Chang, Jessica T et al. (2015) International Worm Meeting "Spatial and temporal analysis of autophagy in organismal aging."

Hansen, Malene, Davis, Joseph H, Chang, Jessica T

[International Worm Meeting, 2015]

Autophagy is a conserved multi-step cellular degradation system that is crucial for many biological processes, including aging. While autophagy is required for lifespan extension in several organisms, the cellular and molecular mechanisms by which autophagy may contribute to longevity remains largely unknown.In the nematode, C. elegans, multiple conserved longevity paradigms, including daf-2/insulin-signaling and germline-less glp-1/Notch mutants require autophagy genes for lifespan extension and display an increased number of autophagosomes in hypodermal cells during development compared to wild-type animals. However, it remains to be addressed whether autophagy is critical for longevity in a temporal- and/or spatial manner.To address this important question, we have developed two new techniques to investigate tissue-specific autophagic flux in C. elegans with age, i.e., (1) a ubiquitously expressed tandem (mCherry::GFP) LGG-1/LC3 reporter to monitor different steps of the autophagy process, and (2) an injection protocol of the chemical Bafilomycin A to rapidly impose an autophagy block in adult animals. Our ongoing systematic analysis of autophagy flux in the major tissues of the animal has uncovered age-dependent changes in wild-type animals, and highlighted both differences and similarities between daf-2 and glp-1 animals. Notably, while we observe several tissue-specific differences in our reporter analyses, we find a key role for autophagy in the intestine of these two longevity paradigms.Collectively, these in-depth analyses along with additional assay development to monitor autophagic flux in C. elegans are providing novel insights into the underlying mechanisms by which autophagy is important for longevity. Such knowledge of the site-of-action of autophagy will be critical for targeting autophagy in higher organisms. .

Chang SY et al. (2017) J Microbiol Biotechnol "Erratum to: Genome Characteristics of Lactobacillus fermentum Strain JDFM216 for Application as Probiotic Bacteria."

Lee HK, Heo J, Chang SY, Jeong DY, Oh S, Jo SH, Kim Y, Park MR, Song MH, Kim JN

[J Microbiol Biotechnol, 2017]

This erratum is being published to correct the 1st author's name of above manuscript by Jang et al. that was published in Journal of Microbiology and Biotechnology (2017, 27: 1266-1271). The 1st author name(Sung Yong Jang) should appear as 'Sung Yong Chang'.

Samuel ADT et al. (2003) J Neurosci "Synaptic activity of the AFD neuron in Caenorhabditis elegans correlates with thermotactic memory."

Murthy VN, Samuel ADT, Silva RA

[J Neurosci, 2003]

Thermotactic behavior in Caenorhabditis elegans is sensitive to both a worm's ambient temperature (T-amb) and its memory of the temperature of its cultivation (T-cult). The AFD neuron is part of a neural circuit that underlies thermotactic behavior. By monitoring the fluorescence of pH-sensitive green fluorescent protein localized to synaptic vesicles, we measured the rate of the synaptic release of AFD in worms cultivated at temperatures between 15 and 25degreesC, and subjected to fixed, ambient temperatures in the same range. We found that the rate of AFD synaptic release is high if either T-amb > T-cult or T-amb > T-cult, but AFD synaptic release is low if T-amb congruent to T-cult. This suggests that AFD encodes a direct comparison between T-amb and T-cult.

Opperman CH et al. (1992) Parasitol Today "Nematode acetylcholinesterases--molecular forms and their potential role in nematode behavior."

Chang S-H, Opperman CH

[Parasitol Today, 1992]

Nematode movement is reliant upon the somatic musculature that runs longitudinally along the body wall. Neuromuscular synapses occur in the ventral and dorsal cords and employ the excitatory neurotransmitter, acetylcholine (ACh), for modulation of muscle activity. Acetylcholine activity is terminated by hydrolysis by acetylcholinesterase (AChE). Here, Charles Opperman and Stella Chang discuss the molecular forms and potential role of this enzyme.

Bommireddy R et al. (2007) Trends Mol Med "TGFbeta1 and Treg cells: alliance for tolerance."

Bommireddy R, Doetschman T

[Trends Mol Med, 2007]

Transforming growth factor beta1 (TGFbeta1), an important pleiotropic, immunoregulatory cytokine, uses distinct signaling mechanisms in lymphocytes to affect T-cell homeostasis, regulatory T (T(reg))-cell and effector-cell function and tumorigenesis. Defects in TGFbeta1 expression or its signaling in T cells correlate with the onset of several autoimmune diseases. TGFbeta1 prevents abnormal T-cell activation through the modulation of Ca(2+)-calcineurin signaling in a Caenorhabditis elegans Sma and Drosophila Mad proteins (SMAD)3 and SMAD4-independent manner; however, in T(reg) cells, its effects are mediated, at least in part, through SMAD signaling. TGFbeta1 also acts as a pro-inflammatory cytokine and induces interleukin (IL)-17-producing pathogenic T-helper cells (T(h) IL-17 cells) synergistically during an inflammatory response in which IL-6 is produced. Here, we will review TGFbeta1 and its signaling in T cells with an emphasis on the regulatory arm of immune tolerance.

Agulnik SI et al. (1995) Genomics "Conservation of the T-box gene family from Mus musculus to Caenorhabditis elegans."

Bollag RJ, Silver LM, Agulnik SI

[Genomics, 1995]

Recently, a novel family of genes with a region of homology to the mouse T locus, which is known to play a crucial, and conserved, role in vertebrate development, has been discovered. The region of homology has been named the T-box. The T-box domain of the prototypical T locus product is associated with sequence-specific DNA binding activity. In this report, we have characterized four members of the T-box gene family from the nematode Caenorhabditis elegans. All lie in close proximity to each other in the middle of chromosome III. Homology analysis among all completely sequenced T-box products indicates a larger size for the conserved T-box domain (166 to 203 residues) than previously reported. Phylogenetic analysis suggests that one C. elegans T-box gene may be a direct ortholog of the mouse Tbx2 and Drosophila omb genes. The accumulated data demonstrate the ancient nature of the T-box gene family and suggest the existence of at least three separate T-box-containing genes in a common early metazoan ancestor to nematodes and vertebrates.

Ju T et al. (2006) Glycobiology "Identification of core 1 O-glycan T-synthase from Caenorhabditis elegans."

Ju T, Zheng Q, Cummings RD

[Glycobiology, 2006]

The common O-glycan core structure in animal glycoproteins is the core 1 disaccharide Galbeta1-3GalNAcalpha1-Ser/Thr, which is generated by addition of Gal to GalNAcalpha1-Ser/Thr by core 1 UDP-Gal:GalNAcalpha1-Ser/Thr beta1,3-galactosyltransferase (core 1 beta3-Gal-T or T-synthase, EC2.4.1.122)(2). Although O-glycans play important roles in vertebrates, much remains to be learned from model organisms such as the free-living nematode Caenorhabditis elegans, which offer many advantages in exploring O-glycan structure/function. Here we report the cloning and enzymatic characterization of T-synthase from C. elegans (Ce-T-synthase). A putative C. elegans gene for T-synthase, C38H2.2, was identified in GenBank by a BlastP search using the human T-synthase protein sequence. The full-length cDNA for Ce-T-synthase, which was generated by PCR using a C. elegans cDNA library as the template, contains 1,170 bp including the stop TAA. The cDNA encodes a protein of 389 amino acids with typical type-II membrane topology and a remarkable 42.7% identity to the human T-synthase. Ce-T-synthase has 7 Cys residues in the lumenal domain including 6 conserved Cys residues in all of the orthologs. The Ce-T-synthase has 4 potential N-glycosylation sequons, whereas the mammalian orthologs lack N-glycosylation sequons. Only one gene for Ce-T-synthase was identified in the genome-wide search and it contains 8 exons. Promoter analysis of the Ce-T-synthase using green fluorescent protein constructs show that the gene is expressed at all developmental stages and appears to be in all cells. Unexpectedly, only minimal activity was recovered in the recombinant, soluble Ce-T-synthase secreted from a wide variety of mammalian cell lines, whereas robust enzyme activity was recovered in the soluble Ce-T-synthase expressed in Hi-5 insect cells. Vertebrate T-synthase requires the molecular chaperone Cosmc, but our results show that Ce-T-synthase does not require Cosmc, and might require invertebrate-specific factors for formation of the optimally active enzyme. These results show that the Ce-T-synthase is a functional ortholog to the human T-synthase in generating core 1 O-glycans and opens new avenues to explore O-glycan function in this model organism.

Muir RE et al. (2007) Int J Syst Evol Microbiol "Leucobacter chromiireducens subsp. solipictus subsp. nov., a pigmented bacterium isolated from the nematode Caenorhabditis elegans, and emended description of L. chromiireducens."

Muir RE, Tan MW

[Int J Syst Evol Microbiol, 2007]

A yellow-pigmented, Gram-positive, aerobic, non-motile, non-spore-forming, irregular rod-shaped bacterium (strain TAN 31504(T)) was isolated from the bacteriophagous nematode Caenorhabditis elegans. Based on 16S rRNA gene sequence similarity, DNA G+C content of 69.5 mol%, 2,4-diaminobutyric acid in the cell-wall peptidoglycan, major menaquinone MK-11, abundance of anteiso- and iso-fatty acids, polar lipids diphosphatidylglycerol and phosphatidylglycerol and a number of shared biochemical characteristics, strain TAN 31504(T) was placed in the genus Leucobacter. DNA-DNA hybridization comparisons demonstrated a 91 % DNA-DNA relatedness between strain TAN 31504(T) and Leucobacter chromiireducens LMG 22506(T) indicating that these two strains belong to the same species, when the recommended threshold value of 70 % DNA-DNA relatedness for the definition of a bacterial species by the ad hoc committee on reconciliation of approaches to bacterial systematics is considered. Based on distinct differences in morphology, physiology, chemotaxonomic markers and various biochemical characteristics, it is proposed to split the species L. chromiireducens into two novel subspecies, Leucobacter chromiireducens subsp. chromiireducens subsp. nov. (type strain L-1(T)=CIP 108389(T)=LMG 22506(T)) and Leucobacter chromiireducens subsp. solipictus subsp. nov. (type strain TAN 31504(T)=DSM 18340(T)=ATCC BAA-1336(T)).

Agulnik SI et al. (1997) Genome "Three novel T-box genes in Caenorhabditis elegans."

Ruvinsky I, Agulnik SI, Silver LM

[Genome, 1997]

The T-box gene family consists of members that share a unique DNA binding domain. The best characterized T-box gene, Brachyury or T, encodes a transcription factor that plays an important role in early vertebrate development. Seven other recently described mouse T-box genes are also expressed during development. In the nematode Caenorhabditis elegans, four T-box genes have been characterized to date. In this study, we describe three new C. elegans T-box genes, named Ce-tbx-11, Ce-tbx-12, and Ce-tbx-17. Ce-tbx-11 and Ce-tbx-17 were uncovered through the sequencing efforts of the C. elegans Genome Project. Ce-tbx-12 was uncovered through degenerate PCR analysis of C. elegans genomic DNA. Ce-tbx-11 and Ce-tbx-17 are located in close proximity to the four other previously described T-box genes in the central region of chromosome III. In contrast, Ce-tbx-12 maps alone to chromosome II. Phylogenetic analysis of all known T-box domain sequences provides evidence of an ancient origin for this gene family.

Yang, F.-J. et al. (2017) International Worm Meeting "Site-specific single copy insertion of transgenes using phiC31 integrase in C. elegans."

Wang, J., Yang, F.-J., Chang, T.

[International Worm Meeting, 2017]

C. elegans has many tools for genome modification. However, the precise insertion of larger DNA constructs is still relatively laborious and difficult. In hopes of making large integrations at predetermined genomic sites easier, we have adapted the fC31 integrase system for use in C. elegans. We have integrated into the genome a codon-optimized version of fC31 that is expressed in the germline, and we have successfully used this strain to integrate three constructs in proof of principle experiments. In our hands, integration by fC31 appears easier than the selection based MosSCI insertion protocol. The largest construct tested thus far is only ~8 kb, and we are in the process of testing larger ones. Given its relative ease in generating integrants, the fC31 system may offer another useful option for transgene analysis and genome manipulation in C. elegans.