Cholesterol-producing transgenic Caenorhabditis elegans lives longer due to newly acquired enhanced stress resistance.

Because Caenorhabditis elegans lacks several components of the de novo sterol biosynthetic pathway, it requires sterol as an essential nutrient. Supplemented cholesterol undergoes extensive enzymatic modification in C. elegans to form other sterols of unknown function. 7-Dehydrocholesterol reductase (DHCR) catalyzes the reduction of the Delta7 double bond of sterols and is suspected to be defective in C. elegans, in which the major endogenous sterol is 7-dehydrocholesterol (7DHC). We microinjected a human DHCR expression vector into C. elegans, which was then incorporated into chromosome by gamma-radiation. This transgenic C. elegans was named cholegans, i.e., cholesterol-producing C. elegans, because it was able to convert 7DHC into cholesterol. We investigated the effects of changes in sterol composition on longevity and stress resistance by examining brood size, mean life span, UV resistance, and thermotolerance. Cholegans contained 80% more cholesterol than the wild-type control. The brood size of cholegans was reduced by 40% compared to the wild-type control, although the growth rate was not significantly changed. The mean life span of cholegans was increased up to 131% in sterol-deficient medium as compared to wild-type. The biochemical basis for life span extension of cholegans appears to partly result from its acquired resistance against both UV irradiation and thermal stress.

Requirement of tyrosylprotein sulfotransferase-A for proper cuticle formation in the nematode C. elegans.

Tyrosine O-sulfation is one of the post-translational modification processes that occur to membrane proteins and secreted proteins in eukaryotes. Tyrosylprotein sulfotransferase (TPST) is responsible for this modification, and in this report, we describe the expression pattern and the biological role of TPST-A in the nematode Caenorhabditis elegans. We found that TPST-A was mainly expressed in the hypodermis, especially in the seam cells. Reduction of TPST-A activity by RNAi caused severe defects in cuticle formation, indicating that TPST-A is involved in the cuticle formation in the nematode. We found that RNAi of TPST-A suppressed the roller phenotype caused by mutations in the rol-6 collagen gene, suggesting that sulfation of collagen proteins may be important for proper organization of the extracellular cuticle matrix. The TPST-A RNAi significantly decreased the dityrosine level in the worms, raising the possibility that the sulfation process may be a pre-requisite for the collagen tyrosine cross-linking.

Functional genomic approaches using the nematode Caenorhabditis elegans as a model system.

Since the completion of the genome project of the nematode C. elegans in 1998, functional genomic approaches have been applied to elucidate the gene and protein networks in this model organism. The recent completion of the whole genome of C. briggsae, a close sister species of C. elegans, now makes it possible to employ the comparative genomic approaches for identifying regulatory mechanisms that are conserved in these species and to make more precise annotation of the predicted genes. RNA interference (RNAi) screenings in C. elegans have been performed to screen the whole genome for the genes whose mutations give rise to specific phenotypes of interest. RNAi screens can also be used to identify genes that act genetically together with a gene of interest. Microarray experiments have been very useful in identifying genes that exhibit co-regulated expression profiles in given genetic or environmental conditions. Proteomic approaches also can be applied to the nematode, just as in other species whose genomes are known. With all these functional genomic tools, genetics will still remain an important tool for gene function studies in the post genome era. New breakthroughs in C. elegans biology, such as establishing a feasible gene knockout method, immortalized cell lines, or identifying viruses that can be used as vectors for introducing exogenous gene constructs into the worms, will augment the usage of this small organism for genome-wide biology.

Neuron cell type-specific SNAP-25 expression driven by multiple regulatory elements in the nematode Caenorhabditis elegans.

In order to characterize the mechanisms regulating neuronal expression of the nematode SNAP-25 gene, we identified the SNAP-25 genes of Caenorhabditis elegans and Caenorhabditis briggsae. Comparative sequence analysis and reporter assays revealed two putative 5' regulatory elements, P1 and P2, and four elements, I1h, I1m, I2h, and I2m, in the first intron. Nuclear extracts contained activities that bound the P2 and I1h elements. Different elements were required for SNAP-25 expression in different neuronal subsets; P1 was required in DA and DD motor neurons, and I1m and I2m were required in DB and DA neurons, respectively. P2 was active in amphid and phasmid neurons, I1h in pharyngeal neurons, and I2h in touch receptor neurons. The I2h element contained a putative binding site for transcription factor UNC-86. Both UNC-86 and MEC-3 were required for I2h activity in the mechanosensory neurons: in these neurons, GFP expression driven by I2h was abolished in animals bearing either an unc-86 null or a mec-3 null mutation, or an unc-86 mutation that leads to defective interaction with MEC-3. Deletion of the MEC-3 binding site also abolished the GFP expression. Gel mobility-shift assay results suggest that transcriptional regulation of SNAP-25 may involve multiple transcription factors.

Sequence-specific binding to telomeric DNA by CEH-37, a homeodomain protein in the nematode Caenorhabditis elegans.

Caenorhabditis elegans can serve as a model system to study telomere functions due to its similarity to higher organisms in telomere structures. We report here the identification of the nematode homeodomain protein CEH-37 as a telomere-binding protein using a yeast one-hybrid screen. The predicted three-dimensional model of the homeodomain of CEH-37, which has a typical helix-loop-helix structure, was similar to that of the Myb domain of known telomere-binding proteins, which is also a helix-loop-helix protein, despite little amino acid sequence similarity. We demonstrated the specific binding of CEH-37 to the nematode telomere sequences in vitro by competition assays. We determined that CEH-37 binding required at least 1.5 repeats of TTAGGC and that the core sequence for binding was GGCTTA. We found that CEH-37 had an ability to bend telomere sequence-containing DNA, which is the case for other known telomere-binding proteins such as TRF1 and RAP1, indicating that CEH-37 may be involved in establishing or maintaining a secondary structure of the telomeres in vivo. We also demonstrated that CEH-37 was primarily co-localized to the chromosome ends in vivo, indicating that CEH-37 may play roles in telomere functions. Consistent with this, a ceh-37 mutation resulting in a truncated protein caused a weak high incidence of male phenotype, which may have been caused by chromosome instability. The identification of CEH-37 as a telomere-binding protein may represent an evolutionary conservation of telomere-binding proteins in terms of tertiary protein structure rather than primary amino acid sequence.