich in details of factors that influence these regulatory processes, relatively few of the factors responsible for gene expression in the nematode C. elegans have been characterized. This lag in knowledge reflects both the relatively recent arrival of C. elegans on the list of experimental systems, as well as its general unsuitability for biochemistry. There are no tissue culture cell lines established from C. elegans, and it is difficult to isolate, in large amounts, any homogeneous cell type. Moreover, the impermeable eggshell encasing the embryo and the cuticle encasing the worm make pharmacological studies in intact animals difficult and tedious. Grim as this sounds, progress has been made in C. elegans in the field of gene expression. The sensitivity of techniques has improved and the available molecular tool kit has expanded. The study of individual genes has provided descriptions of several regulatory processes, some general and some gene specific. Our current level of understanding of gene regulation is sufficient to say that C. elegans appears, in general, to be a typical eukaryote. As such, C. elegans is amenable to many of the standard analytical approaches used in other developmental systems. The purpose of this chapter is to review our current state of knowledge of transcription and translation in C. elegans (for a review
[
2000]
There is growing interest in the use of bioindicators to assess metal toxicity in soil. The current ASTM Standard Guide for Conducting Laboratory Soil Toxicity Test with the lumbricid earthworm Eisenia fetida (E 1676-97) uses a common earthworm. The nematode Caenorhabditis elegans is a natural soil inhabitant with many characteristics that make an ideal alternate test organism. It has been used to assess metal toxicity in aquatic media, agar plates and in soil. Work is currently underway on the design of a C. elegans procedure for metals in soil. The objective of this study was to determine differences in LC50S between the chloride salt and the nitrate salt forms of cadmium, copper, lead, nickel, and zinc, in three types of soil: Cecil, Tifton, and ASTM artificial soil. Results indicated that the toxicological effect of the metallic salt varies and is dependent on the particular metal. For Cd and Pb the nitrate form is more toxic while Cu and Ni are more toxic in the chloride form. The composition of the soil also effected toxicity, with the metal being the least toxic in ASTM soil and more toxic in the Tifton soil. This strongly correlated with organic matter and clay content of the soil. It is important to determine the effects of carrier salt form and soil composition on metal toxicity, not only in order to standardize the protocol for C. elegans soil toxicity testing, but also in establishing acceptable exposure concentrations in the soil.