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[
1985]
Expression of the vitellogenin genes is restricted to the intestine of adult hermaphrodite C. elegans. In order to identify potential cis-acting elements involved in this developmental regualtion, we have sequenced the regions surrounding the 5' ends of five of the six members of this gene family. In addition, we have sequenced several of the promoters from the homologous genes from the related species C. briggsae. Although the various promoters are largely diverged from one another, we have discovered two potential regulatory sequences within the first 250 bp upstream of each of the genes. The first, TGTCAAT, occurs eight times as a perfect heptamer upstream of the five C. elegans genes, at least once per promoter. Allowing a 1 bp mismatch, the element is found in both orientations a total of 27 times, four to six timer per promoter. It is present preferentially at two locations: just upstream of the TATA box and, in the opposite orientation, at position -180. The second sequence, CTGATAA, is also present as a perfect heptamer in a restricted region of each promoter: near position -135. Remarkably, this sequence is also found upstream of the vitellogenin genes of vertebrates. Both sequences have been conserved in the C. briggsae promoters. We hypothesize that these two sequences are involved in the sex-, tissue-, and stage-specific expression of the vitellogenin genes.
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[
Methods Mol Biol,
2012]
Cellular effects of primary mitochondrial dysfunction, as well as potential mitochondrial disease therapies, can be modeled in living animals such as the microscopic nematode, Caenorhabditis elegans. In particular, molecular analyses can provide substantial insight into the mechanism by which genetic and/or pharmacologic manipulations alter mitochondrial function. The relative expression of individual genes across both nuclear and mitochondrial genomes, as well as relative quantitation of mitochondrial DNA content, can be readily performed by quantitative real-time PCR (qRT-PCR) analysis of C. elegans. Additionally, microarray expression profiling offers a powerful tool by which to survey the global genetic consequences of various causes of primary mitochondrial dysfunction and potential therapeutic interventions at both the single gene and integrated pathway level. Here, we describe detailed protocols for RNA and DNA isolation from whole animal populations in C. elegans, qRT-PCR analysis of both nuclear and mitochondrial genes, and global nuclear genome expression profiling using the Affymetrix GeneChip C. elegans Genome Array.
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[
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
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[
1989]
Transposable elements have recently been described in several species: Caenorhabditis elegans, Caenorhabditis briggsae, Ascaris lumbricoides, and Panagrellus redivivus. Because of the intense interest in C. elegans as an experimental organism for developmental genetic studies and the availability of sophisticated genetics, most is know about transposons in this species. This review focuses principally on Tc1 (Tc=transposon) of C. elegans, the best understood element in nematodes. Other elements in C. elegans and also elements in other species of nematodes will be briefly surveyed. The interested reader should also see two recent related reviews. The genome of C. elegans is 8 x 10(7) base pairs (bp) in extent, the smallest known for any metazoan. There are six chromosomes per haploid set, and about 83% of C. elegans DNA behaves as single-copy sequence in renaturation experiments. The repeated sequences are of several types, including functional genes, inverted or "foldback" sequences, and short repeated sequences of a few hundred nucleotides. The global arrangment of these short repeats is of the "short-period-interspersion" or "Xenopus" pattern. Some of the repetitive sequences consist of transposable elements, and at least five distinct families have been identified in C. elegans, Tc1 through Tc5. The sequence of one Tc1 element has been determined and shows that Tc1 resembles bacterial insertion sequence elements with terminal inverted repeats and a central open reading frame. The complete sequences for any members of the other transposon families have not been determined, but the data suggest that Tc2, Tc3, and Tc5 are also insertion sequence-like in structure and that Tc4 is foldbacklike in structure. No "retrotransposon-like" elements have been identified in C. elegans, although such elements have been described in A.
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[
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
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[
2017]
An organism's health depends on the integrity of molecular and biochemical networks responsible for ensuring homeostasis within its cells and tissues. However, upon aging, a progressive failure in the maintenance of this homeostatic balance occurs in response to various insults, allowing the accumulation of damage, the physiological decline of individual tissues, and susceptibility to diseases. Despite the complex nature of the aging process, simple genetic and environmental alterations can cause an increase in healthy lifespan or "healthspan" in laboratory model organisms. Genetic manipulations of model organisms including yeast, worms, flies, and mice have revealed signaling elements involved in DNA damage, stem cells maintenance, proteostasis, energy, and oxidative metabolism (Riera et al., 2016). However, one of the most intriguing discoveries made in these models resides in the ability of environmental factors to profoundly alter the aging process by remodeling some of the genetic programs mentioned above (Riera and Dillin, 2016). The first line of evidence that an external cue could powerfully regulate longevity was obtained by performing dietary restriction in rodents, a reduction in food intake without malnutrition. Dietary restriction is the most robust intervention to increase lifespan in model organisms including rodents and primates, and delays the emergence of age-related diseases (Mair and Dillin, 2008). How dietary restriction extends lifespan remains an open question, but decades of research are evidencing molecular pathways embedded in the response to reduce energy availability, resulting in the emergence of an altered metabolic state that promotes health and longevity. Nonetheless, the discovery of dietary restriction opened a new avenue of research in the aging field, and in particular in the understanding of how animals deal with fluctuating energy levels in their natural environment, and how their longevity is affected by such factors. This is particularly relevant for the nematode Caenorhabditis elegans, which survives in a changing environment and must be able to coordinate energy-demanding processes including basal cellular functions, growth, reproduction, and physical activity with available external resources. In order to sense their environment, C. elegans possess ciliated sensory neurons located primarily in sensory organs in the head and tail regions. Cilia function as sensory receptors, expressing many G protein-coupled receptors (GPCRs) and transient receptor potential (TRP) channels, and mutants with defective sensory cilia have impaired sensory perception (Bargmann, 2006). Cilia are membrane-bound microtubule-based structures and in C. elegans are only found at the dendritic endings of sensory neurons. Sensory neurons provide nematodes with a remarkable form of developmental plasticity, allowing them to assess food availability, temperature, and crowding information (worm density) in order to arrest their development if required, thus forming long-lived and stress-resistant dauer larvae (Bargmann, 2006; Golden and Riddle, 1982). When favorable times return, worms assess the same cues to recover and resume normal development. As the entry and exit of the dauer larval stage suggest, worm sensory neurons truly function as neuroendocrine organs, being implicated in many physiological functions in addition to their behavioral role (Bargmann, 2006). Much information on these neurons has been gathered from laser ablation experiments and analysis of mutants presenting defects in sensory cilia. A seminal discovery in the aging field was achieved when the laboratory of Cynthia Kenyon showed in 1999 that mutations that cause various defects in cilia formation, including the absence of cilia, deletion of middle and distal segments, or impair chemosensory signal transduction increase longevity profoundly (Apfeld and Kenyon, 1999). Later, this group also demonstrated that laser ablation of specific pairs of gustatory and olfactory chemosensory neurons was sufficient to extend lifespan (Alcedo and Kenyon, 2004). What is the role of TRP channels in modulating these neuroendocrine processes, and what kind of stimuli are these receptors detecting to control aging? This chapter summarizes relevant discoveries that clarify some of the roles of TRP channels in the aging process.