Expression profiles and unc-27 mutation rescue of the striated muscle type troponin I isoform-3 in Caenorhabditis elegans.

Transcription control of multiple genes in tissue- and stage-specific patterns is still of major interest. We show here that troponin I (TNI) is expressed under the control of upstream non-coding sequences and had functions as an isoform of intermediate type between pharynx and body-wall of the gene. In Caenorhabditis elegans, three striated muscle TNIs are expressed in body-wall muscles and a cardiac isoform is expressed in the pharynx. We have analyzed the gene expression mechanisms of tni-3 gene and motility function of its protein product. Promoter deletion analysis of the tni-3 gene identified muscle enhancers including the head enhancer. The CBF1/Su(H)/LAG-1-binding motif was included in the head enhancer. Yeast one-hybrid screening isolated the lag-1 clone in five candidates. Functional differences between the three striated muscle TNIs were investigated by the expression of promoter-fusion genes into tni-2/unc-27(e155) null mutant animals. The results suggest that the cis-elements in the promoters of the three genes are important for their tissue-specific expression and that from the function of TNI-3, the tni-3 gene would be an intermediate in the evolution of these genes by gene duplication. Mechanisms of tni-3 expression and its molecular function may contribute to our understanding of gene evolution and developmental programs.

Cytomegalovirus disease during severe drug eruptions: report of 2 cases and retrospective study of 18 patients with drug-induced hypersensitivity syndrome.

BACKGROUND: Overt cytomegalovirus (CMV) disease is a serious viral infection that usually occurs in immunocompromised patients but rarely in immunocompetent patients. Cutaneous lesions, albeit rare, occur as late systemic manifestations of CMV infections and are usually fatal. OBSERVATIONS: We describe 2 patients with drug-induced hypersensitivity syndrome (one end of a spectrum of severe drug eruptions) who subsequently developed cutaneous CMV ulcers at unusual sites, such as the trunk; this occurrence was immediately followed by gastrointestinal manifestations, which were fatal in 1 patient. To identify factors predictive of CMV disease, we retrospectively investigated the prevalence of CMV reactivation during drug-induced hypersensitivity syndrome in 18 patients. In this analysis, patients were divided into 2 groups depending on the positivity of CMV DNA in the blood. CONCLUSIONS: Older and male patients with antecedent high human herpesvirus 6 DNA loads are at risk for CMV disease irrespective of corticosteroid administration. A rapid reduction in white blood cell numbers is also predictive of the onset of CMV disease.

Transcription factors GATA/ELT-2 and forkhead/HNF-3/PHA-4 regulate the tropomyosin gene expression in the pharynx and intestine of Caenorhabditis elegans.

Gene regulation during development is an important biological activity that leads to synthesis of biomolecules at specific locations and specific times. The single tropomyosin gene of Caenorhabditis elegans, tmy-1/lev-11, produces four isoforms of protein: two from the external promoter and two from the internal promoter. We investigated the internal promoter of tropomyosin to identify sequences that regulate expression of tmy-1 in the pharynx and intestine. By promoter deletion of tmy-1 reporters as well as by database analyses, a 100-bp fragment that contained binding sequences for a GATA factor, for a chicken CdxA homolog, and for a forkhead factor was identified. Both the forkhead and CdxA binding sequences contributed to pharyngeal and intestinal expression. In addition, the GATA site also influenced intestinal expression of tmy-1 reporter. We showed that ELT-2 and PHA-4 proteins interact directly with the GATA and forkhead binding sequences, respectively, in gel mobility shift assays. RNA interference knockdown of elt-2 diminished tmy-1::gfp expression in the intestine. In contrast to RNA interference knockdown of pha-4, expression of tmy-1::gfp in pha-4;smg-1 mutants was slightly weaker than that of the wild type. Ectopic expression of PHA-4 and ELT-2 by heat shock was sufficient to elicit widespread expression of tmy-1::lacZ reporter in embryos. We found no indication of a synergistic relation between ELT-2 and PHA-4. Based on our data, PHA-4 and CdxA function as general transcription factors for pharyngeal and intestinal regulation of tmy-1. We present models by which ELT-2, PHA-4, and CdxA orchestrate expression from the internal promoter of tmy-1.

Functional importance of polymerization and localization of calsequestrin in C. elegans.

Dual roles of calsequestrin (CSQ-1) being the Ca2+ donor and Ca2+ acceptor make it an excellent Ca2+-buffering protein within the sarcoplasmic reticulum (SR). We have isolated and characterized a calsequestrin (csq-1)-null mutant in Caenorhabditis elegans. To our surprise, this mutant csq-1(jh109) showed no gross defects in muscle development or function but, however, is highly sensitive to perturbation of Ca2+ homeostasis. By taking advantage of the viable null mutant, we investigated the domains of CSQ-1 that are important for polymerization and cellular localization, and required for its correct buffering functions. In transgenic animals rescued with various CSQ-1 constructs, the in vivo patterns of polymerization and localization of several mutated calsequestrins were observed to correlate with the structure-function relationship. Our results suggest that polymerization of CSQ-1 is essential but not sufficient for correct cellular localization and function of CSQ-1. In addition, direct interaction between CSQ-1 and the ryanodine receptor (RyR) was found for the first time, suggesting that the cellular localization of CSQ-1 in C. elegans is indeed modulated by RyR through a physical interaction.

Tissue-specific interactions of TNI isoforms with other TN subunits and tropomyosins in C. elegans: the role of the C- and N-terminal extensions.

The aim of this study is to investigate the function of the C-terminal extension of three troponin I isoforms, that are unique to the body wall muscles of Caenorhabditis elegans and to understand the molecular interactions within the TN complex between troponin I with troponin C/T, and tropomyosin. We constructed several expression vectors to generate recombinant proteins of three body wall and one pharyngeal troponin I isoforms in Escherichia coli. Protein overlay assays and Western blot analyses were performed using antibodies. We demonstrated that pharyngeal TNI-4 interacted with only the pharyngeal isoforms of troponin C/T and tropomyosin. In contrast, the body wall TNI-2 bound both the body wall and pharyngeal isoforms of these components. Similar to other invertebrates, the N-terminus of troponin I contributes to interactions with troponin C. Full-length troponin I was essential for interactions with tropomyosin isoforms. Deletion of the C-terminal extension had no direct effect on the binding of the body wall troponin I to other muscle thin filament troponin C/T and tropomyosin isoforms.

A novel non-coding DNA family in Caenorhabditis elegans.

Many repetitive elements, for example, SINEs, LINEs, LTR-retrotransposons and other SSRs are dispersed throughout eukaryotic genomes. To understand the biological function of these repetitive elements is of great current research interest. In this study, we report on the identification of a novel non-coding DNA family, designated CE1 family, in the nematode C. elegans genome. Some CE1 elements constituted a large palindrome sequence. The CE1 elements were interspersed at 95 sites in the C. elegans genome. Most of the CE1 elements were associated with, or were within, protein-coding genes. The sequence of the CE1 elements indicated that some could form a hairpin structure. One of the CE1 family, CE1(bs258), is located in the first intron of a novel gene, C46H11.6 which encodes a PDZ/DHR/GLGF domain protein. In gfp and lacZ reporter gene assays the CE1(bs258) element appeared to behave as an enhancer element for the expression of C46H11.6 but no effect on the expression of the opposite direction gene, pat-10 which encodes the body-wall muscle troponin C. The CE1(bs258) RNA transcript was detected by RT-PCR even when CE1(bs258) was located in an intron. We conclude that CE1 elements are involved in the expression of adjacent genes and are therefore selectively retained in the C. elegans genome. We discussed a biological function of the CE1(bs258) having many transcription factor-binding sites.

Biochemical and Molecular Biological Analyses of space-flown nematodes in Japan, the First International Caenorhabditis elegans Experiment (ICE-First).

The first International Caenorhabditis elegans Experiment (ICE-First) was carried out using a Russian Soyuz spacecraft from April 19-30, 2004. This experiment was a part of the program of the DELTA (Dutch Expedition for Life science Technology and Atmospheric research) mission, and the space agencies that participate in the International Space Station (ISS) program formed international research teams. A Japanese research team that conducted by Japan aerospace Exploration Agency (JAXA) investigated the following aspects of the organism: (1) whether meiotic chromosomal dynamics and apoptosis in the germ cells were normal under microgravity conditions, (2) the effect of the space flight on muscle cell development, and (3) the effect of the space flight on protein aggregation. In this article, we summarize the results of these biochemical and molecular biological analyses.

VHA-8, the E subunit of V-ATPase, is essential for pH homeostasis and larval development in C. elegans.

Vacuolar H+-ATPase (V-ATPase) is an ATP-dependent proton pump, which transports protons across the membrane. It is a multi-protein complex which is composed of at least 13 subunits. The Caenorhabditis elegans vha-8 encodes the E subunit of V-ATPase which is expressed in the hypodermis, intestine and H-shaped excretory cells. VHA-8 is necessary for proper intestinal function likely through its role in cellular acidification of intestinal cells. The null mutants of vha-8 show a larval lethal phenotype indicating that vha-8 is an essential gene for larval development in C. elegans. Interestingly, characteristics of necrotic cell death were observed in the hypodermis and intestine of the arrested larvae suggesting that pH homeostasis via the E subunit of V-ATPase is required for the cell survival in C. elegans.

The homeoproteins MAB-18 and CEH-14 insulate the dauer collagen gene col-43 from activation by the adjacent promoter of the Spermatheca gene sth-1 in Caenorhabditis elegans.

Genome searches in this study indicate that the nematode Caenorhabditis elegans genome has 2582 bidirectionally oriented genes that account for more than 25% of the total genes. We analyze the transcriptional repression system for one of these predicted bidirectional promoters, which controls the expression of the spermathecal gene sth-1 and collagen gene col-43. These two genes are separated by 1.3 kb and are transcribed bidirectionally. sth-1 is expressed in spermatheca after the L4 stage and col-43 is expressed in the hypodermal cells of the L2d dauer stage. The upstream regions required for the expression of sth-1 and col-43 shared an overlapped control sequence. Two homeoproteins, MAB-18 and CEH-14, were isolated by yeast one-hybrid screening as binding proteins of the overlapped region. MAB-18 bound to two homeodomain-binding sites and interacted with CEH-14 to repress col-43 expression in spermatheca. These results indicate that the two homeoproteins interact with each other to repress col-43 expression in sth-1-expressing tissues. This is the first report of bidirectional gene regulation analysis in the C.elegans genome.

Tissue expression of four troponin I genes and their molecular interactions with two troponin C isoforms in Caenorhabditis elegans.

Gene duplication is a major genetic event that can produce multiple protein isoforms. Comparative sequence and functional analysis of related gene products can provide insights into protein family evolution. To characterize the Caenorhabditis elegans troponin I family, we analyzed gene structures, tissue expression patterns and RNAi phenotypes of four troponin I isoforms. Tissue expression patterns were determined using lacZ/gfp/rfp reporter gene assays. The tni-1, tni-2/unc-27 and tni-3 genes, each encoding a troponin I isoform, are uniquely expressed in body wall, vulval and anal muscles but at different levels; tni-4 was expressed solely in the pharynx. Expressing tni-1 and -2 gene RNAi caused motility defects similar to unc-27 (e155) mutant, a tni-2 null allele. The tni-3 RNAi expression produced egg laying defects while the tni-4 RNAi caused arrest at gastrulation. Overlay analyses were used to assay interactions between the troponin I and two troponin C isoforms. The three body wall troponin I isoforms interacted with body wall and pharyngeal troponin C isoforms; TNI-4 interacted only with pharyngeal troponin C. Our results suggest the body wall genes have evolved following duplication of the pharynx gene and provide important data about gene duplication and functional differentiation of nematode troponin I isoforms.

Cultivation and characterization of planarian neuronal cells isolated by fluorescence activated cell sorting (FACS).

Studies using molecular markers have revealed that planarians possess a highly organized brain. Here we separated brain neurons from dissociated planarian head cells by fluorescence activated cell sorting (FACS), and characterized them by single cell PCR analysis and cell culture. Dissociated cells were labeled with three different fluorescent dyes, Hoechst 33258, Merocyanine 540, and Propidium Iodide (PI), and fractioned by FACS. Interestingly, we have succeeded in identifying a cell fraction specific to the head, which we have named the head-abundant cell fraction (HAC). Most of the HAC expressed neuron-specific genes and proteins. When they were cultured in vitro, they showed an ability to extend neurites on several types of extracellular matrices (ECMs), and, depending on the ECM type used, presented a high level of plasticity in morphology and gene expression.

Molecular dissection, tissue localization and Ca2+ binding of the ryanodine receptor of Caenorhabditis elegans.

The ryanodine receptor of Caenorhabditis elegans (CeRyR) which contains 5,071 amino acid residues, is encoded by a single gene, ryr-1/unc-68. The unc-68(kh30) mutation, isolated in an animal showing abnormal response to the anesthetic ketamine, has the substitution Ser1444Asn in CeRyR, predicted to be a phosphorylation site. To elucidate the function of the region of CeRyR, and to determine the localization of CeRyR in this animal, ten region-peptides were produced in Escherichia coli by using expression plasmids and eight antisera were raised against these fusion peptides. One antibody against the region corresponding to the kh30 mutation site enabled detection of CeRyR from mutant animals both in Western analysis and in situ. Specificity of this antiserum was demonstrated using Western analysis, which showed the full size and the partial size bands in wild-type and in the Tc1-induced deletion mutant animals, respectively, but no corresponding bands in unc-68 null mutant animals. CeRyR was detected in I-bands of muscle sarcomeres by double immunostaining. CeRyR was found in the body wall, pharyngeal, vulval, anal and sex muscles of adult worms and also found to be present in embryonic muscle, but not in non-muscle cells. Two EF-hand motifs and the C terminus were demonstrated to be Ca(2+) binding regions. On the basis of these results, we propose a model for the functional domains of CeRyR, which agrees well with the model of mammalian skeletal RyR, which is based on proteolysis and cross-linking analysis. We discuss the usefulness and limitations of the molecular dissection approach, which uses peptides and peptide-specific antibodies to determine the local structure and function of individual domains within a large molecule.