| Gene ID | Transcript ID | Common Gene Name | # of miRNA targets for specified miRNAs | Chromosome | Strand Direction | Transcript Link to view miRNA target predictions | Gene Link | Description |
|---|---|---|---|---|---|---|---|---|
| AH9.1 | AH9.1 | AH9.1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| AH9.4 | AH9.4 | AH9.4 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| B0198.2 | B0198.2a | B0198.2 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0198.2 | B0198.2b | B0198.2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0198.3 | B0198.3a | B0198.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| B0272.2 | B0272.2 | memb-1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| B0302.1 | B0302.1a.1 | kin-25 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | kin-25 encodes a nonreceptor tyrosine kinase that is a member of the Ack subfamily of cytoplasmic tyrosine kinases. [Source: WormBase] |
| B0302.1 | B0302.1a.2 | kin-25 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | kin-25 encodes a nonreceptor tyrosine kinase that is a member of the Ack subfamily of cytoplasmic tyrosine kinases. [Source: WormBase] |
| B0302.1 | B0302.1b | kin-25 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | kin-25 encodes a nonreceptor tyrosine kinase that is a member of the Ack subfamily of cytoplasmic tyrosine kinases. [Source: WormBase] |
| B0310.3 | B0310.3 | B0310.3 | 2 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| B0310.5 | B0310.5 | ugt-46 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| B0344.2 | B0344.2 | wrt-9 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | wrt-9 encodes a hedgehog-like protein, with an N-terminal signal sequence, a Wart domain, and a C-terminal region of proline-rich, low-complexity sequence. the Wart domain is predicted to form a cysteine-crosslinked protein involved in intercellular signalling, and it has subtle similarity to the N-terminal Hedge domain of HEDGEHOG proteins. WRT-9 has no obvious function in RNAi assays. [Source: WormBase] |
| B0395.1 | B0395.1 | nhx-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | nhx-1 encodes a sodium/proton exchanger expressed intracellularly within hypodermal and muscle cells. NHX-1 is required for embryonic viability, and is thought to prevent intracellular acidification by catalysing the electroneutral exchange of vesicular sodium for an intracellular proton. [Source: WormBase] |
| B0403.4 | B0403.4 | tag-320 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| B0403.5 | B0403.5 | B0403.5 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0416.1 | B0416.1 | B0416.1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0416.2 | B0416.2 | B0416.2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0416.3 | B0416.3 | B0416.3 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0416.4 | B0416.4 | B0416.4 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0416.5 | B0416.5a | B0416.5 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| B0416.5 | B0416.5b | B0416.5 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| B0416.6 | B0416.6 | gly-13 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | gly-13 encodes an experimentally verified UDP-N-acetylglucosamine alpha-3-D-mannoside beta-1,2-N-acetylglucosaminyltransferase I (GnT I), that is the primary GnT I enzyme in vivo, and that can act on unusual substrates. gly-13 is expressed throughout development in many cell types. gly-13 has no obvious function in vivo, since a deletion allele of gly-13 is phenotypically normal even as a double or triple mutant with gly-12 and gly-14. [Source: WormBase] |
| B0563.1 | B0563.1 | B0563.1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0563.2 | B0563.2 | tsp-11 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0563.6 | B0563.6a | B0563.6 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0563.6 | B0563.6b.1 | B0563.6 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0563.6 | B0563.6b.2 | B0563.6 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0563.6 | B0563.6c | B0563.6 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C01C10.1 | C01C10.1 | clc-2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | clc-2 encodes a claudin homolog, closely similar to CLC-1, that is required for normal cohesion of apical junctions in epithelia. claudins are integral membrane proteins with four transmembrane sequences that are found in mammalian tight junctions (TJs), induce TJs when transgenically expressed in cells normally lacking them, and can mediate the specific conductance of of specific ions (e.g., magnesium or calcium) through TJs while blocking the flow of water. CLC-2 maintains the impermeability ('barrier function') of epithelia, since clc-1(RNAi) animals have abnormal permeability of the hypodermis to dyes. clc-2 is expressed in hypodermal seam cells, with two diffuse lines of CLC-2 protein. [Source: WormBase] |
| C01C10.3 | C01C10.3.1 | acl-12 | 2 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C01C10.3 | C01C10.3.2 | acl-12 | 2 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C01C4.2 | C01C4.2 | C01C4.2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C01C4.3 | C01C4.3b | C01C4.3 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | C01C4.3 encodes a serine/threonine protein kinase. [Source: WormBase] |
| C02B4.1 | C02B4.1 | adt-1 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | The adt-1 gene encodes a metalloproteinase with disintegrin-like and metalloproteinase with thrombospondin type I motifs (ADAMTS) that is required for male tail morphogenesis. [Source: WormBase] |
| C02B4.3 | C02B4.3 | C02B4.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02B8.1 | C02B8.1.1 | C02B8.1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C02B8.1 | C02B8.1.2 | C02B8.1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C02B8.6 | C02B8.6 | C02B8.6 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02C6.1 | C02C6.1a | dyn-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | dyn-1 encodes the C. elegans ortholog of the dynamin GTPase. dyn-1 activity is required for endocytosis, synaptic vesicle recycling, cytokinesis, and the CED-1 pathway that regulates engulfment and degradation of apoptotic cells. mutations in dyn-1 affect locomotion, egg-laying, defecation, and embryonic development, indicating that dyn-1's endocytic function is required for a number of diverse processes. dyn-1 reporter fusion constructs are expressed in motor neurons, intestinal cells, and pharyngeal muscle. [Source: WormBase] |
| C02C6.1 | C02C6.1b | dyn-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | dyn-1 encodes the C. elegans ortholog of the dynamin GTPase. dyn-1 activity is required for endocytosis, synaptic vesicle recycling, cytokinesis, and the CED-1 pathway that regulates engulfment and degradation of apoptotic cells. mutations in dyn-1 affect locomotion, egg-laying, defecation, and embryonic development, indicating that dyn-1's endocytic function is required for a number of diverse processes. dyn-1 reporter fusion constructs are expressed in motor neurons, intestinal cells, and pharyngeal muscle. [Source: WormBase] |
| C02C6.2 | C02C6.2a | olrn-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | olrn-1 encodes, by alternative splicing, two isoforms of a transmembrane protein required for differentiation of the AWC[ON] neuron, expression of str-2 in AWC[ON], adaptation to benzaldehyde, chemotaxis to butanone, and enhancement of chemotaxis to butanone by the presence of food. OLRN-1 is orthologous to Drosophila melanogaster RAW and Schistosoma japonicum SJCHGC05616. while OLRN-1 has orthologs in nematodes, trematodes, and arthropods, its has no obvious chordate homologs. OLRN-6 is expressed in many pharyngeal neurons and some head neurons, but is required solely in the AWC[ON] neuron for butanone enhancement. OLRN-6's function in butanone enhancement is both serotonin- and dopamine-independent, and appears to also act in chemotactic enhancement of 2,3-pentanedione and isoamyl alcohol. by orthology with RAW, OLRN-6 is predicted to inhibit JNK-1 signalling, which may in turn allow the asymmetrical AWC[ON] fate to emerge. [Source: WormBase] |
| C02C6.2 | C02C6.2b | olrn-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | olrn-1 encodes, by alternative splicing, two isoforms of a transmembrane protein required for differentiation of the AWC[ON] neuron, expression of str-2 in AWC[ON], adaptation to benzaldehyde, chemotaxis to butanone, and enhancement of chemotaxis to butanone by the presence of food. OLRN-1 is orthologous to Drosophila melanogaster RAW and Schistosoma japonicum SJCHGC05616. while OLRN-1 has orthologs in nematodes, trematodes, and arthropods, its has no obvious chordate homologs. OLRN-6 is expressed in many pharyngeal neurons and some head neurons, but is required solely in the AWC[ON] neuron for butanone enhancement. OLRN-6's function in butanone enhancement is both serotonin- and dopamine-independent, and appears to also act in chemotactic enhancement of 2,3-pentanedione and isoamyl alcohol. by orthology with RAW, OLRN-6 is predicted to inhibit JNK-1 signalling, which may in turn allow the asymmetrical AWC[ON] fate to emerge. [Source: WormBase] |
| C02F12.4 | C02F12.4 | tag-52 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02F12.7 | C02F12.7 | tag-278 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02H7.3 | C02H7.3a | aex-3 | 3 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | aex-3 encodes a guanine nucleotide exchange factor for the rab-3 GTPase that is orthologous to human MAP kinase activating protein containing death domain (MADD, OMIM:603584). AEX-3 is required for intracellular vesicle trafficking as well as synaptic vesicle release and interacts with CAB-1 and RAB-3 to regulate separate pathways for neural activities such as defecation and male mating, respectively. AEX-3 is also required for egg laying and locomotion. AEX-3 is expressed in nearly all neurons. [Source: WormBase] |
| C03A3.1 | C03A3.1a | C03A3.1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C03A3.1 | C03A3.1b | C03A3.1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C03B1.1 | C03B1.1 | C03B1.1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C03F11.3 | C03F11.3 | scav-1 | 2 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C03G5.10 | C03G5.10 | nspc-3 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C03G5.11 | C03G5.11 | nspc-4 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C03G5.12 | C03G5.12 | nspc-5 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C03G5.13 | C03G5.13 | nspc-6 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C03G5.2 | C03G5.2 | nspc-7 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C03G5.8 | C03G5.8 | nspc-1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C03G5.9 | C03G5.9 | nspc-2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C04A11.1 | C04A11.1 | C04A11.1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C04A11.3 | C04A11.3 | gck-4 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C04A11.4 | C04A11.4 | adm-2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | adm-2 encodes a protein containing a snake venom disintegrin-domain and a metalloprotease-like domain (i.e., a protein of the ADAM family). like ADM-1, ADM-2 is homologous to a mammalian sperm glycoprotein (PH-30/fertilin) implicated in sperm-egg fusion, and ADM-2 might thus be a fusogenic protein mediating the merging of plasma membranes during development. [Source: WormBase] |
| C04B4.2 | C04B4.2 | C04B4.2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C04C11.2 | C04C11.2.1 | arrd-25 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C04E7.1 | C04E7.1 | C04E7.1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C04E7.2 | C04E7.2 | sor-3 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | sor-3 encodes a novel protein that contains an MBT (malignant brain tumor) domain related to the MBT domains found in the Sex comb on midleg (SCM) and Sfmbt Polycomb group proteins. during development, SOR-3 activity is required to specify the correct number of dopaminergic and serotonergic neurons in males, as well as for proper ray neuron axon guidance, distal tip cell migration, and normal body size. SOR-3 activity is necessary for maintaining repression of Hox gene expression, notably that of egl-5 in many head neurons. in regulating neurotransmitter phenotype, sor-3 functions together with sop-2, which also encodes a Polycomb group protein, and members of the TGF-beta signaling pathway. sor-3 and sop-2 also function together to regulate progression through larval development. a SOR-3::GFP reporter fusion is expressed ubiquitously throughout the life cycle and localizes to both the cytoplasm and the nucleus. [Source: WormBase] |
| C04E7.4 | C04E7.4 | C04E7.4 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C04F6.2 | C04F6.2 | C04F6.2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C04F6.3 | C04F6.3.1 | cht-1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | cht-1 encodes a chitinase orthologous to human chitinase-1 (OMIM:600031, mutations are associated with chitotriosidase deficiency). CHT-1 is predicted to function as an extracellular O-glycosyl hydrolase that hydrolyzes the glycosidic bond between two or more carbohydrates. in C. elegans, CHT-1 may play a role in embryogenesis, and may also be required for cuticle degradation during molting and degradation of chitin-containing pathogens as part of a host defense mechanism. [Source: WormBase] |
| C04F6.3 | C04F6.3.2 | cht-1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | cht-1 encodes a chitinase orthologous to human chitinase-1 (OMIM:600031, mutations are associated with chitotriosidase deficiency). CHT-1 is predicted to function as an extracellular O-glycosyl hydrolase that hydrolyzes the glycosidic bond between two or more carbohydrates. in C. elegans, CHT-1 may play a role in embryogenesis, and may also be required for cuticle degradation during molting and degradation of chitin-containing pathogens as part of a host defense mechanism. [Source: WormBase] |
| C04F6.4 | C04F6.4a | unc-78 | 2 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | The unc-78 gene encodes a homolog of actin-interacting protein 1 (AIP1) that regulates the ordered assembly of actin and cofilin in myofibrils. [Source: WormBase] |
| C04F6.5 | C04F6.5 | dhs-27 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | dhs-27 encodes a short-chain dehydrogenase predicted to be mitochondrial. [Source: WormBase] |
| C05C9.1 | C05C9.1 | C05C9.1 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C05C9.3 | C05C9.3 | C05C9.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | The protein product of this gene is predicted to contain a glutamine/asparagine (Q/N)-rich ('prion') domain, by the algorithm of Michelitsch and Weissman (as of the WS77 release of WormBase, i.e., in wormpep77). [Source: WormBase] |
| C05D9.1 | C05D9.1.1 | snx-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C05D9.1 | C05D9.1.2 | snx-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C05D9.1 | C05D9.1.3 | snx-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C05D9.9 | C05D9.9a | C05D9.9 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C05D9.9 | C05D9.9b | C05D9.9 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C05E11.1 | C05E11.1.1 | lnp-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | lnp-1 encodes a highly conserved protein of unknown function, orthologous to human LUNAPARK/KIAA1715 (OMIM:610236), that is required for normally short body length, normal locomotion, fat content, acetylcholine neurotransmission, localization of RAB-3 and SNB-1, and sensitivity to aldicarb. LNP-1 is expressed in muscles, hypodermal cells, and neurons. within neurons, LNP-1 is localized to cell bodies, neuritic processes and commissures, and requiring UNC-104 for localization outside of cell bodies. LNP-1 is likely to act presynaptically. LNP-1 contains two N-terminal predicted transmembrane sequences, and an atypical zinc finger domain (C2HC2). [Source: WormBase] |
| C05E7.1 | C05E7.1 | C05E7.1 | 2 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C05E7.2 | C05E7.2 | C05E7.2 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C06G1.1 | C06G1.1a | C06G1.1 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C06G1.1 | C06G1.1b | C06G1.1 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C07A12.3 | C07A12.3a | nhr-35 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C07A12.4 | C07A12.4a.1 | pdi-2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C07A12.4 | C07A12.4a.2 | pdi-2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C07A12.4 | C07A12.4b | pdi-2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C07A12.4 | C07A12.4c | pdi-2 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C07A4.2 | C07A4.2 | C07A4.2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C07A4.3 | C07A4.3 | C07A4.3 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C07B5.5 | C07B5.5 | nuc-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | The nuc-1 gene encodes a DNase II homolog similar to mammalian and Drosophila DNaseII enzymes and is required for DNA degradation during apoptosis as well as for degradation of dietary DNA during normal feeding. during apoptosis, NUC-1 functions in apoptotic cells at an intermediate stage of DNA degradation, after the killing step, but prior to cell-corpse engulfment. [Source: WormBase] |
| C07D8.6 | C07D8.6 | C07D8.6 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C09B8.7 | C09B8.7a.1 | pak-1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | pak-1 encodes, by alternative splicing, at least five isoforms of a putative p21-activated kinase orthologous to human PAK1, PAK2 (OMIM:?), and PAK3 (OMIM:300142, mutated in nonsyndromic mental retardation). PAK-1 is required (redundantly with its paralog, MAX-2) for normal axonal guidance of motoneurons, P cell migration, and locomotion, with max-2(cy2).pak-1(ok448) double mutants phenotypically resembling unc-73 or ced-10.mig-2 mutants. pak-1 is expressed in pharyngeal muscles, CAN neurons, ventral cord motoneurons, migrating distal tip cells, developing uterus, B, Y, and T cells in the male tail, and vulval muscle cells. by itself, the null pak-1(ok448) mutation has no known phenotype. [Source: WormBase] |
| C09B8.7 | C09B8.7a.2 | pak-1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | pak-1 encodes, by alternative splicing, at least five isoforms of a putative p21-activated kinase orthologous to human PAK1, PAK2 (OMIM:?), and PAK3 (OMIM:300142, mutated in nonsyndromic mental retardation). PAK-1 is required (redundantly with its paralog, MAX-2) for normal axonal guidance of motoneurons, P cell migration, and locomotion, with max-2(cy2).pak-1(ok448) double mutants phenotypically resembling unc-73 or ced-10.mig-2 mutants. pak-1 is expressed in pharyngeal muscles, CAN neurons, ventral cord motoneurons, migrating distal tip cells, developing uterus, B, Y, and T cells in the male tail, and vulval muscle cells. by itself, the null pak-1(ok448) mutation has no known phenotype. [Source: WormBase] |
| C09E10.2 | C09E10.2a | dgk-1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | dgk-1 encodes an ortholog of mammalian diacylglycerol kinase theta (DGKQ). dgk-1 activity functions downstream in a serotonin signaling pathway that regulates locomotion and synaptic transmission. in addition, dgk-1 activity negatively regulates egg laying. dgk-1 genetically interacts with the goa-1 and egl-30 signaling pathways. a GFP::DGK-1 reporter fusion protein is expressed in the excretory canals and in most neurons, including the ventral cord neurons. in neurons, GFP::DGK-1 localizes to axons and cell bodies. when expressed ectopically in HEK293 cells, DGK-1 exhibits DAG kinase activity. [Source: WormBase] |
| C09E10.2 | C09E10.2b | dgk-1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | dgk-1 encodes an ortholog of mammalian diacylglycerol kinase theta (DGKQ). dgk-1 activity functions downstream in a serotonin signaling pathway that regulates locomotion and synaptic transmission. in addition, dgk-1 activity negatively regulates egg laying. dgk-1 genetically interacts with the goa-1 and egl-30 signaling pathways. a GFP::DGK-1 reporter fusion protein is expressed in the excretory canals and in most neurons, including the ventral cord neurons. in neurons, GFP::DGK-1 localizes to axons and cell bodies. when expressed ectopically in HEK293 cells, DGK-1 exhibits DAG kinase activity. [Source: WormBase] |
| C09E10.2 | C09E10.2c | dgk-1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | dgk-1 encodes an ortholog of mammalian diacylglycerol kinase theta (DGKQ). dgk-1 activity functions downstream in a serotonin signaling pathway that regulates locomotion and synaptic transmission. in addition, dgk-1 activity negatively regulates egg laying. dgk-1 genetically interacts with the goa-1 and egl-30 signaling pathways. a GFP::DGK-1 reporter fusion protein is expressed in the excretory canals and in most neurons, including the ventral cord neurons. in neurons, GFP::DGK-1 localizes to axons and cell bodies. when expressed ectopically in HEK293 cells, DGK-1 exhibits DAG kinase activity. [Source: WormBase] |
| C09E10.2 | C09E10.2d | dgk-1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | dgk-1 encodes an ortholog of mammalian diacylglycerol kinase theta (DGKQ). dgk-1 activity functions downstream in a serotonin signaling pathway that regulates locomotion and synaptic transmission. in addition, dgk-1 activity negatively regulates egg laying. dgk-1 genetically interacts with the goa-1 and egl-30 signaling pathways. a GFP::DGK-1 reporter fusion protein is expressed in the excretory canals and in most neurons, including the ventral cord neurons. in neurons, GFP::DGK-1 localizes to axons and cell bodies. when expressed ectopically in HEK293 cells, DGK-1 exhibits DAG kinase activity. [Source: WormBase] |
| C09E10.2 | C09E10.2e | dgk-1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | dgk-1 encodes an ortholog of mammalian diacylglycerol kinase theta (DGKQ). dgk-1 activity functions downstream in a serotonin signaling pathway that regulates locomotion and synaptic transmission. in addition, dgk-1 activity negatively regulates egg laying. dgk-1 genetically interacts with the goa-1 and egl-30 signaling pathways. a GFP::DGK-1 reporter fusion protein is expressed in the excretory canals and in most neurons, including the ventral cord neurons. in neurons, GFP::DGK-1 localizes to axons and cell bodies. when expressed ectopically in HEK293 cells, DGK-1 exhibits DAG kinase activity. [Source: WormBase] |
| C09F12.1 | C09F12.1.1 | clc-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | clc-1 encodes a claudin homolog, closely similar to CLC-2, that is required for normal cohesion of apical junctions in epithelia. claudins are integral membrane proteins with four transmembrane sequences that are found in mammalian tight junctions (TJs), induce TJs when transgenically expressed in cells normally lacking them, and can mediate the specific conductance of of specific ions (e.g., magnesium or calcium) through TJs while blocking the flow of water. CLC-1 maintains the impermeability ('barrier function') of epithelia, since clc-1(RNAi) animals have abnormal permeability of the pharynx to dyes. clc-1 is expressed in spermatheca, pharynx, intestine, hypodermis, the excretory-secretory system, and the cell-cell junctions of the vulva. in pharyngeal cells, CLC-1 colocalizes with AJM-1 in long thin lines, parallel to the pharyngeal axis and lining the lumenal surface, that appear to correspond with apical intercellular junctions. [Source: WormBase] |
| C09F12.1 | C09F12.1.2 | clc-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | clc-1 encodes a claudin homolog, closely similar to CLC-2, that is required for normal cohesion of apical junctions in epithelia. claudins are integral membrane proteins with four transmembrane sequences that are found in mammalian tight junctions (TJs), induce TJs when transgenically expressed in cells normally lacking them, and can mediate the specific conductance of of specific ions (e.g., magnesium or calcium) through TJs while blocking the flow of water. CLC-1 maintains the impermeability ('barrier function') of epithelia, since clc-1(RNAi) animals have abnormal permeability of the pharynx to dyes. clc-1 is expressed in spermatheca, pharynx, intestine, hypodermis, the excretory-secretory system, and the cell-cell junctions of the vulva. in pharyngeal cells, CLC-1 colocalizes with AJM-1 in long thin lines, parallel to the pharyngeal axis and lining the lumenal surface, that appear to correspond with apical intercellular junctions. [Source: WormBase] |
| C09G1.2 | C09G1.2 | C09G1.2 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl |