PlantTFDB - Plant Transcription Factor Database @ CBI, PKU

PlantRegMap/PlantTFDB v5.0

Plant Transcription Factor Database

Transcription Factor Information

Basic Information | Signature Domain | Sequence |

Basic Information? help Back to Top

TF ID

GSBRNA2T00135488001

Common Name

Bn9CON10, GSBRNA2T00135488001

Organism

Brassica napus

Taxonomic ID

3708

Taxonomic Lineage

cellular organisms; Eukaryota; Viridiplantae; Streptophyta; Streptophytina; Embryophyta; Tracheophyta; Euphyllophyta; Spermatophyta; Magnoliophyta; Mesangiospermae; eudicotyledons; Gunneridae; Pentapetalae; rosids; malvids; Brassicales; Brassicaceae; Brassiceae; Brassica

Family

CO-like

Protein Properties

Length: 369aa MW: 41929.6 Da PI: 7.8219

Description

CO-like family protein

Gene Model

Gene Model ID	Type	Source	Coding Sequence
GSBRNA2T00135488001	genome	Genoscope	View CDS

Signature Domain? help Back to Top

No.	Domain	Score	E-value	Start	End	HMM Start	HMM End
1	zf-B_box	18.4	4.4e-06	20	62	4	40
zf-B_box 4 rkCpeHeekelqlfCedCqqllCedClleeHkg......Htvv 40 r C+++++ + +C+ ++ +lC++C + H+ H++v GSBRNA2T00135488001 20 RACDTCGSTICTVYCHADSAYLCNSCDAQVHSAnrvasrHKRV 62 78****99*******************667788888876 PP
2	zf-B_box	32.3	2.1e-10	61	107	2	42
zf-B_box 2 eerkCpeHeekelqlfCedCqqllCedClleeHkg......Htvvpl 42 + r+C+ +e+ ++ + Ce +++ lC C le H+ H++vp+ GSBRNA2T00135488001 61 RVRVCESCERAPAAFMCEADDVSLCTACDLEVHSAnplarrHQRVPV 107 5689****************************6689999999986 PP
3	CCT	65.3	1.8e-22	295	338	1	44
CCT 1 ReaallRYkeKrktRkFeKkirYesRKavAesRpRvKGrFvkqa 44 Rea++lRY+eK+k+RkFeK+irY+sRKa+Ae+RpR++GrF+k + GSBRNA2T00135488001 295 REARVLRYREKKKRRKFEKTIRYASRKAYAERRPRINGRFAKIS 338 9****************************************986 PP

Protein Features ? help Back to Top

Database	Entry ID	E-value	Start	End	InterPro ID	Description
SMART	SM00336	3.2E-9	17	64	IPR000315	B-box-type zinc finger
PROSITE profile	PS50119	10.409	17	64	IPR000315	B-box-type zinc finger
CDD	cd00021	1.79E-6	20	64	No hit	No description
PROSITE profile	PS50119	11.818	60	107	IPR000315	B-box-type zinc finger
Pfam	PF00643	2.0E-8	62	107	IPR000315	B-box-type zinc finger
CDD	cd00021	1.20E-8	63	107	No hit	No description
SMART	SM00336	1.2E-11	65	107	IPR000315	B-box-type zinc finger
Pfam	PF06203	2.4E-16	295	336	IPR010402	CCT domain
PROSITE profile	PS51017	16.073	295	337	IPR010402	CCT domain

Gene Ontology ? help Back to Top
GO Term	GO Category	GO Description
GO:0005622	Cellular Component	intracellular
GO:0005515	Molecular Function	protein binding
GO:0008270	Molecular Function	zinc ion binding

Sequence ? help Back to Top
Protein Sequence Length: 369 aa Download sequence Send to blast
MFKQESNNNI CNRENNRGAR ACDTCGSTIC TVYCHADSAY LCNSCDAQVH SANRVASRHK 60 RVRVCESCER APAAFMCEAD DVSLCTACDL EVHSANPLAR RHQRVPVVPI TGNSCSSLAT 120 ANHTTVTEPE KRVVLVQEDA KETASWLFPK NSDNHNNNNN QNNELLFSDD YLDLADYNSS 180 MDYKFTGQYN QPTQHKQDCT VPEKNYGGDR VVPLQLEETR GNLHHKQHNI TYGSSGSHYN 240 NNGSINHNAY NPSMETDFVP EQTAPDKTVS HPKTHKGKIE KLPEPLIQIL SPMDREARVL 300 RYREKKKRRK FEKTIRYASR KAYAERRPRI NGRFAKISET EVEDQEYNTM LMYYDTGYGI 360 VPSFYGQK*

Sequence ? help Back to Top

Protein Sequence Length: 369 aa Download sequence Send to blast

MFKQESNNNI CNRENNRGAR ACDTCGSTIC TVYCHADSAY LCNSCDAQVH SANRVASRHK  60
RVRVCESCER APAAFMCEAD DVSLCTACDL EVHSANPLAR RHQRVPVVPI TGNSCSSLAT  120
ANHTTVTEPE KRVVLVQEDA KETASWLFPK NSDNHNNNNN QNNELLFSDD YLDLADYNSS  180
MDYKFTGQYN QPTQHKQDCT VPEKNYGGDR VVPLQLEETR GNLHHKQHNI TYGSSGSHYN  240
NNGSINHNAY NPSMETDFVP EQTAPDKTVS HPKTHKGKIE KLPEPLIQIL SPMDREARVL  300
RYREKKKRRK FEKTIRYASR KAYAERRPRI NGRFAKISET EVEDQEYNTM LMYYDTGYGI  360
VPSFYGQK*

Nucleic Localization Signal ? help Back to Top

No.	Start	End	Sequence
1	304	308	KKKRR
2	304	309	KKKRRK
3	305	309	KKRRK

Expression -- Description ? help Back to Top
Source	Description
Uniprot	TISSUE SPECIFICITY: Expressed in leaves, shoots and shoot apical meristem. Detected in the vascular tissue of the hypocotyl, the cotyledons and the leaves. Restricted to the protoxylem and phloem in young inflorescence stems and to the phloem only in older inflorescences. Also detected in the vascular tissue of the root. {ECO:0000269\|PubMed:15229176}.

Functional Description ? help Back to Top
Source	Description
UniProt	Transcription factor that acts in the long day flowering pathway and may mediate between the circadian clock and the control of flowering. Plays a role in the regulation of flowering time by acting on 'SUPPRESSOR OF OVEREXPRESSION OF CO1', 'TERMINAL FLOWER 1' and 'FLOWERING LOCUS T'. Also regulates P5CS2 and ACS10 (involved in proline and ethylene biosynthesis, respectively). Regulates the expression of NAKR1 by binding to the 5'-TGTG(N2-3)ATG-3' motif (PubMed:27255839). {ECO:0000269\|PubMed:10834834, ECO:0000269\|PubMed:11323677, ECO:0000269\|PubMed:21950734, ECO:0000269\|PubMed:27255839}.

Cis-element ? help Back to Top
Source	Link
PlantRegMap	GSBRNA2T00135488001

Regulation -- Description ? help Back to Top
Source	Description
UniProt	INDUCTION: Expressed with a circadian rhythm showing a broad peak between 12 hours and dawn. Higher expression under long days.

Regulation -- PlantRegMap ? help Back to Top
Source	Upstream Regulator	Target Gene
PlantRegMap	Retrieve	-

Annotation -- Nucleotide ? help Back to Top
Source	Hit ID	E-value	Description
GenBank	AF016011	0.0	AF016011.1 Brassica napus CONSTANS homolog (Bn9CON10) gene, complete cds.

Annotation -- Protein ? help Back to Top
Source	Hit ID	E-value	Description
Refseq	XP_009121540.1	0.0	PREDICTED: zinc finger protein CONSTANS
Swissprot	Q39057	0.0	CONS_ARATH; Zinc finger protein CONSTANS
TrEMBL	A0A3P6DFZ4	0.0	A0A3P6DFZ4_BRACM; Uncharacterized protein
TrEMBL	O48885	0.0	O48885_BRANA; CONSTANS homolog
STRING	Bra008669.1-P	0.0	(Brassica rapa)

Orthologous Group ? help Back to Top
Lineage	Orthologous Group ID	Taxa Number	Gene Number
Malvids	OGEM2128	26	70

Best hit in Arabidopsis thaliana ? help Back to Top
Hit ID	E-value	Description
AT5G15840.1	1e-146	B-box type zinc finger protein with CCT domain

Publications ? help Back to Top
Yeoh CC, et al. Fine mapping links the FTa1 flowering time regulator to the dominant spring1 locus in Medicago. PLoS ONE, 2013. 8(1): p. e53467 [PMID:23308229] Joon Seo P,Jung JH,Park MJ,Lee K,Park CM Controlled turnover of CONSTANS protein by the HOS1 E3 ligase regulates floral transition at low temperatures. Plant Signal Behav, 2013. 8(4): p. e23780 [PMID:23425850] Yu Y, et al. MlWRKY12, a novel Miscanthus transcription factor, participates in pith secondary cell wall formation and promotes flowering. Plant Sci., 2013. 212: p. 1-9 [PMID:24094048] Sgamma T,Jackson A,Muleo R,Thomas B,Massiah A TEMPRANILLO is a regulator of juvenility in plants. Sci Rep, 2014. 4: p. 3704 [PMID:24424565] Qian H, et al. The circadian clock gene regulatory module enantioselectively mediates imazethapyr-induced early flowering in Arabidopsis thaliana. J. Plant Physiol., 2014. 171(5): p. 92-8 [PMID:24484962] Ortiz-Marchena MI, et al. Photoperiodic control of carbon distribution during the floral transition in Arabidopsis. Plant Cell, 2014. 26(2): p. 565-84 [PMID:24563199] Endo M,Kudo D,Koto T,Shimizu H,Araki T Light-dependent destabilization of PHL in Arabidopsis. Plant Signal Behav, 2014. 9(3): p. e28118 [PMID:24614229] Steinbach Y,Hennig L Arabidopsis MSI1 functions in photoperiodic flowering time control. Front Plant Sci, 2014. 5: p. 77 [PMID:24639681] Johansson M,Staiger D SRR1 is essential to repress flowering in non-inductive conditions in Arabidopsis thaliana. J. Exp. Bot., 2014. 65(20): p. 5811-22 [PMID:25129129] Chalhoub B, et al. Plant genetics. Early allopolyploid evolution in the post-Neolithic Brassica napus oilseed genome. Science, 2014. 345(6199): p. 950-3 [PMID:25146293] Shim JS,Imaizumi T Circadian clock and photoperiodic response in Arabidopsis: from seasonal flowering to redox homeostasis. Biochemistry, 2015. 54(2): p. 157-70 [PMID:25346271] Fu J,Yang L,Dai S Identification and characterization of the CONSTANS-like gene family in the short-day plant Chrysanthemum lavandulifolium. Mol. Genet. Genomics, 2015. 290(3): p. 1039-54 [PMID:25523304] Song YH,Shim JS,Kinmonth-Schultz HA,Imaizumi T Photoperiodic flowering: time measurement mechanisms in leaves. Annu Rev Plant Biol, 2015. 66: p. 441-64 [PMID:25534513] Liu T,Zhu S,Tang Q,Tang S Identification of a CONSTANS homologous gene with distinct diurnal expression patterns in varied photoperiods in ramie (Boehmeria nivea L. Gaud). Gene, 2015. 560(1): p. 63-70 [PMID:25623329] Golembeski GS,Kinmonth-Schultz HA,Song YH,Imaizumi T Photoperiodic flowering regulation in Arabidopsis thaliana. Adv. Bot. Res., 2014. 72: p. 1-28 [PMID:25684830] Leal Valentim F, et al. A quantitative and dynamic model of the Arabidopsis flowering time gene regulatory network. PLoS ONE, 2015. 10(2): p. e0116973 [PMID:25719734] Han Y,Zhang X,Wang W,Wang Y,Ming F Correction: the suppression of WRKY44 by GIGANTEA-miR172 pathway is involved in drought response of Arabidopsis thaliana. PLoS ONE, 2015. 10(4): p. e0124854 [PMID:25844872] Lucas-Reina E,Romero-Campero FJ,Romero JM,Valverde F An Evolutionarily Conserved DOF-CONSTANS Module Controls Plant Photoperiodic Signaling. Plant Physiol., 2015. 168(2): p. 561-74 [PMID:25897001] Simon S,Rühl M,de Montaigu A,Wötzel S,Coupland G Evolution of CONSTANS Regulation and Function after Gene Duplication Produced a Photoperiodic Flowering Switch in the Brassicaceae. Mol. Biol. Evol., 2015. 32(9): p. 2284-301 [PMID:25972346] Ortiz-Marchena MI,Romero JM,Valverde F Photoperiodic control of sugar release during the floral transition: What is the role of sugars in the florigenic signal? Plant Signal Behav, 2015. 10(5): p. e1017168 [PMID:26039474] Wang C,Dehesh K From retrograde signaling to flowering time. Plant Signal Behav, 2015. 10(6): p. e1022012 [PMID:26098376] Hajdu A, et al. High-level expression and phosphorylation of phytochrome B modulates flowering time in Arabidopsis. Plant J., 2015. 83(5): p. 794-805 [PMID:26120968] Golembeski GS,Imaizumi T Photoperiodic Regulation of Florigen Function in Arabidopsis thaliana. Arabidopsis Book, 2015. 13: p. e0178 [PMID:26157354] Jang K,Lee HG,Jung SJ,Paek NC,Seo PJ The E3 Ubiquitin Ligase COP1 Regulates Thermosensory Flowering by Triggering GI Degradation in Arabidopsis. Sci Rep, 2015. 5: p. 12071 [PMID:26159740] Marín-González E, et al. SHORT VEGETATIVE PHASE Up-Regulates TEMPRANILLO2 Floral Repressor at Low Ambient Temperatures. Plant Physiol., 2015. 169(2): p. 1214-24 [PMID:26243615] Sarid-Krebs L, et al. Phosphorylation of CONSTANS and its COP1-dependent degradation during photoperiodic flowering of Arabidopsis. Plant J., 2015. 84(3): p. 451-63 [PMID:26358558] Lazaro A,Mouriz A,Piñeiro M,Jarillo JA Red Light-Mediated Degradation of CONSTANS by the E3 Ubiquitin Ligase HOS1 Regulates Photoperiodic Flowering in Arabidopsis. Plant Cell, 2015. 27(9): p. 2437-54 [PMID:26373454] Matsoukas IG Florigens and antiflorigens: a molecular genetic understanding. Essays Biochem., 2015. 58: p. 133-49 [PMID:26374892] Mulki MA,von Korff M CONSTANS Controls Floral Repression by Up-Regulating VERNALIZATION2 (VRN-H2) in Barley. Plant Physiol., 2016. 170(1): p. 325-37 [PMID:26556793] Xu L, et al. Genome-wide association study reveals the genetic architecture of flowering time in rapeseed (Brassica napus L.). DNA Res., 2016. 23(1): p. 43-52 [PMID:26659471] Wada T,Tominaga-Wada R CAPRICE family genes control flowering time through both promoting and repressing CONSTANS and FLOWERING LOCUS T expression. Plant Sci., 2015. 241: p. 260-5 [PMID:26706076] Tang Q, et al. The mitogen-activated protein kinase phosphatase PHS1 regulates flowering in Arabidopsis thaliana. Planta, 2016. 243(4): p. 909-23 [PMID:26721646] Xu F, et al. DELLA proteins physically interact with CONSTANS to regulate flowering under long days in Arabidopsis. FEBS Lett., 2016. 590(4): p. 541-9 [PMID:26801684] Kinmonth-Schultz HA, et al. Cool night-time temperatures induce the expression of CONSTANS and FLOWERING LOCUS T to regulate flowering in Arabidopsis. New Phytol., 2016. 211(1): p. 208-24 [PMID:26856528] Sun X, et al. The Oryza sativa Regulator HDR1 Associates with the Kinase OsK4 to Control Photoperiodic Flowering. PLoS Genet., 2016. 12(3): p. e1005927 [PMID:26954091] Nemoto Y,Nonoue Y,Yano M,Izawa T Hd1,a CONSTANS ortholog in rice, functions as an Ehd1 repressor through interaction with monocot-specific CCT-domain protein Ghd7. Plant J., 2016. 86(3): p. 221-33 [PMID:26991872] Fernández V,Takahashi Y,Le Gourrierec J,Coupland G Photoperiodic and thermosensory pathways interact through CONSTANS to promote flowering at high temperature under short days. Plant J., 2016. 86(5): p. 426-40 [PMID:27117775] Zhu Y,Liu L,Shen L,Yu H NaKR1 regulates long-distance movement of FLOWERING LOCUS T in Arabidopsis. Nat Plants, 2016. 2(6): p. 16075 [PMID:27255839] Wang H, et al. The DELLA-CONSTANS Transcription Factor Cascade Integrates Gibberellic Acid and Photoperiod Signaling to Regulate Flowering. Plant Physiol., 2016. 172(1): p. 479-88 [PMID:27406167] Gil KE, et al. Alternative splicing provides a proactive mechanism for the diurnal CONSTANS dynamics in Arabidopsis photoperiodic flowering. Plant J., 2017. 89(1): p. 128-140 [PMID:27607358] Shim JS,Kubota A,Imaizumi T Circadian Clock and Photoperiodic Flowering in Arabidopsis: CONSTANS Is a Hub for Signal Integration. Plant Physiol., 2017. 173(1): p. 5-15 [PMID:27688622] Park HJ,Kim WY,Pardo JM,Yun DJ Molecular Interactions Between Flowering Time and Abiotic Stress Pathways. Int Rev Cell Mol Biol, 2016. 327: p. 371-412 [PMID:27692179] Riboni M,Robustelli Test A,Galbiati M,Tonelli C,Conti L ABA-dependent control of GIGANTEA signalling enables drought escape via up-regulation of FLOWERING LOCUS T in Arabidopsis thaliana. J. Exp. Bot., 2016. 67(22): p. 6309-6322 [PMID:27733440] Song YH The Effect of Fluctuations in Photoperiod and Ambient Temperature on the Timing of Flowering: Time to Move on Natural Environmental Conditions. Mol. Cells, 2016. 39(10): p. 715-721 [PMID:27788575] Hayama R, et al. PSEUDO RESPONSE REGULATORs stabilize CONSTANS protein to promote flowering in response to day length. EMBO J., 2017. 36(7): p. 904-918 [PMID:28270524] Gnesutta N, et al. CONSTANS Imparts DNA Sequence Specificity to the Histone Fold NF-YB/NF-YC Dimer. Plant Cell, 2017. 29(6): p. 1516-1532 [PMID:28526714] Liu J, et al. MicroRNA319-regulated TCPs interact with FBHs and PFT1 to activate CO transcription and control flowering time in Arabidopsis. PLoS Genet., 2017. 13(5): p. e1006833 [PMID:28558040] Cai D,Liu H,Sang N,Huang X Identification and characterization of CONSTANS-like (COL) gene family in upland cotton (Gossypium hirsutum L.). PLoS ONE, 2017. 12(6): p. e0179038 [PMID:28591177] Kubota A, et al. TCP4-dependent induction of CONSTANS transcription requires GIGANTEA in photoperiodic flowering in Arabidopsis. PLoS Genet., 2017. 13(6): p. e1006856 [PMID:28628608] Shibuta M,Abe M FE Controls the Transcription of Downstream Flowering Regulators Through Two Distinct Mechanisms in Leaf Phloem Companion Cells. Plant Cell Physiol., 2017. 58(11): p. 2017-2025 [PMID:29036620] Kurokura T,Samad S,Koskela E,Mouhu K,Hytönen T Fragaria vesca CONSTANS controls photoperiodic flowering and vegetative development. J. Exp. Bot., 2017. 68(17): p. 4839-4850 [PMID:29048562] Hassidim M, et al. CIRCADIAN CLOCK ASSOCIATED1 (CCA1) and the Circadian Control of Stomatal Aperture. Plant Physiol., 2017. 175(4): p. 1864-1877 [PMID:29084902] Ordoñez-Herrera N, et al. The Transcription Factor COL12 Is a Substrate of the COP1/SPA E3 Ligase and Regulates Flowering Time and Plant Architecture. Plant Physiol., 2018. 176(2): p. 1327-1340 [PMID:29187570] Kumar S,Choudhary P,Gupta M,Nath U VASCULAR PLANT ONE-ZINC FINGER1 (VOZ1) and VOZ2 Interact with CONSTANS and Promote Photoperiodic Flowering Transition. Plant Physiol., 2018. 176(4): p. 2917-2930 [PMID:29507119] Kumar A,Singh A,Panigrahy M,Sahoo PK,Panigrahi KCS Carbon nanoparticles influence photomorphogenesis and flowering time in Arabidopsis thaliana. Plant Cell Rep., 2018. 37(6): p. 901-912 [PMID:29541883] Liu Y, et al. CIB1 and CO interact to mediate CRY2-dependent regulation of flowering. EMBO Rep., 2019. [PMID:30126927] Robert LS,Robson F,Sharpe A,Lydiate D,Coupland G Conserved structure and function of the Arabidopsis flowering time gene CONSTANS in Brassica napus. Plant Mol. Biol., 1998. 37(5): p. 763-72 [PMID:9678571]