[
1987]
The concept of developmentally programmed senescence has been outlined by Leonard Hayflick (this volume), and examples from development have been used as exemplars of "developmentally programmed senescence" (Richard Russell, this volume). Unlike development, senescence has probably evolved in the absence of direct selection for increased longevity, perhaps as a direct result of the absence of such selection. (For an excellent review see Charlesworth.) A popular evolutionary model that has received experimental support suggests that senescence may result from pleiotropic effects of selection for adaptive life history characteristics. In the literature on aging, less rigorous arguements have been used to suggest that in human evolution, a delay in the age of senescence has been indirectly selected for by means of so-called longevity assurance or longevity-determinant genes. However, all explanations for the evolution of senescence are theoretical, and, with few exceptions, remain largely untested. Like Dr. Hayflick and Russell, I will assume that by developmental programming we mean genetic specification. I will use a general definition so as not to preclude examples that fail to meet one or more of the rigid criteria defined by Russell (this volume). This less rigid definition of programmed aging is necessary, because unlike development, where genetics has been successfully applied for 50 years, examples of genetic specification of senescent processes are quite few. In the literature on aging, it is still not widely accepted that mutants can alter fundamental patterns of senescent events in well-defined ways. One purpose of this presentation is to outline a few examples. In senescence, large batteries of new genes are not differentially regulated; this is quite unlike development, where many genes are differentially regulated. The molecular etiology of senescence is unknown in almost every instance and, as such, makes the study of aging a fascinating area for inquiry. If senescence is unlike development in lacking differential gene regulation, what are the approaches that are likely to yield useful results in the analysis of senescence and the aging process? The developmental genetic paradigm is a useful, indeed essential, theoretical construct for approaching the aging process in an experimental context. The lack of a suitable model organism in which classical and molecular genetics can be productively combined with other experimental techniques has impeded our understanding of senescence. Despite a general lack of evidence for genetic specification, there are instances where genetic specification is clearly evident; the analysis of mutational events that alter normal senescence in well-defined ways demonstrates this point. These instances also provide experimental models for dissecting the aging
[
1994]
Nematodes have been cultured continuously in the laboratory since 1944 when Margaret Briggs Gochnauer isolated and cultured the free-living hermaphroditic species Caenorhabditis briggsae. Work with C. briggsae and other rhabditid nematodes, C. elegans, Rhabditis anomala, and R. pellio, demonstrated the relative ease with which they could be cultured. The culturing techniques described here were developed for C. elegans, but are generally suitable (to varying degrees) for other free-living nematodes. Whereas much of the early work involved axenic culturing, most of these techniques are no longer in common use and are not included here. In the 1970s C. elegans became the predominant research model due to work by Brenner and co-workers on the genetics and development of this species. An adult C. elegans is about 1.5 mm long, and under optimal laboratory conditions has a life cycle of approximately 3 days. There are two sexes, males and self-fertile hermaphrodites, that are readily distinguishable as adults. The animals are transparent throughout the life cycle, permitting observation of cell divisions in living animals using differential interference microscopy. The complete cell lineage and neural circuitry have been determined and a large collection of behavioral and anatomical mutants have been isolated. C. elegans has six developmental stages: egg, four larval stages (L1-L4), and adult. Under starvation conditions or specific manipulations of the culture conditions a developmentally arrested dispersal stage, the dauer larva, can be formed as an alternative third larval stage. Many of the protocols included here and other experimental protocols have been summarized in "The Nematode Caenorhabditis elegans". We also include a previously unpublished method for long-term chemostat cultures of C. elegans. General laboratory culture conditions for nematode parasites of animals have been described, but none of these nematodes can be cultured in the laboratory through more than one life cycle. Marine nematodes and some plant parasites have been cultured xenically or with fungi. Laboratory cultivation of several plant parasites on Arabidopsis thaliana seedlings in agar petri plates has also been reported.