Gene Details:
- Gene ID: AT5G25900
- Gene Symbol: ATKO1, CYP701A3, GA3
- Gene Name: ARABIDOPSIS THALIANA ENT-KAURENE OXIDASE 1, CYTOCHROME P450 701 A3, GA requiring 3
- Description: GA requiring 3;(source:Araport11)
- TAIR Accession: locus:2180572
- Genome: Araport11_genome_release
- Species: Arabidopsis thaliana
Transcripts:
Plant Ontology Annotations:
- PO:0009005 — root — raíz (Spanish, exact), radices (exact, plural), radix (exact), 根 (Japanese, exact), aerial root (narrow), climbing root (narrow)
- PO:0000084 — plant sperm cell — célula espermática o esperma (Spanish, exact), male gamete (exact), microgamete (exact), 植物精子細胞 (Japanese, exact), sperm nucleus (related), sperm cell (broad)
Gene Ontology:
- GO:0009686 — involved in — gibberellin biosynthetic process
- GO:0009507 — located in — chloroplast
- GO:0010241 — acts upstream of or within — ent-kaurene oxidation to kaurenoic acid
- GO:0009686 — acts upstream of or within — gibberellin biosynthetic process
- GO:0009707 — located in — chloroplast outer membrane
- GO:0052617 — enables — ent-kaur-16-en-19-al oxidase activity
- GO:0009740 — acts upstream of or within — gibberellic acid mediated signaling pathway
- GO:0009707 — is active in — chloroplast outer membrane
- GO:0016709 — enables — oxidoreductase activity, acting on paired donors, with incorporation or reduction of molecular oxygen, NAD(P)H as one donor, and incorporation of one atom of oxygen
- GO:0005506 — enables — iron ion binding
- GO:0005783 — located in — endoplasmic reticulum
- GO:0020037 — enables — heme binding
- GO:0010241 — involved in — ent-kaurene oxidation to kaurenoic acid
- GO:0019825 — enables — oxygen binding
- GO:0052616 — enables — ent-kaur-16-en-19-ol oxidase activity
- GO:0052615 — enables — ent-kaurene oxidase activity
Germplasm Phenotype:
- CS60 — dwarf, responsive to gibberellin; germination increased by gibberellin.
Function-related keywords:
Literature:
- Drought Rhizogenesis in Arabidopsis thaliana (Differential Responses of Hormonal Mutants). DOI: 10.1104/pp.104.2.761 ; PMID: 12232124
- A plastid envelope location of Arabidopsis ent-kaurene oxidase links the plastid and endoplasmic reticulum steps of the gibberellin biosynthesis pathway. DOI: 10.1046/j.1365-313x.2001.01150.x ; PMID: 11722763
- Emission of ent-kaurene, a diterpenoid hydrocarbon precursor for gibberellins, into the headspace from plants. DOI: 10.1093/pcp/pch149 ; PMID: 15509835
- Cold and light control seed germination through the bHLH transcription factor SPATULA. DOI: 10.1016/j.cub.2005.11.010 ; PMID: 16303558
- Mapping the Arabidopsis organelle proteome. DOI: 10.1073/pnas.0506958103 ; PMID: 16618929
- Global identification of DELLA target genes during Arabidopsis flower development. DOI: 10.1104/pp.108.121301 ; PMID: 18502975
- Dynamic landscapes of four histone modifications during deetiolation in Arabidopsis. DOI: 10.1105/tpc.109.066845 ; PMID: 20008096
- Reactivation of meristem activity and sprout growth in potato tubers require both cytokinin and gibberellin. DOI: 10.1104/pp.110.168252 ; PMID: 21163959
- and AHK3-like cytokinin receptors in Brassica napus reveals two subfamilies of AHK2 orthologues. DOI: 10.1093/jxb/eru422 ; PMID: 25336686
- GA-DELLA pathway is involved in regulation of nitrogen deficiency-induced anthocyanin accumulation. DOI: 10.1007/s00299-017-2102-7 ; PMID: 28275852
- Arabidopsis defense mutant ndr1-1 displays accelerated development and early flowering mediated by the hormone gibberellic acid. DOI: 10.1016/j.plantsci.2019.04.006 ; PMID: 31203885
- STO and GA negatively regulate UV-B-induced Arabidopsis root growth inhibition. DOI: 10.1080/15592324.2019.1675471 ; PMID: 31595819
- Ectopic expression of the Arabidopsis florigen gene FLOWERING LOCUS T in seeds enhances seed dormancy via the GA and DOG1 pathways. DOI: 10.1111/tpj.15354 ; PMID: 34037275
- Mapping the Arabidopsis organelle proteome. DOI: 10.1073/pnas.0506958103 ; PMID: 16618929
Sequences:
cDNA Sequence
- >AT5G25900.1
CAAGTTTCTATGAAACGTAAAACGATGAGTTTAGTAAAAAAAAACTAGAGATTATAGTCAGAAAAACTATAATAATAAGAAGATAACATTAAACGGATAGATTCATGTCTCTTTTTTGAAATCCAAAATTGGGTAAAATCCAAAAACCAAAATCTTGCCAAATGCCAATAAGAGCAAAAATCCAAACTTTCCTTTCTCTTCACTATTACACAATGAAATCAACACTACATTTTCACATCAAAATCACATTCCTTCCATGGCCTTCTTCTCCATGATCTCCATTCTCCTTGGCTTTGTTATCTCCTCCTTCATCTTCATCTTCTTCTTCAAGAAACTTCTCTCCTTCTCCAGAAAGAACATGTCTGAAGTCTCCACTCTCCCCTCTGTTCCAGTGGTACCAGGGTTTCCTGTTATTGGGAACTTGCTGCAACTAAAAGAGAAGAAACCTCACAAGACTTTCACTAGATGGTCAGAGATTTATGGTCCTATTTACTCTATAAAGATGGGTTCTTCTTCTCTTATTGTCCTCAATTCTACTGAGACTGCCAAAGAGGCCATGGTGACGCGGTTTTCGTCTATCTCAACGAGGAAGTTGTCAAATGCGTTGACAGTCCTTACTTGTGACAAATCTATGGTTGCTACTAGTGATTATGATGATTTCCACAAGTTGGTGAAACGGTGTCTCTTGAACGGTCTTTTGGGTGCTAATGCACAGAAACGAAAAAGACATTACAGAGATGCACTCATTGAAAATGTGTCTTCCAAGTTGCATGCCCATGCTAGGGACCATCCACAAGAACCTGTAAACTTCAGAGCTATATTTGAGCATGAGCTTTTCGGTGTAGCATTGAAGCAAGCTTTTGGGAAAGATGTGGAATCCATTTATGTTAAAGAACTCGGTGTGACTTTGTCGAAAGACGAGATCTTCAAGGTTTTAGTACATGACATGATGGAAGGTGCAATTGATGTTGATTGGAGAGACTTCTTCCCATACTTGAAATGGATTCCAAATAAAAGTTTTGAAGCAAGAATCCAGCAAAAGCATAAACGTAGACTCGCAGTGATGAATGCTCTGATTCAAGATCGACTGAAGCAGAATGGTTCAGAATCGGATGATGATTGCTATCTCAACTTCTTGATGTCGGAAGCGAAAACACTAACCAAGGAGCAAATTGCTATCTTGGTTTGGGAGACGATTATCGAGACAGCTGACACTACTTTGGTTACAACTGAATGGGCCATCTATGAGCTCGCTAAGCATCCAAGTGTCCAAGATCGTCTGTGCAAAGAAATCCAAAATGTCTGCGGAGGAGAAAAGTTCAAAGAAGAGCAATTGTCTCAAGTTCCTTATCTCAATGGAGTCTTTCATGAAACGCTTAGGAAATACAGTCCTGCTCCTCTAGTTCCCATTCGCTACGCCCACGAGGATACGCAAATCGGAGGCTATCATGTCCCTGCAGGAAGTGAGATTGCAATAAACATATATGGATGCAACATGGATAAGAAGCGTTGGGAGAGACCAGAGGACTGGTGGCCGGAGCGGTTTCTTGATGATGGCAAATATGAAACGTCAGATCTTCACAAGACAATGGCGTTTGGAGCGGGAAAGAGGGTTTGTGCTGGTGCTCTTCAAGCATCTCTCATGGCAGGCATTGCTATTGGAAGATTAGTGCAAGAATTCGAGTGGAAGCTTAGAGATGGCGAAGAAGAGAATGTGGATACATATGGCTTGACCTCTCAGAAGCTTTATCCTCTTATGGCTATTATCAATCCAAGGCGTTCTTAAGACAGAAATCTCTTCTTTCTTTTGTTAGTTTTTAACCTTGTATCAACTTTTATTTGTAACAAATGCTGTTTTGTAGTACTATTTATGTTTTACTGTGTTATATTTTACTATCCTCTGAGATTGCATCATCTTATTGATTCTTATA
CDS Sequence
Protein Sequence