Recombinant DNA technology has made it possible to clone receptors from many organisms by cross-hybridization or by the polymerase chain reaction. It may be difficult, though, to establish the functional importance of any clone obtained. We describe the cloning of nematode acetylcholine receptor genes by selection for resistance to levamisole, a scheme providing assurance that the clones obtained are functionally related...
[
Methods Cell Biol,
1995]
The nematode Caenorhabditis elegans is a small, rapidly growing organism that can easily be raised in the laboratory on the bacterium Escherichia coli. Because C. elegans is a self-fertilizing hermaphrodite, it is possible to readily grow large quantities of the organism in swirling liquid cultures and also possible to propagate severely incapacitated mutants. The rapidity of growth and the ability to self-fertilize necessitate special measures to establish a synchronous culture.
[
1977]
The soil nematode Caenorhabditis elegans was selected 11 years ago by Sydney Brenner as an experimental organism suitable for the isolation of many behavioral mutants and small enough for anatomical analysis of such mutants with the electron microscope. Two distinct goals motivated the initial studies of this organism: first, the hope that some of the mutants would have simple anatomical alterations that could be directly correlated with their behavioral defects, allowing the assignment of specific functions to specific neurons, and second, the hope that the detailed analysis of the kinds of alterations induced by individual mutations and the classes of cells affected by given mutations would reveal general features of the genetic program that specifies the development of the organism. Over the past 11 years the number of investigators working on C. elegans has increased to about 75 and is still growing. Nearly 3,000 different mutants have been isolated and different investigators are pursuing their effects on different cells. My own research is in the development of the nervous system. In particular, I would like to learn something about the workings of the complex black box that connects individual genes to the determination of the morphology of developing neurons. Are there gene products whose specific function is to determine the morphology of cells? If so, what are these gene products and how do they act in the developing cell? One would anticipate that mutations in such hypothetical genes would cause specific morphological alterations in cells. Because the morphology of a neuron determines its function, by selecting behavioral mutants altered in the function of the nervous system one might commonly find mutants that alter the morphology of neurons, and some of these might be in specific morphological genes. It is my hope that it will be possible to compare such mutants to the wild type in order to identify the defective gene products and thereby learn something about the role of normal gene products in determining the development of neurons. In this paper I will first summarize the results of several years' work on one specific class of mutants in the nematode, sensory mutants, work performed both in my laboratory and that of my colleagues Jim Lewis and Jonathan Hodgkin. Second, I will discuss frankly some of the difficulties and frustrations we have experienced in trying to interpret the effects of these specific mutants. Some of these difficulties illustrate problems endemic to genetic studies of development. Third, I will describe the more recent work performed in my labortory that is being directed toward genetic analysis of the structure and function of a