-
[
Curr Opin Neurobiol,
2012]
Escape behaviors are crucial to survive predator encounters. Touch to the head of Caenorhabditis elegans induces an escape response where the animal rapidly backs away from the stimulus and suppresses foraging head movements. The coordination of head and body movements facilitates escape from predacious fungi that cohabitate with nematodes in organic debris. An appreciation of the natural habitat of laboratory organisms, like C. elegans, enables a comprehensive neuroethological analysis of behavior. In this review we discuss the neuronal mechanisms and the ecological significance of the C. elegans touch response.
-
[
Curr Opin Genet Dev,
1996]
The sequencing of the 100 Mb Caenorhabditis elegans genome-containing approximately 14,000 genes-is approximately 50% complete. One of its most interesting features is its compactness; introns and intergenic distances are unusually small and, surprisingly, approximately 25% of genes are contained in polycistronic transcription units (operons) with only approximately 100 bp between genes.
-
[
Int J Parasitol,
2000]
Onchocerca volvulus, the filarial parasite that causes onchocerciasis or river blindness, contains three distinct genomes. These include the nuclear genome, the mitochondrial genome and the genome of an intracellular endosymbiont of the genus Wolbachia. The nuclear genome is roughly 1.5x10(8) bp in size, and is arranged on four chromosome pairs. Analysis of expressed sequence tags from different life-cycle stages has resulted in the identification of transcripts from roughly 4000 O. volvulus genes. Several of these transcripts are highly abundant, including those encoding collagen and cuticular proteins. Analysis of several gene sequences from O. volvulus suggests that the nuclear genes of O. volvulus are relatively compact and are interrupted relatively frequently by small introns. The intron-exon boundaries of these genes generally follow the GU-AG rule characteristic of the splice donor and acceptors of other vertebrate organisms. The nuclear genome also contains at least one repeated sequence family of a 150 bp repeat which is arranged in tandem arrays and appears subject to concerted evolution. The mitochondrial genome of O. volvulus is remarkably compact, only 13747 bp in size. Consistent with the small size of the genome, four gene pairs overlap, eight contain no intergenic regions and the remaining gene pairs are separated by small intergenic domains ranging from 1 to 46 bp. The protein-coding genes of the O. volvulus mitochondrial genome exhibit a striking codon bias, with 15/20 amino acids having a single codon preference greater than 70%. Intraspecific variation in both the nuclear and mitochondrial genomes appears to be quite limited, consistent with the hypothesis that O. volvulus has suffered a genetic bottleneck in the recent past.
-
[
Science,
1994]
Worms, butterflies, and chimpanzees all have the same body axes-head and tail, front and back, and left and right sides. How are these axes established during development? Is there a single molecular map used by most metazoan embryos or have similar coordinates been achieved during evolution by diverse routes? A comparison of the mechanisms that establish body axes in distantly related organisms can begin to answer this fundamental question.
-
[
Pflugers Arch,
2017]
The nematode C. elegans exhibits complex thermal experience-dependent navigation behaviors in response to environmental temperature changes of as little as 0.01C over a >10C temperature range. The remarkable thermosensory abilities of this animal are mediated primarily via the single pair of AFD sensory neurons in its head. In this review, we describe the contributions of AFD to thermosensory behaviors and temperature-dependent regulation of organismal physiology. We also discuss the mechanisms that enable this neuron type to adapt to recent temperature experience and to exhibit extraordinary thermosensitivity over a wide dynamic range.
-
[
Yakugaku Zasshi,
2008]
Selenium (Se) is an essential trace element. Se is found as selenocysteine (Sec) in Se-proteins. Sec is the 21(st) amino acid, because Sec has its tRNA, the codon UGA and those components in its translational machinery. Sec UGA codon shares with major stop codon UGA. We purified Sec synthesizing enzymes, such as seryl-tRNA synthetase (SerRS), Sec synthetase (SecS) and selenophosphate synthetase (SePS). I described the procedures to prepare Sec tRNA, SerRS, SecS, SePS and [(75)Se]H(2)Se in detail. We clarified that SecS composed of two proteins, SecSalpha and SecSbeta. Sec synthesizing and incorporating systems present in Monela, Animalia and Protoctista but not in Plantae and Fungi. We showed that protozoa had Sec tRNA on which Sec was synthesized from Ser-tRNA by bovine and protozoa SecS. Some worms, such as Caenorhabditis elegans and Fasiola gigantica, also had Sec tRNA on which Sec was synthesized by bovine liver SecS or C. elegans enzymes. We showed recognition sites of mammalian Sec tRNA by SecS. The identitiy units of Sec tRNA are 9 bp aminoacyl- and 6 bp D-stems. This recognition is not the base-specific manner but the length-specific manner. From comparison of the phylogeny trees of Sec synthesizing system and translation system, we concluded that the evolution of Sec synthesizing system is older than that of the translation system.
-
[
Curr Opin Neurobiol,
2016]
Increasing interest in sex differences in Caenorhabditis elegans neurobiology is resulting from several advances, including the completion of the male tail connectome and the surprising discovery of two 'new' neurons in the male head. In this species, sex-specific circuits in the hermaphrodite and male control reproductive behaviors such as egg-laying and copulation, respectively. Studies of these systems are revealing interesting similarities and contrasts, particularly in the mechanisms by which nutritional status influences reproductive behaviors. Other studies have highlighted the importance of sexual modulation of shared neurons and circuits in optimizing behavioral strategies. Together, these findings indicate that C. elegans uses intertwined, distributed sex differences in circuit structure and function to implement sex-specific as well as sexually divergent, shared behaviors.
-
[
Genome Res,
2005]
The Caenorhabditis elegans genome sequence is now complete, fully contiguous telomere to telomere and totaling 100,291,840 bp. The sequence has catalyzed the collection of systematic data sets and analyses, including a curated set of 19,735 protein-coding genes-with >90% directly supported by experimental evidence-and >1300 noncoding RNA genes. High-throughput efforts are under way to complete the gene sets, along with studies to characterize gene expression, function, and regulation on a genome-wide scale. The success of the worm project has had a profound effect on genome sequencing and on genomics more broadly. We now have a solid platform on which to build toward the lofty goal of a true molecular understanding of worm biology with all its implications including those for human health.
-
[
Mech Ageing Dev,
2003]
Aging is the most complex phenotype for a multicellular organism. This process is now being under severe investigation. Here I will review the different processes known to affect longevity in the nematode Caenorhabditis elegans and their relationship with thermotolerance. All the longevity mutants that have been tested so far show an increase in stress resistance. In particular, long-lived mutants affected in the IGF/insulin pathway and those affected in the germ-line formation are both thermotolerant and long-lived. The mechanisms that activate the stress resistance are now been understood including the DAF-16 fork head transcription factor transport to the nucleus and the activation of genes involved in the defense to stress. The high correlation between stress resistance and longevity suggests that the same molecular activities that defend the cell from stress can defend the cell from the damage caused by aging.
-
[
Curr Opin Biotechnol,
2007]
Using DNA microarrays to generate transcriptional profiles of the aging process is a powerful tool for identifying biomarkers of aging. In Caenorhabditis elegans, a number of whole-genome profiling studies identified genes that change expression levels with age. High-throughput RNAi screens in worms determined a number of genes that modulate lifespan when silenced. Transcriptional profiling of the fly head identified a molecular pathway, the ''response to light'' gene set, that increases expression with age and could be directly related to the tendency for a reduction in light levels to extend fly''s lifespan. In mouse, comparing the gene expression profiles of several drugs to the gene expression profile of caloric restriction identified metformin as a drug whose action could potentially mimic caloric restriction in vivo. Finally, genes in the mitochondrial electron transport chain group decrease expression with age in the human, mouse, fly, and worm.