| 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 |
|---|---|---|---|---|---|---|---|---|
| B0198.3 | B0198.3a | B0198.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| B0272.1 | B0272.1 | tbb-4 | 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 | 1 | 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 | 2 | 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] |
| B0395.3 | B0395.3.1 | B0395.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | B0395.3 is orthologous to the human gene CHOLINE ACETYLTRANSFERASE ISOFORM R (CHAT. OMIM:118490), which when mutated leads to disease. [Source: WormBase] |
| B0395.3 | B0395.3.2 | B0395.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | B0395.3 is orthologous to the human gene CHOLINE ACETYLTRANSFERASE ISOFORM R (CHAT. OMIM:118490), which when mutated leads to disease. [Source: WormBase] |
| B0403.2 | B0403.2 | ubc-17 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0403.3 | B0403.3 | B0403.3 | 2 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| B0403.4 | B0403.4 | tag-320 | 1 | 23 X | Reverse | 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 | |
| B0416.6 | 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] |
| B0563.4 | B0563.4.1 | tmbi-4 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| B0563.4 | B0563.4.2 | tmbi-4 | 1 | 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 | |
| B0563.7 | B0563.7 | B0563.7 | 1 | 23 X | Reverse | 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] |
| C01C10.4 | C01C10.4 | clc-5 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | clc-5 encodes a claudin homolog that may be required for normal cohesion of apical junctions in epithelia. CLC-5 is worm-specific, with obvious homologs only in C. elegans. CLC-5 has no obvious function in mass RNAi assays. 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. [Source: WormBase] |
| C02B4.1 | C02B4.1 | adt-1 | 3 | 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] |
| C02B8.4 | C02B8.4 | hlh-8 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | The hlh-8 gene encodes a helix-loop-helix protein required for normal muscle development, and hence for normal defecation and egg-laying. [Source: WormBase] |
| C02B8.5 | C02B8.5 | C02B8.5 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | C02B8.5 encodes a homolog of the functionally active Fmrf Receptor (FR. CG2114) of D. melanogaster. it is thus possible that C02B8.5 is a receptor for one of the FMRF-like neurotransmitters in C. elegans (e.g., FLP-1 through FLP-12). [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] |
| C02C6.3 | C02C6.3a | C02C6.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02C6.3 | C02C6.3b | C02C6.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02C6.3 | C02C6.3c | C02C6.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02C6.3 | C02C6.3d.1 | C02C6.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02C6.3 | C02C6.3d.2 | C02C6.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02D4.2 | C02D4.2a | ser-2 | 3 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | ser-2 encodes at least four tyramine 7-transmembrane domain receptors (GPCRs), by alternative splicing from three different promoters, that have distinct but partially overlapping expression patterns. ser-2 has at least three alternative promoters that drive SER-2 expression in a set of sensory, inter- and motor neurons (e.g., AIY, AIZ, and RIA) adding up to ~10% of all neurons in the nervous system, as well as pharyngeal cells and head muscles. the deletion ser-2(pk1397) has no obvious mutant phenotype. LIM-4 is required for SER-2 expression, and MAB-23 is required for SER-2 expression at normally high levels. [Source: WormBase] |
| C02D4.2 | C02D4.2b | ser-2 | 3 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | ser-2 encodes at least four tyramine 7-transmembrane domain receptors (GPCRs), by alternative splicing from three different promoters, that have distinct but partially overlapping expression patterns. ser-2 has at least three alternative promoters that drive SER-2 expression in a set of sensory, inter- and motor neurons (e.g., AIY, AIZ, and RIA) adding up to ~10% of all neurons in the nervous system, as well as pharyngeal cells and head muscles. the deletion ser-2(pk1397) has no obvious mutant phenotype. LIM-4 is required for SER-2 expression, and MAB-23 is required for SER-2 expression at normally high levels. [Source: WormBase] |
| C02D4.2 | C02D4.2e | ser-2 | 3 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | ser-2 encodes at least four tyramine 7-transmembrane domain receptors (GPCRs), by alternative splicing from three different promoters, that have distinct but partially overlapping expression patterns. ser-2 has at least three alternative promoters that drive SER-2 expression in a set of sensory, inter- and motor neurons (e.g., AIY, AIZ, and RIA) adding up to ~10% of all neurons in the nervous system, as well as pharyngeal cells and head muscles. the deletion ser-2(pk1397) has no obvious mutant phenotype. LIM-4 is required for SER-2 expression, and MAB-23 is required for SER-2 expression at normally high levels. [Source: WormBase] |
| C02D4.2 | C02D4.2f | ser-2 | 3 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | ser-2 encodes at least four tyramine 7-transmembrane domain receptors (GPCRs), by alternative splicing from three different promoters, that have distinct but partially overlapping expression patterns. ser-2 has at least three alternative promoters that drive SER-2 expression in a set of sensory, inter- and motor neurons (e.g., AIY, AIZ, and RIA) adding up to ~10% of all neurons in the nervous system, as well as pharyngeal cells and head muscles. the deletion ser-2(pk1397) has no obvious mutant phenotype. LIM-4 is required for SER-2 expression, and MAB-23 is required for SER-2 expression at normally high levels. [Source: WormBase] |
| C02F12.4 | C02F12.4 | tag-52 | 2 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02F12.5 | C02F12.5 | C02F12.5 | 2 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | C02F12.5 encodes a putatively secreted protein with a Kunitz/bovine pancreatic trypsin inhibitor domain. C02F12.5 has no obvious function in mass RNAi assays. [Source: WormBase] |
| C02F12.7 | C02F12.7 | tag-278 | 2 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02H7.2 | C02H7.2 | npr-19 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C02H7.3 | C02H7.3a | aex-3 | 1 | 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] |
| C03B1.1 | C03B1.1 | C03B1.1 | 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 | 2 | 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 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C04E7.1 | C04E7.1 | C04E7.1 | 2 | 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] |
| C04F6.5 | C04F6.5 | dhs-27 | 2 | 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] |
| C05A9.1 | C05A9.1a | pgp-5 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | pgp-5 encodes a transmembrane protein that is a member of the P-glycoprotein subclass of the ATP-binding cassette (ABC) transporter superfamily. by homology, PGP-5 is predicted to function as an ATP-dependent efflux pump that protects C. elegans by exporting exogenous toxins. however, as loss of pgp-5 activity via large-scale RNAi screens does not result in any obvious abnormalities, the precise role of PGP-5 in C. elegans development and/or behavior is not yet known. [Source: WormBase] |
| C05A9.1 | C05A9.1b | pgp-5 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | pgp-5 encodes a transmembrane protein that is a member of the P-glycoprotein subclass of the ATP-binding cassette (ABC) transporter superfamily. by homology, PGP-5 is predicted to function as an ATP-dependent efflux pump that protects C. elegans by exporting exogenous toxins. however, as loss of pgp-5 activity via large-scale RNAi screens does not result in any obvious abnormalities, the precise role of PGP-5 in C. elegans development and/or behavior is not yet known. [Source: WormBase] |
| C05A9.2 | C05A9.2 | C05A9.2 | 2 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C05C9.1 | C05C9.1 | C05C9.1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C05D9.3 | C05D9.3 | C05D9.3 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C05E11.4 | C05E11.4 | amt-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | amt-1 encodes a transmembrane transporter that by homology, is predicted to transport ammonium ions across the plasma membrane. as loss of amt-1 activity via large-scale RNAi screens does not result in any obvious abnormalities, the precise role of AMT-1 in C. elegans development and/or behavior is not yet known. [Source: WormBase] |
| C05E11.5 | C05E11.5 | amt-4 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | amt-4 encodes a member of the ammonium transporter protein family. [Source: WormBase] |
| C05E11.7 | C05E11.7 | C05E11.7 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C05E7.1 | C05E7.1 | C05E7.1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C05E7.4 | C05E7.4 | C05E7.4 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C05G5.1 | C05G5.1 | C05G5.1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C05G5.4 | C05G5.4.1 | C05G5.4 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C05G5.5 | C05G5.5 | C05G5.5 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C06E2.1 | C06E2.1 | C06E2.1 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C06E2.7 | C06E2.7 | ubc-22 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | ubc-22 encodes an E2 ubiquitin-conjugating enzyme orthologous to Saccharomyces cerevisiae UBC8 and human UBC1/HIP2 (Huntingtin interacting protein 2, OMIM:602846) which are involved in regulating fructose-1,6-bisphosphatase and huntingtin catabolism, respectively. by homology, UBC-22 is likely required for covalent attachment of ubiquitin to select target proteins to facilitate their degradation. however, as loss of UBC-22 activity via RNA-mediated interference (RNAi) does not result in any abnormalities, the precise role of UBC-22 in C. elegans development and/or behavior is not yet known. [Source: WormBase] |
| C06E2.8 | C06E2.8 | ins-9 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | ins-9 encodes an insulin-like peptide of the insulin superfamily of proteins (OMIM:176730, 147440). INS-9 is one of 38 insulin-like peptides in C. elegans and although INS-9 overexpression can result in low levels of embryonic and larval lethality, the precise role of INS-9 in C. elegans development is not yet clear. INS-9 is expressed exclusively in the amphid sensory neurons ASI and ASJ that regulate dauer arrest, but INS-9 overexpression does not enhance dauer arrest in a wild-type or daf-2 mutant background. [Source: WormBase] |
| C06G1.4 | C06G1.4.1 | ain-1 | 3 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | ain-1 encodes an unfamiliar protein synergistically required, with LIN-31, for the normal timing of vulval differentiation, independently of LET-60/RAS, and parallel to or downstream of LIN-14/LIN-28/HBL-1. AIN-1 is expressed in cytoplasmic foci (that are probably P bodies) in several tissues, including vulval precursor cells and neurons. AIN-1 coimmunoprecipitates with DCR-1 and ALG-1, also binds ALG-1 in vitro, and does not require DNA or RNA for its binding. in vivo, AIN-1 targets ALG-1 to cytoplasmic foci, in which it colocalizes with DCAP-2. AIN-1 is likely to be a RISC component, since anti-AIN-1 antibodies precipitate 29 different miRNAs, including mir-2, mir-52, mir-58, mir-71, mir-77, and mir-239a. ain-1(ku322) mutants are essentially wild-type, except for sporadically gapped alae and excess seam cell nuclei arising from retarded seam cell fusion. more prominently, ain-1(ku322) suppresses the multivulva phenotype of lin-31(n1053) mutations, while strongly enhancing lin-31(n1053)'s egg-laying defect. the cellular basis of lin-31(n1053).ain-1(ku322) phenotypes is a delay in vulval development in L4 larvae not seen with either mutation alone. ain-1(ku322) has no effect on let-60(n1046) or lin-3(e1275) mutations. ain-1(ku322) suppresses the precocious vulval development of lin-14(RNAi), lin-28 mutants, and hbl-1(RNAi). alg-1 or alg-1 ain-1 mutant alae resemble ain-1 alae, indicating that ALG-1 and AIN-1 act in a common genetic pathway. AIN-1 is homologous to Brugia malayi 14748.m00068, 14052.m00191, and 14963.m01790, and paralogous to C. elegans B0041.2. AIN-1 and its nematode homologs have weak similarity to human TNRC6A (GW182. OMIM:610739) and Drosophila GAWKY. [Source: WormBase] |
| C06G1.4 | C06G1.4.2 | ain-1 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | ain-1 encodes an unfamiliar protein synergistically required, with LIN-31, for the normal timing of vulval differentiation, independently of LET-60/RAS, and parallel to or downstream of LIN-14/LIN-28/HBL-1. AIN-1 is expressed in cytoplasmic foci (that are probably P bodies) in several tissues, including vulval precursor cells and neurons. AIN-1 coimmunoprecipitates with DCR-1 and ALG-1, also binds ALG-1 in vitro, and does not require DNA or RNA for its binding. in vivo, AIN-1 targets ALG-1 to cytoplasmic foci, in which it colocalizes with DCAP-2. AIN-1 is likely to be a RISC component, since anti-AIN-1 antibodies precipitate 29 different miRNAs, including mir-2, mir-52, mir-58, mir-71, mir-77, and mir-239a. ain-1(ku322) mutants are essentially wild-type, except for sporadically gapped alae and excess seam cell nuclei arising from retarded seam cell fusion. more prominently, ain-1(ku322) suppresses the multivulva phenotype of lin-31(n1053) mutations, while strongly enhancing lin-31(n1053)'s egg-laying defect. the cellular basis of lin-31(n1053).ain-1(ku322) phenotypes is a delay in vulval development in L4 larvae not seen with either mutation alone. ain-1(ku322) has no effect on let-60(n1046) or lin-3(e1275) mutations. ain-1(ku322) suppresses the precocious vulval development of lin-14(RNAi), lin-28 mutants, and hbl-1(RNAi). alg-1 or alg-1 ain-1 mutant alae resemble ain-1 alae, indicating that ALG-1 and AIN-1 act in a common genetic pathway. AIN-1 is homologous to Brugia malayi 14748.m00068, 14052.m00191, and 14963.m01790, and paralogous to C. elegans B0041.2. AIN-1 and its nematode homologs have weak similarity to human TNRC6A (GW182. OMIM:610739) and Drosophila GAWKY. [Source: WormBase] |
| C06G1.5 | C06G1.5 | C06G1.5 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C07A4.1 | C07A4.1 | tiar-3 | 1 | 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 | |
| C07B5.3 | C07B5.3 | C07B5.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C07B5.4 | C07B5.4b.1 | C07B5.4 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C07B5.4 | C07B5.4b.2 | C07B5.4 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C08A9.3 | C08A9.3a | C08A9.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C09B7.1 | C09B7.1a | ser-7 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | ser-7 encodes an ortholog of mammalian 5-HT7 metabotropic serotonin receptors. SER-7 is required for stimulation of egg-laying or pharyngeal pumping by serotonin (5-HT), for regular pumping in response to bacteria, and probably also for 5-HT to activate MC neurons. SER-7 and SER-1 are redundantly required for normal egg-laying. SER-7 is expressed in head and tail neurons, pharyngeal neurons (M4, MCs, I2s, I3, M5, M3s, I4, I6, and M2s), vulval muscles, and intestine. heterologously expressed SER-7, when challenged with 5-HT, stimulates intracellular adenylate cyclase activity. SER-7 has high affinity for 5-HT and tryptamine, but not for 5-CT, and is unaffected by at least some agonists of mammalian 5-HT7 receptors. [Source: WormBase] |
| C09B7.1 | C09B7.1b | ser-7 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | ser-7 encodes an ortholog of mammalian 5-HT7 metabotropic serotonin receptors. SER-7 is required for stimulation of egg-laying or pharyngeal pumping by serotonin (5-HT), for regular pumping in response to bacteria, and probably also for 5-HT to activate MC neurons. SER-7 and SER-1 are redundantly required for normal egg-laying. SER-7 is expressed in head and tail neurons, pharyngeal neurons (M4, MCs, I2s, I3, M5, M3s, I4, I6, and M2s), vulval muscles, and intestine. heterologously expressed SER-7, when challenged with 5-HT, stimulates intracellular adenylate cyclase activity. SER-7 has high affinity for 5-HT and tryptamine, but not for 5-CT, and is unaffected by at least some agonists of mammalian 5-HT7 receptors. [Source: WormBase] |
| C09B7.1 | C09B7.1c | ser-7 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | ser-7 encodes an ortholog of mammalian 5-HT7 metabotropic serotonin receptors. SER-7 is required for stimulation of egg-laying or pharyngeal pumping by serotonin (5-HT), for regular pumping in response to bacteria, and probably also for 5-HT to activate MC neurons. SER-7 and SER-1 are redundantly required for normal egg-laying. SER-7 is expressed in head and tail neurons, pharyngeal neurons (M4, MCs, I2s, I3, M5, M3s, I4, I6, and M2s), vulval muscles, and intestine. heterologously expressed SER-7, when challenged with 5-HT, stimulates intracellular adenylate cyclase activity. SER-7 has high affinity for 5-HT and tryptamine, but not for 5-CT, and is unaffected by at least some agonists of mammalian 5-HT7 receptors. [Source: WormBase] |
| C09B7.2 | C09B7.2.1 | C09B7.2 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C09B8.6 | C09B8.6a | hsp-25 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | hsp-25 encodes a member of the small heat shock family of proteins. HSP-25 is expressed throughout development and in vitro, exhibits chaperone activity. HSP-25 localizes to: 1) dense bodies and M lines in body wall muscle, 2) the lining of the pharynx, and 3) to cell-cell junctions in the spermathecal wall. consistent with a role in myofibril organization, HSP-25 binds vinculin and alpha-actinin in vitro. [Source: WormBase] |
| C09B8.6 | C09B8.6b | hsp-25 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | hsp-25 encodes a member of the small heat shock family of proteins. HSP-25 is expressed throughout development and in vitro, exhibits chaperone activity. HSP-25 localizes to: 1) dense bodies and M lines in body wall muscle, 2) the lining of the pharynx, and 3) to cell-cell junctions in the spermathecal wall. consistent with a role in myofibril organization, HSP-25 binds vinculin and alpha-actinin in vitro. [Source: WormBase] |
| C09B8.6 | C09B8.6c.1 | hsp-25 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | hsp-25 encodes a member of the small heat shock family of proteins. HSP-25 is expressed throughout development and in vitro, exhibits chaperone activity. HSP-25 localizes to: 1) dense bodies and M lines in body wall muscle, 2) the lining of the pharynx, and 3) to cell-cell junctions in the spermathecal wall. consistent with a role in myofibril organization, HSP-25 binds vinculin and alpha-actinin in vitro. [Source: WormBase] |
| C09B8.6 | C09B8.6c.2 | hsp-25 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | hsp-25 encodes a member of the small heat shock family of proteins. HSP-25 is expressed throughout development and in vitro, exhibits chaperone activity. HSP-25 localizes to: 1) dense bodies and M lines in body wall muscle, 2) the lining of the pharynx, and 3) to cell-cell junctions in the spermathecal wall. consistent with a role in myofibril organization, HSP-25 binds vinculin and alpha-actinin in vitro. [Source: WormBase] |
| C09B8.6 | C09B8.6c.3 | hsp-25 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | hsp-25 encodes a member of the small heat shock family of proteins. HSP-25 is expressed throughout development and in vitro, exhibits chaperone activity. HSP-25 localizes to: 1) dense bodies and M lines in body wall muscle, 2) the lining of the pharynx, and 3) to cell-cell junctions in the spermathecal wall. consistent with a role in myofibril organization, HSP-25 binds vinculin and alpha-actinin in vitro. [Source: WormBase] |
| C09B8.6 | C09B8.6c.4 | hsp-25 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | hsp-25 encodes a member of the small heat shock family of proteins. HSP-25 is expressed throughout development and in vitro, exhibits chaperone activity. HSP-25 localizes to: 1) dense bodies and M lines in body wall muscle, 2) the lining of the pharynx, and 3) to cell-cell junctions in the spermathecal wall. consistent with a role in myofibril organization, HSP-25 binds vinculin and alpha-actinin in vitro. [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] |
| C09F12.3 | C09F12.3 | C09F12.3 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C09G1.2 | C09G1.2 | C09G1.2 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C09G1.3 | C09G1.3 | C09G1.3 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C10A4.3 | C10A4.3 | C10A4.3 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C10E2.3 | C10E2.3 | hda-4 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | hda-4 encodes a class II histone deacetylase that contains a putative MEF-2 DNA binding domain, a nuclear localization signal domain, and a single catalytic domain and may affect locomotion, body morphology, and growth. interacts with MEF-2 in in vitro assays and is expressed in body-wall muscle, neurons, and hypodermal seam cells [Source: WormBase] |
| C10E2.4 | C10E2.4 | C10E2.4 | 1 | 23 X | Reverse | View as cDNA map | View as Table | Internal | Ensembl | |
| C11E4.6 | C11E4.6.1 | C11E4.6 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C11E4.6 | C11E4.6.2 | C11E4.6 | 2 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl | |
| C11E4.8 | C11E4.8 | C11E4.8 | 1 | 23 X | Forward | View as cDNA map | View as Table | Internal | Ensembl |