The Mec-8 Gene of Caenorhabditis Elegans Affects Muscle and Sensory Neuron Function and Interacts with Three Other Genes: Unc-52, Smu-1 and Smu-2

Mutations in the Caenorhabditis elegans gene mec-8 were previously shown to cause defects in mechanosensation and in the structure and dye filling of certain chemosensory neurons. Using noncomplementation screens, we have identified eight new mec-8 alleles and a deficiency that uncovers the locus. Strong mec-8 mutants exhibit an incompletely penetrant cold-sensitive embryonic and larval arrest, which we have correlated with defects in the attachment of body muscle to the hypodermis and cuticle. Mutations in mec-8 strongly enhance the mutant phenotype of unc-52(viable) mutations; double mutants exhibit an unconditional arrest and paralysis at the twofold stage of embryonic elongation, a phenotype characteristic of lethal alleles of unc-52, a gene previously shown to encode a homolog of the core protein of heparan sulfate proteogylcan, found in basement membrane, and to be involved in the anchorage of myofilament lattice to the muscle cell membrane. We have identified and characterized four extragenic recessive suppressors of a mec-8; unc-52(viable) synthetic lethality. The suppressors, which define the genes smu-1 and smu-2, can weakly suppress all mec-8 mutant phenes. They also suppress the muscular dystrophy conferred by an unc-52(viable) mutation.     

Mutations in the Unc-52 Gene Responsible for Body Wall Muscle Defects in Adult Caenorhabditis Elegans Are Located in Alternatively Spliced Exons

The unc-52 gene in Caenorhabditis elegans produces several large proteins that function in the basement membrane underlying muscle cells. Mutations in this gene result in defects in myofilament assembly and in the attachment of the myofilament lattice to the muscle cell membrane. The st549 and ut111 alleles of unc-52 produce a lethal (Pat) terminal phenotype whereas the e444, e669, e998, e1012 and e1421 mutations result in viable, paralyzed animals. We have identified the sequence alterations responsible for these mutant phenotypes. The st549 allele has a premature stop codon in exon 7 that should result in the complete elimination of unc-52 gene function, and the ut111 allele has a Tc1 transposon inserted into the second exon of the gene. The five remaining mutations are clustered in a small interval containing three adjacent, alternatively spliced exons (16, 17 and 18). These mutations affect some, but not all of the unc-52-encoded proteins. Thirteen intragenic revertants of the e669, e998, e1012 and e1421 alleles have also been sequenced. The majority of these carry the original mutation plus a G to A transition in the conserved splice acceptor site of the affected exon. This result suggests that reversion of the mutant phenotype in these strains may be the result of exon-skipping.     

UNC-52/perlecan affects gonadal leader cell migrations in C. elegans hermaphrodites through alterations in growth factor signaling

The unc-52 gene of Claenorhabditis elegans encodes a homologue of the basement membrane heparan sulfate proteoglycan perlecan. Viable alleles reduce the abundance of UNC-52 in late larval stages and increase the frequency of distal tip cell (DTC) migration defects caused by mutations disrupting the UNC-6/netrin guidance system. These unc-52 alleles do not cause circumferential DTC migration defects in an otherwise wild-type genetic background. The effects of unc-52 mutations on DTC migrations are distinct from effects on myofilament organization and can be partially suppressed by mutations in several genes encoding growth factor-like molecules, including EGL-17/FGF, UNC-129/TGF-beta, DBL-1/TGF-beta, and EGL-20/WNT. We propose that UNC-52 serves dual roles in C. elegans larval development in the maintenance of muscle structure and the regulation of growth factor-like signaling pathways.     

The Unc-8 and Sup-40 Genes Regulate Ion Channel Function in Caenorhabditis Elegans Motorneurons

Two Caenorhabditis elegans genes, unc-8 and sup-40, have been newly identified, by genetic criteria, as regulating ion channel function in motorneurons. Two dominant unc-8 alleles cause motorneuron swelling similar to that of other neuronal types in dominant mutants of the deg-1 gene family, which is homologous to a mammalian gene family encoding amiloride-sensitive sodium channel subunits. As for previously identified deg-1 family members, unc-8 dominant mutations are recessively suppressed by mutations in the mec-6 gene, which probably encodes a second type of channel component. An unusual dominant mutation, sup-41 (lb125), also co-suppresses unc-8 and deg-1, suggesting the existence of yet another common component of ion channels containing unc-8 or deg-1 subunits. Dominant, transacting, intragenic suppressor mutations have been isolated for both unc-8 and deg-1, consistent with the idea that, like their mammalian homologues, the two gene products function as multimers. The sup-40 (lb130) mutation dominantly suppresses unc-8 motorneuron swelling and produces a novel swelling phenotype in hypodermal nuclei. sup-40 may encode an ion channel component or regulator that can correct the osmotic defect caused by abnormal unc-8 channels.     

Regulation of the mec-3 gene by the C.elegans homeoproteins UNC-86 and MEC-3.

The mec-3 gene encodes a homeodomain protein with LIM repeats that is required for the specification of touch cell fate in Caenorhabditis elegans. Previous experiments suggested that mec-3 expression requires the product of the unc-86 gene, a POU-type homeoprotein, and mec-3 itself. We have analyzed the control of mec-3 expression by identifying potential cis regulatory elements in the mec-3 gene (by conservation in a related nematode and by DNase I footprinting using unc-86 and mec-3 proteins) and testing their importance by transforming C.elegans with mec-3lacZ fusions in which these sites have been mutagenized in vitro. Both unc-86 and mec-3 proteins bind specifically to the promoter of the mec-3 gene, suggesting that both proteins may be directly involved in the regulation of the mec-3 gene. In addition, the footprint pattern with mec-3 protein is altered in the presence of unc-86 protein. In vivo transformation experiments reveal that some of the binding regions of the two proteins are needed for general positive control and maintenance of mec-3 expression while others have no detectable, unique function. Interestingly, the unc-86 gene appears to be required not only to initiate mec-3 expression but also to maintain it.     

The UNC-112 gene in Caenorhabditis elegans encodes a novel component of cell-matrix adhesion structures required for integrin localization in the muscle cell membrane

Embryos homozygous for mutations in the unc-52, pat-2, pat-3, and unc-112 genes of C. elegans exhibit a similar Pat phenotype. Myosin and actin are not organized into sarcomeres in the body wall muscle cells of these mutants, and dense body and M-line components fail to assemble. The unc-52 (perlecan), pat-2 (alpha-integrin), and pat-3 (beta-integrin) genes encode ECM or transmembrane proteins found at the cell-matrix adhesion sites of both dense bodies and M-lines. This study describes the identification of the unc-112 gene product, a novel, membrane-associated, intracellular protein that colocalizes with integrin at cell-matrix adhesion complexes. The 720-amino acid UNC-112 protein is homologous to Mig-2, a human protein of unknown function. These two proteins share a region of homology with talin and members of the FERM superfamily of proteins.We have determined that a functional UNC-112::GFP fusion protein colocalizes with PAT-3/beta-integrin in both adult and embryonic body wall muscle. We also have determined that UNC-112 is required to organize PAT-3/beta-integrin after it is integrated into the basal cell membrane, but is not required to organize UNC-52/perlecan in the basement membrane, nor for DEB-1/vinculin to localize with PAT-3/beta-integrin. Furthermore, UNC-112 requires the presence of UNC-52/perlecan and PAT-3/beta-integrin, but not DEB-1/vinculin to become localized to the muscle cell membrane.     

胃癌细胞中Ras基因的表达、突变分析及新剪接型Kras△E2的发现

目的：传统Ras家族由Kras,Hras和Nras基因组成,这类基因的点突变经常在人类肿瘤中发现,突变热点位于12,13,61位密码子。ERas基因是2003年在鼠胚胎干（ES）细胞中发现的,其cDNA编码的蛋白与Kras,Hras和Nras分别有46％,43％和47％的相似性,故属于新的Ras家族成员,近几年发现ERas基因的表达与胃癌密切相关,而传统Ras基因在胃癌细胞中的表达及突变情况系统报道较少,本文旨在研究传统Ras基因Kras,Hras,Nras及其家族新成员ERas基因在胃癌细胞中的表达和突变情况。方法：选用7株不同来源不同分化程度的胃癌细胞系,利用RT—PCR及real-timePCR检测Ras基因在这些胃癌细胞系中的表达,并通过测序对传统Ras基因突变热点12,13,61位密码子及ERas基因全长进行突变分析。结果：QRas基因在这些胃癌细胞系中均有不同程度的表达,其中Hras和Nms基因在各株细胞中表达水平均一,而Kras和ERas基因则呈差异性表达;②在这些胃癌细胞中传统Ras基因突变热点12,13,61位密码子不存在突变,ERas基因全长亦未检测到突变．③发现Kras基因一新的剪接型,特点为第一、三外显子直接拼接,缺失第二外显子,命名为Kras△E2。结论：与在其他肿瘤中不同,传统Ras基因在胃癌细胞中不存在突变热点,家族新成员ERas基因全长亦无突变,在国际上首次报道新剪接型Kras△E2,从而得出创新性结论：Ras基因家族在胃癌细胞中并不是通过热点突变导致持续活化而致癌,而可能是通过ERas基因表达量的调节或形成新的剪接型KrasAE2而致癌。另外,Kras基因是一被受国际关注的肿瘤基因,新剪接型的发现可能会对Kras基因致癌机制产生新的认识,意义重大。     

Mutations Affecting Acetylcholine Levels in the Nematode Caenorhabditis elegans

Gene cha-1.unc-17 of the nematode Caenorhabditis elegans is a complex gene, consisting of at least two complementation groups. One part (cha-1 region) of the gene encodes the enzyme choline acetyltransferase (ChAT), but the function of the other part (unc-17 region) is still unclear. We measured the ChAT activity and ACh levels of the cha-1 and unc-17 complex gene mutants. We show here that alterations in ACh levels, rather than the ChAT activity, reflect abnormal phenotypes accompanying cha-1.unc-17 mutations, that is, the decreased ACh levels in cha-1 mutations and abnormal accumulation in unc-17 mutations. Our results suggest that the unc-17 region may encode functions necessary for storage and/or release of ACh at the presynaptic level.     

Resistance to volatile anesthetics by mutations enhancing excitatory neurotransmitter release in Caenorhabditis elegans

The molecular mechanisms whereby volatile general anesthetics (VAs) disrupt behavior remain undefined. In Caenorhabditis elegans mutations in the gene unc-64, which encodes the presynaptic protein syntaxin 1A, produce large allele-specific differences in VA sensitivity. UNC-64 syntaxin normally functions to mediate fusion of neurotransmitter vesicles with the presynaptic membrane. The precise role of syntaxin in the VA mechanism is as yet unclear, but a variety of results suggests that a protein interacting with syntaxin to regulate neurotransmitter release is essential for VA action in C. elegans. To identify additional proteins that function with syntaxin to control neurotransmitter release and VA action, we screened for suppressors of the phenotypes produced by unc-64 reduction of function. Loss-of-function mutations in slo-1, which encodes a Ca(2+)-activated K+ channel, and in unc-43, which encodes CaM-kinase II, and a gain-of-function mutation in egl-30, which encodes Gqalpha, were isolated as syntaxin suppressors. The slo-1 and egl-30 mutations conferred resistance to VAs, but unc-43 mutations did not. The effects of slo-1 and egl-30 on VA sensitivity can be explained by their actions upstream or parallel to syntaxin to increase the level of excitatory neurotransmitter release. These results strengthen the link between transmitter release and VA action.     

Functional overlap between the mec-8 gene and five sym genes in Caenorhabditis elegans.

Earlier work showed that the Caenorhabditis elegans gene mec-8 encodes a regulator of alternative RNA splicing and that mec-8 null mutants have defects in sensory neurons and body muscle attachment but are generally viable and fertile. We have used a genetic screen to identify five mutations in four genes, sym-1-sym-4, that are synthetically lethal with mec-8 loss-of-function mutations. The phenotypes of sym single mutants are essentially wild type. mec-8; sym-1 embryos arrest during embryonic elongation and exhibit defects in the attachment of body muscle to extracellular cuticle. sym-1 can encode a protein containing a signal sequence and 15 contiguous leucine-rich repeats. A fusion of sym-1 and the gene for green fluorescent protein rescued the synthetic lethality of mec-8; sym-1 mutants; the fusion protein was secreted from the apical hypodermal surface of the embryo. We propose that SYM-1 helps to attach body muscle to the extracellular cuticle and that another gene that is dependent upon mec-8 for pre-mRNA processing overlaps functionally with sym-1. RNA-mediated interference experiments indicated that a close relative of sym-1 functionally overlaps both sym-1 and mec-8 in affecting muscle attachment. sym-2, sym-3, and sym-4 appear to provide additional functions that are essential in the absence of mec-8(+).     

Dominant Unc-37 Mutations Suppress the Movement Defect of a Homeodomain Mutation in Unc-4, a Neural Specificity Gene in Caenorhabditis Elegans

The unc-4 gene of Caenorhabditis elegans encodes a homeodomain protein that defines synaptic input to ventral cord motor neurons. unc-4 mutants are unable to crawl backward because VA motor neurons are miswired with synaptic connections normally reserved for their sister cells, the VB motor neurons. These changes in connectivity are not accompanied by any visible effects upon neuronal morphology, which suggests that unc-4 regulates synaptic specificity but not axonal guidance or outgrowth. In an effort to identify other genes in the unc-4 pathway, we have devised a selection scheme for rare mutations that suppress the Unc-4 phenotype. We have isolated four, dominant, extragenic, allele-specific suppressors of unc-4(e2322ts), a temperature sensitive allele with a point mutation in the unc-4 homeodomain. Our data indicate that these suppressors are gain-of-function mutations in the previously identified unc-37 gene. We show that the loss-of-function mutation unc-37(e262) phenocopies the Unc-4 movement defect but does not prevent unc-4 expression or alter VA motor neuron morphology. These findings suggest that unc-37 functions with unc-4 to specify synaptic input to the VA motor neurons. We propose that unc-37 may be regulated by unc-4. Alternatively, unc-37 may encode a gene product that interacts with the unc-4 homeodomain.     

APC mutation in the alternatively spliced region of exon 9 associated with late onset familial adenomatous polyposis

Germ-line mutations in the adenomatous polyposis coli (APC) gene are responsible for familial adenomatous polyposis (FAP). Genotype-phenotype correlation studies in patients with FAP have demonstrated associations of certain variants of the disease with mutations at specific sites within the APC gene. In a large FAP family, we identified a frameshift mutation located in the alternatively spliced region of exon 9. Phenotypic studies of affected family members showed that the clinical course of FAP was delayed, with gastrointestinal symptoms and death from colorectal carcinoma occurring on average 25 and 20 years later than usual, respectively. The numbers of colorectal adenomas differed markedly among affected individuals and the location of colorectal cancer lay frequently in the proximal colon. Our findings suggest that the exon 9 mutation identified in the pedigree is associated with late onset of FAP. The atypical phenotype may be explained by the site of the mutation in the APC gene. Analysis of the APC protein product indicated that the exon 9 mutation did not result in a detectable truncated APC protein. Given the location of the mutation within an alternatively spliced exon of APC, it is conceivable that normal APC proteins are produced from the mutant allele by alternative splicing.     

Expression of cDNAs encoding mouse cardiac troponin T isoforms: characterization of a large sample of independent clones

We have isolated 52 mouse cardiac troponin-T-encoding cDNA clones (TnT) by specific antibody screening of a λZAPII expression library. Sequencing data from the large sample of independent cDNAs demonstrated relationships among the expression of four alternatively-spliced exons of the cardiac TnT gene, producing seven classes of cDNAs encoding four protein isoforms differing in two variable regions. In the N-terminal variable region and next to the embryonic-specific exon 4, an alternatively spliced exon 3a was identified in 20% of the adult isoforms. The alternatively spliced exon 12, corresponding to a central variable region between the two functional domains of TnT, was found in approx. 79% of the 52 mouse cardiac TnT cDNAs with a single base mutation completely abolishing the splicing at an internal acceptor site. Three novel alternative splicing acceptor sites in the 5'-untranslated portion of exon 2 have been identified with different frequencies.     

Alternative splicing of exon 17 and a missense mutation in exon 20 of the insulin receptor gene in two brothers with a novel syndrome of insulin resistance (congenital fiber-type disproportion myopathy)

The insulin receptor (IR) in two brothers with a rare syndrome of congenital muscle fiber type disproportion myopathy (CFTDM) associated with diabetes and severe insulin resistance was studied. By direct sequencing of Epstein-Barr virus-transformed lymphocytes both patients were found to be compound heterozygotes for mutations in the IR gene. The maternal allele was alternatively spliced in exon 17 due to a point mutation in the -1 donor splice site of the exon. The abnormal skipping of exon 17 shifts the amino acid reading frame and leads to a truncated IR, missing the entire tyrosine kinase domain. In the correct spliced variant, the point mutation is silent and results in a normally translated IR. The paternal allele carries a missense mutation in the tyrosine kinase domain. All three cDNA variants were present in the lymphocytes of the patients. Purified IR from 293 cells overexpressing either of the two mutated receptors lacked basal or stimulated IR beta-subunit autophosphorylation. A third brother who inherited both normal alleles has an normal muscle phenotype and insulin sensitivity, suggesting a direct linkage of these IR mutations with the CFTDM phenotype.