Gene
dhrs3b
- ID
- ZDB-GENE-041010-172
- Name
- dehydrogenase/reductase (SDR family) member 3b
- Symbol
- dhrs3b Nomenclature History
- Previous Names
-
- ik:tdsubc_1f3
- tdsubc_1f3
- xx:tdsubc_1f3
- zgc:101705
- Type
- protein_coding_gene
- Location
- Chr: 11 Mapping Details/Browsers
- Description
- Predicted to enable all-trans-retinol dehydrogenase (NAD+) activity. Predicted to be involved in regulation of retinoic acid receptor signaling pathway and retinoid metabolic process. Predicted to be located in membrane. Predicted to be active in lipid droplet. Is expressed in several structures, including axis; margin; myotome; nervous system; and ventral mesoderm. Orthologous to human DHRS3 (dehydrogenase/reductase 3).
- Genome Resources
- Note
- None
- Comparative Information
-
- All Expression Data
- 8 figures from 3 publications
- Cross-Species Comparison
- High Throughput Data
- Thisse Expression Data
-
- IMAGE:7155647 (17 images)
Wild Type Expression Summary
- All Phenotype Data
- No data available
- Cross-Species Comparison
- Alliance
Phenotype Summary
Mutations
| Allele | Type | Localization | Consequence | Mutagen | Supplier |
|---|---|---|---|---|---|
| la010509Tg | Transgenic insertion | Unknown | Unknown | DNA | |
| la027262Tg | Transgenic insertion | Unknown | Unknown | DNA | |
| sa14805 | Allele with one point mutation | Unknown | Premature Stop | ENU |
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No data available
Human Disease
Domain, Family, and Site Summary
Domain Details Per Protein
| Protein | Additional Resources | Length | NAD(P)-binding domain superfamily | Short-chain dehydrogenase/reductase SDR |
|---|---|---|---|---|
| UniProtKB:Q5XJP6 | InterPro | 302 |
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| Type | Name | Annotation Method | Has Havana Data | Length (nt) | Analysis |
|---|---|---|---|---|---|
| mRNA |
dhrs3b-201
(1)
|
Ensembl | 1,652 nt | ||
| ncRNA |
dhrs3b-002
(1)
|
Ensembl | 863 nt |
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Interactions and Pathways
No data available
Plasmids
No data available
No data available
| Relationship | Marker Type | Marker | Accession Numbers | Citations |
|---|---|---|---|---|
| Contained in | BAC | CH211-226M7 | ZFIN Curated Data | |
| Encodes | EST | IMAGE:7155647 | Thisse et al., 2004 | |
| Encodes | EST | tdsubc_1f3 | ||
| Encodes | cDNA | MGC:101705 | ZFIN Curated Data | |
| Encodes | cDNA | MGC:191245 | ZFIN Curated Data |
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| Type | Accession # | Sequence | Length (nt/aa) | Analysis |
|---|---|---|---|---|
| RNA | RefSeq:NM_001006070 (1) | 1671 nt | ||
| Genomic | GenBank:BX470199 (2) | 197146 nt | ||
| Polypeptide | UniProtKB:Q5XJP6 (1) | 302 aa |
- Mitchell, J.M., Sucharov, J., Pulvino, A.T., Brooks, E.P., Gillen, A.E., Nichols, J.T. (2021) The alx3 gene shapes the zebrafish neurocranium by regulating frontonasal neural crest cell differentiation timing. Development (Cambridge, England). 148(7):
- Isabella, A.J., Barsh, G.R., Stonick, J.A., Dubrulle, J., Moens, C.B. (2020) Retinoic Acid Organizes the Zebrafish Vagus Motor Topographic Map via Spatiotemporal Coordination of Hgf/Met Signaling. Developmental Cell. 53(3):344-357.e5
- Rauwerda, H., Pagano, J.F., de Leeuw, W.C., Ensink, W., Nehrdich, U., de Jong, M., Jonker, M., Spaink, H.P., Breit, T.M. (2017) Transcriptome dynamics in early zebrafish embryogenesis determined by high-resolution time course analysis of 180 successive, individual zebrafish embryos. BMC Genomics. 18:287
- Braasch, I., Gehrke, A.R., Smith, J.J., Kawasaki, K., Manousaki, T., Pasquier, J., Amores, A., Desvignes, T., Batzel, P., Catchen, J., Berlin, A.M., Campbell, M.S., Barrell, D., Martin, K.J., Mulley, J.F., Ravi, V., Lee, A.P., Nakamura, T., Chalopin, D., Fan, S., Wcisel, D., Cañestro, C., Sydes, J., Beaudry, F.E., Sun, Y., Hertel, J., Beam, M.J., Fasold, M., Ishiyama, M., Johnson, J., Kehr, S., Lara, M., Letaw, J.H., Litman, G.W., Litman, R.T., Mikami, M., Ota, T., Saha, N.R., Williams, L., Stadler, P.F., Wang, H., Taylor, J.S., Fontenot, Q., Ferrara, A., Searle, S.M., Aken, B., Yandell, M., Schneider, I., Yoder, J.A., Volff, J.N., Meyer, A., Amemiya, C.T., Venkatesh, B., Holland, P.W., Guiguen, Y., Bobe, J., Shubin, N.H., Di Palma, F., Alföldi, J., Lindblad-Toh, K., Postlethwait, J.H. (2016) The spotted gar genome illuminates vertebrate evolution and facilitates human-teleost comparisons. Nature Genetics. 48(4):427-37
- Jimenez, L., Wang, J., Morrison, M.A., Whatcott, C., Soh, K.K., Warner, S., Bearss, D., Jette, C.A., Stewart, R.A. (2016) Phenotypic chemical screening using zebrafish neural crest reporters identifies retinoid acid as an inhibitor of epithelial morphogenesis. Disease models & mechanisms. 9(4):389-400
- Elkon, R., Milon, B., Morrison, L., Shah, M., Vijayakumar, S., Racherla, M., Leitch, C.C., Silipino, L., Hadi, S., Weiss-Gayet, M., Barras, E., Schmid, C.D., Ait-Lounis, A., Barnes, A., Song, Y., Eisenman, D.J., Eliyahu, E., Frolenkov, G.I., Strome, S.E., Durand, B., Zaghloul, N.A., Jones, S.M., Reith, W., Hertzano, R. (2015) RFX transcription factors are essential for hearing in mice. Nature communications. 6:8549
- Samarut, E., Gaudin, C., Hughes, S., Gillet, B., de Bernard, S., Jouve, P.E., Buffat, L., Allot, A., Lecompte, O., Berekelya, L., Rochette-Egly, C., and Laudet, V. (2014) Retinoic acid receptor subtype-specific transcriptotypes in the early zebrafish embryo. Molecular endocrinology (Baltimore, Md.). 28(2):260-272
- Varshney, G.K., Lu, J., Gildea, D., Huang, H., Pei, W., Yang, Z., Huang, S.C., Schoenfeld, D.S., Pho, N., Casero, D., Hirase, T., Mosbrook-Davis, D.M., Zhang, S., Jao, L.E., Zhang, B., Woods, I.G., Zimmerman, S., Schier, A.F., Wolfsberg, T., Pellegrini, M., Burgess, S.M., and Lin, S. (2013) A large-scale zebrafish gene knockout resource for the genome-wide study of gene function. Genome research. 23(4):727-735
- Wang, D., Jao, L.E., Zheng, N., Dolan, K., Ivey, J., Zonies, S., Wu, X., Wu, K., Yang, H., Meng, Q., Zhu, Z., Zhang, B., Lin, S., and Burgess, S.M. (2007) Efficient genome-wide mutagenesis of zebrafish genes by retroviral insertions. Proceedings of the National Academy of Sciences of the United States of America. 104(30):12428-12433
- Strausberg,R.L., Feingold,E.A., Grouse,L.H., Derge,J.G., Klausner,R.D., Collins,F.S., Wagner,L., Shenmen,C.M., Schuler,G.D., Altschul,S.F., Zeeberg,B., Buetow,K.H., Schaefer,C.F., Bhat,N.K., Hopkins,R.F., Jordan,H., Moore,T., Max,S.I., Wang,J., Hsieh,F., Diatchenko,L., Marusina,K., Farmer,A.A., Rubin,G.M., Hong,L., Stapleton,M., Soares,M.B., Bonaldo,M.F., Casavant,T.L., Scheetz,T.E., Brownstein,M.J., Usdin,T.B., Toshiyuki,S., Carninci,P., Prange,C., Raha,S.S., Loquellano,N.A., Peters,G.J., Abramson,R.D., Mullahy,S.J., Bosak,S.A., McEwan,P.J., McKernan,K.J., Malek,J.A., Gunaratne,P.H., Richards,S., Worley,K.C., Hale,S., Garcia,A.M., Gay,L.J., Hulyk,S.W., Villalon,D.K., Muzny,D.M., Sodergren,E.J., Lu,X., Gibbs,R.A., Fahey,J., Helton,E., Ketteman,M., Madan,A., Rodrigues,S., Sanchez,A., Whiting,M., Madan,A., Young,A.C., Shevchenko,Y., Bouffard,G.G., Blakesley,R.W., Touchman,J.W., Green,E.D., Dickson,M.C., Rodriguez,A.C., Grimwood,J., Schmutz,J., Myers,R.M., Butterfield,Y.S., Krzywinski,M.I., Skalska,U., Smailus,D.E., Schnerch,A., Schein,J.E., Jones,S.J., and Marra,M.A. (2002) Generation and initial analysis of more than 15,000 full-length human and mouse cDNA sequences. Proceedings of the National Academy of Sciences of the United States of America. 99(26):16899-903
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