Plenefisch JD et al. (1994) Worm Breeder's Gazette "Cloning mua-3: Some Observations on the New Molecular Era"

Plenefisch JD, Hedgecock EM

[Worm Breeder's Gazette, 1994]

Cloning mua-3: some observations on the new Molecular Era John Plenefisch and Edward Hedgecock, Dept. of Biology, Johns Hopkins University, Baltimore MD 21218

Kipreos ET et al. (1992) Worm Breeder's Gazette "Cloning of the C. elegans Tumor Suppressor Genes lin-19 and lin-23"

Hedgecock EM, Kipreos ET

[Worm Breeder's Gazette, 1992]

Cloning of the C. elegans tumor suppressor genes lin-l9 and lin-23. Edward T. Kipreos and Edward M. Hedgecock Department of Biology, Johns Hopkins University, Baltimore, MD 21218

David Yu et al. (2001) International C. elegans Meeting "Characterization of Several G protein-coupled Receptors for the Secretin Family of Neuropeptides"

David Yu, Edward Hedgecock

[International C. elegans Meeting, 2001]

The secretin family of neuropeptides includes several physiologically essential molecules: secretin, calcitonin, corticotrophin releasing factor, and glucagon. In humans, defects in receptors of the secretin family cause abnormal function in the liver and pancreas, leading to several gastrointestinal diseases. To better understand the molecular biology of these receptors, we have identified three novel genes in C. elegans that are possible orthologues to the human secretin family receptors using BLAST and ESTs: ZK643.3, C18B12.2, and C13B9.4. These genes exhibit a high level of conservation with mammalian and fly secretin family receptors. Amino acid alignments suggest ZK643.3 is homologous to human corticotrophin releasing factor receptor, C13B9.4 is homologous to human calcitonin receptor, and C18B12.2 is homologous to human secretin receptor (see poster by Mastwal and Hedgecock). Previous work has shown that ZK643.3 is expressed in the muscle cells of the head and in muscle cells that control opening and closing of the vulva (Coates, 1995). To further characterize this gene, we generated a ZK643.3 promoter::GFP fusion construct. We observed expression in head muscle cells and pharyngeal and ventral nerve cord neurons. RNAi and co-immunoprecipitation of ZK643.3, as well as C13B9.4 and C18B12.2 will provide further insight to the function of this secretin receptor family and identify interacting proteins.

Surjeet Mastwal et al. (2001) International C. elegans Meeting "Evolution and function of the serpentine receptors of the secretin family"

Edward Hedgecock, Surjeet Mastwal

[International C. elegans Meeting, 2001]

The secretin family of serpentine receptors is an ancient family that has members in C. elegans, Drosophila, and vertebrates . Our alignment data suggests at least five member genes in the common ancestor of these lineages. Further duplications of each of the genes within the individual lineages lead to further expansion of the family . The five subfamily branches with their C. elegans members are flamingo-cefla(f15b9.7), latrophilin(lat-1(b0457.1) and lat-2(b0286.2)), calcitonin receptor(c13b9.4), corticotrophin releasing factor receptor(zk643.3), and secretin receptor(c18b12.2). Most of the studied members of this family are involved in regulated secretion in response to a peptide ligand. We are currently attempting to understand the organismal biology of this family in C. elegans by expression and phenotypic analysis and by linking these receptors to the peptide ligands that activate them. One of the aspects that we are focusing on is the latrophilin subfamily. Lat-1 expression starts after gastrulation and continues into the adult. It is expressed in the hypodermal, pharyngeal and some neuronal cells in the embryo. During larval development it is expressed in mechanosensory and interneurons in the head and tail, gland cell in pharynx, gonadal sheath cells, spermatheca, uterine epithelial cells and intestinal cells. We are focusing on the following aspects of the expression pattern: expression in alternating dorsal hypodermal cells during intercalation, expression and localization to the apical surface in the pharyngeal primordium cells, expression in ventral cord neurons and gland cell in the dauer, and expression in the reproductive organs. Phenotypes from RNAi have correlated with some of these expression patterns. These include elongation defects, abnormal pharyngeal development and attachment, small eggs, and ovulation defects in the injected animal. Lat-2 is expressed in the g1 gland cell and arcade cells in the head in which it localizes to the syncitial end of the process, and the expression cycles with the molts.

Surjeet Mastwal et al. (2003) International Worm Meeting "Latrophilins:Synaptic proteins with novel epithelial function in C elegans, and evolution of family B g-protein coupled receptors"

Edward Hedgecock, Surjeet Mastwal

[International Worm Meeting, 2003]

Latrophilins are cell surface proteins coupling an extracellular cell adhesion/interaction domain to a family B g-protein coupled receptor (GPCR) signaling domain. In vertebrates, multiple highly alternatively spliced paralogs exist and are expressed in the nervous system with synaptic localization. The C elegans orthologs, lat-1 and lat-2, have similar overall protein structure, but unlike the vertebrate orthologs are not highly alternatively spliced with only lat-1 having two isoforms. We see lat-1 expression in two main cell types: developing epithelia and neurons, localizing to the apical and presynaptic surfaces respectively. RNAi and deletion mutants show defects in embryonic elongation, pharyngeal development and reproductive organ formation, correlating with the expression in the epithelium of these tissues. In comparison, lat-2 expression is limited to the arcade and g1 gland cells with expression cycling during the molting period. Our data suggests a role for lat-1, and possibly lat-2, in the cell surface organization/reorganization of epithelial cells during development, possibly by selective targeting of exocytic vesicles, with a similar role at the synapses. In total, we have identified eight family B GPCR genes in C elegans: flamingo (fmi-1/F15b9.7), two latrophilin-related proteins (lat-1/B0457.1, lat-2/B0286.2), two methuselah-related proteins (mth-1/F31D5.5, mth-2/F31D5.4), and three presumptive hormone receptors (seb-1/C13B9.4, seb-2/ZK643.4, seb-3/C18B12.2). We have characterized the genomic structure by sequencing cDNAs and RT-PCR, evolution by sequence and domain comparisons, and expression of these genes. Our analysis of the evolution of this family indicates major alterations of domain structure and several duplication events prior to the metazoan radiation, leaving at least five orthologus branches between C elegans and H sapiens. In addition, our analysis of the family B members in recently duplicated species give a glimpse of the ongoing evolutionary processes that are occurring in these genes.

Surjeet Mastwal et al. (2002) East Coast Worm Meeting "Evolution and fuction of the secretin family of serpentine receptors"

Edward Hedgecock, David Yu, Surjeet Mastwal

[East Coast Worm Meeting, 2002]

The secretin family of serpentine receptors is an ancient family that has members in C. elegans, Drosophila, and vertebrates . Our alignment data suggests at least five member genes in the common ancestor of these lineages. Further duplications of each of the genes within the individual lineages lead to further expansion of the family . The five subfamily branches with their C. elegans members are flamingo-cefla(f15b9.7), latrophilin(lat-1(b0457.1) and lat-2(b0286.2)), calcitonin receptor(c13b9.4), corticotrophin releasing factor receptor(zk643.3), and secretin receptor(c18b12.2). Most of the studied members of this family are involved in regulated secretion in response to a peptide ligand. We are currently attempting to understand the organismal biology of this family in C. elegans by expression and phenotypic analysis and by linking these receptors to the peptide ligands that activate them. One of the aspects that we are focusing on is the latrophilin subfamily. Lat-1 expression starts after gastrulation and continues into the adult. It is expressed in the hypodermal, pharyngeal and some neuronal cells in the embryo. During larval development it is expressed in mechanosensory and interneurons in the head and tail, gland cell in pharynx, gonadal sheath cells, spermatheca, uterine epithelial cells and intestinal cells. We are focusing on the following aspects of the expression pattern: expression in alternating dorsal hypodermal cells during intercalation, expression and localization to the apical surface in the pharyngeal primordium cells, expression in ventral cord neurons and gland cell in the dauer, and expression in the reproductive organs. Phenotypes from RNAi have correlated with some of these expression patterns. These include elongation defects, abnormal pharyngeal development and attachment, small eggs, and ovulation defects in the injected animal. Lat-2 is expressed in the g1 gland cell and arcade cells in the head in which it localizes to the syncitial end of the process, and the expression cycles with the molts.

Yuanmei Zuo et al. (2008) "Cadherin Superfamily Proteins in Caenorhabditis elegans and Caenorhabditis briggsae"

Surjeet Mastwal, Yuanmei Zuo, Edward Hedgecock

[2008]

"Analysis of the complete genome of Caenorhabditis elegans has revealed a small, stable and ancient cadherin family comprising 12 genes. The soil nematodes C. elegans and C. briggsae diverged from a common ancestor roughly 100 million years ago but still retain strong morphological and genetic similarities such as identical chromosome numbers, similar genome sizes, significant levels of synteny as well as high sequence homology in genic regions. We used reciprocal C. elegans/briggsae cadherin sequence comparisons to identify additional C. elegans exons, modify exon boundaries, remove incorrectly predicted exons, which lead to the modification of 6 of the 12 C. elegans cadherin gene structures. Additionally, twelve orthologous genes were identified in C. briggsae. We observed size differences between the C. elegans and C. briggsae genes that are attributed to intron size change. Remarkably, the kinds and number of protein modules and their organization is nearly identical in the 12 C. briggsae/elegans orthologous pairs. Eleven changes in cysteine number and position in the extracellular regions have occurred indicating evolutionary changes in the folding of the orthologous C.elegans/briggsae proteins.The 12 cadherins proteins show high sequence conservation in C.elegans and C. briggsae, except CDH-3 , CDH-10 and CDH-12 .Mutational events such as these repeats, indels and substitutions have caused these protein regions to diverge radically. Our sequence data from other Caenorhabditis strains CB5161 and PB212 also show a drastic difference in these regions, supporting the conjecture that rapid change is an intrinsic property of these regions.Our phylogenetic analysis suggests that the 12 C.elegans cadherin genes belong in 7 likely orthologous branches shared in common with other metazoans. Notably, sequence similarity, domain organization and phylogenetic analysis allow us to make several novel assignments of Drosophila cadherins as orthologs of C. elegans cadherins while confirming previously known relationships.Keywords: cadherin, genomic structure, protein evolution, phylogenetic analysis."

Guo C-B et al. (1994) Worm Breeder's Gazette "mig-5, A Gene Required For Both Cell Migration and Cell Fate Determination"

Guo C-B, Hedgecock EM

[Worm Breeder's Gazette, 1994]

mig-5, A GENE REQUIRED FOR BOTH CELL MIGRATION AND CELL FATE DETERMINATION Chaobo Guo and Edward Hedgecock, Department of Biology, Johns Hopkins University, Baltimore, MD 21218 Cell migration and cell fate determination are two important and interdependent events during animal development. In mig-5 mutants, we observe abnormal migrations and transformation in cell fates in a variety of lineages. The descendants of the QL neuroblast fail to migrate posteriorly, but migrate anteriorly instead. Distal tip cells (DTCs) leading the gonad arms make precocious dorsal turns or migrate along abnormal tracks. DTCs are frequently missing and occasionally a third DTC is present. Rarely, two anchor cells are present in the the aphrodite gonad and often two linker cells are present in the male. In vulval equivalence group, one or two secondary vulval precursor cells (VPCs) are often missing, and in the pre-anal equivalence group, P12 usually adopts a P11 like secondary fate rather than its normal primary fate. Interestingly, in mig-5, both cell migration and cell fate are affected in single type of cell (DTC). We have two EMS-induced alleles of mig-5, rh94 and rhl47. rhl47 is the stronger allele. The DTC phenotype of rhl47/Df is similar to that of rhl47 homozygotes, consistent with the possibility that rhl47 is a null allele. The mig-5 mutation shows both maternal and zygotic sufficiency at least for Q cell and DTC phenotypes. Preliminary data also suggest that the mig-5 DTC phenotype is temperature-sensitive in both alleles. mig-5 is immediately right of fer-15 and emb-27 on LGII in a region covered by cosmids or YACs. In deficiency tests, mig-5 is complemented by mnDf91, 92, 94, 97, 98 and 109, but not complemented by mnDf84, 93, 99, 101, 103, 104, 106 and 108. So far, we have used the cosmids spanning the left half of the zyg-ll--zyg-9 region as probes looking for the deficiency endpoints. In addition to the Southern analysis, PCR and cosmid rescue techniques are also being used in the effort to clone the mig-5 gene.

Toshia Myers et al. (2003) International Worm Meeting "What is the cellular focus of lin-35 Rb?"

Iva Greenwald, Toshia Myers

[International Worm Meeting, 2003]

Class A and class B synthetic Multivulva (synMuv) genes function in genetically redundant pathways to inhibit vulval fate specification. While the exact mechanism of inhibition in C. elegans is unknown, many synMuv genes encode proteins that have been implicated in transcriptional repression in other systems, such as the class B synMuv gene lin-35 Rb (Lu and Horvitz, 1998). The cellular focus of synMuv genes is currently unclear. Originally, synMuv genes were proposed to act non-autonomously to repress vulval fates from within the hyp7 (Herman and Hedgecock, 1990; Hedgecock and Herman, 1995), but were subsequently proposed to act autonomously within the vulval precursor cells (VPCs) (Lu and Horvitz, 1998; Thomas and Horvitz, 1999). It is also conceivable that synMuv genes, which in general are broadly expressed, may have more than one cellular focus. Determining the cellular focus of synMuv gene activity is critical to understanding their roles during vulval development and the signalling events that lead to the invariant pattern of VPC fates, as models for the role of synMuv genes depend on inferences about their cellular focus. For example, the existence of an inhibitory signal was inferred based on the interpretation that hyp7 is the focus of lin-15 (Herman and Hedgecock, 1990); additionally, the view that LIN-35 Rb and transcription factors activated by the Ras-MAP kinase cascade compete with target gene promoters to antagonize vulval induction (Lu and Horvitz, 1998) requires that the focus of lin-35 activity be the VPCs. Utilizing both mosaic analysis and tissue-specific promoters for rescue experiments, we are currently trying to determine the focus of class B synMuv gene lin-35. We will report on our progress at the meeting. Hedgecock E.M., and Herman R.K. (1995). Genetics 141, 989-1006; Herman R.K., and Hedgecock E.M. (1990). Nature 348, 169-171; Lu X., and Horvitz, H.R. (1998). Cell 95, 981-991; Thomas, J.H., and Horvitz, H.R. (1999). Development 126, 3449-3459.

Hishida R et al. (1996) Worm Breeder's Gazette "hch-1 encodes a Zn protease of the tolloid / BMP-1 family"

Katsura I, Hishida R, Kondo K, Ishihara T

[Worm Breeder's Gazette, 1996]

hch-1 gene is necessary for two quite different developmental processes in C. elegans: hatching and cell migration (Hedgecock et al., Development 100:365-382, 1987). The mutant embryos cannot digest proteins in the eggshell and consequently show delayed hatching. hch-1 mutations also cause the QL neuroblast and its descendants to migrate in a wrong direction (anteriorly instead of posteriorly).