PlantTFDB
PlantRegMap/PlantTFDB v5.0
Plant Transcription Factor Database
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(e.g., LFY)
Transcription Factor Information
Basic Information | Signature Domain | Sequence | 
Basic Information? help Back to Top
TF ID Lsa015049
Organism
Lactuca sativa
Taxonomic ID
Taxonomic Lineage
cellular organisms; Eukaryota; Viridiplantae; Streptophyta; Streptophytina; Embryophyta; Tracheophyta; Euphyllophyta; Spermatophyta; Magnoliophyta; Mesangiospermae; eudicotyledons; Gunneridae; Pentapetalae; asterids; campanulids; Asterales; Asteraceae; Cichorioideae; Cichorieae; Lactucinae; Lactuca
Family ERF
Protein Properties Length: 220aa    MW: 24949 Da    PI: 5.4233
Description ERF family protein
Gene Model
Gene Model ID Type Source Coding Sequence
gnl|UG|Lsa#S58674067PU_refUnigeneView CDS
Signature Domain? help Back to Top
Signature Domain
No. Domain Score E-value Start End HMM Start HMM End
1AP251.72.1e-1683133255
        AP2   2 gykGVrwdkkrgrWvAeIrdpsengkrkrfslgkfgtaeeAakaaiaarkkleg 55 
                ++ GVr ++ +g+++AeIrd + ng   r++lg+f++aeeAa  +++a+ +++g
  Lsa015049  83 RFIGVRKRP-WGKFAAEIRDSTRNG--IRVWLGTFDSAEEAALIYDQAAFSMRG 133
                789******.**********44465..*************************98 PP
Protein Features ? help Back to Top
3D Structure
Database Entry ID E-value Start End InterPro ID Description
CDDcd000182.11E-2782141No hitNo description
PfamPF008472.5E-1183133IPR001471AP2/ERF domain
SuperFamilySSF541714.25E-2083143IPR016177DNA-binding domain
SMARTSM003801.3E-3283147IPR001471AP2/ERF domain
PROSITE profilePS5103220.79883141IPR001471AP2/ERF domain
Gene3DG3DSA:3.30.730.107.0E-2784142IPR001471AP2/ERF domain
PRINTSPR003676.5E-88495IPR001471AP2/ERF domain
PRINTSPR003676.5E-8107123IPR001471AP2/ERF domain
Gene Ontology ? help Back to Top
GO Term GO Category GO Description
GO:0006355Biological Processregulation of transcription, DNA-templated
GO:0003677Molecular FunctionDNA binding
GO:0003700Molecular Functiontranscription factor activity, sequence-specific DNA binding
Sequence ? help Back to Top
Protein Sequence    Length: 220 aa     Download sequence    Send to blast
MCSFPNLEFF PMSPCSWDEL IFSHEMLSAE VQIKEENIIF QDPTDDHYEL SSEIDLSKTS  60
HDRGQILEVI TKPKEEPDVQ KTRFIGVRKR PWGKFAAEIR DSTRNGIRVW LGTFDSAEEA  120
ALIYDQAAFS MRGSSTQLNF PMERVKESLK GKSYTSFKDG SSPAAVIKET HRVRRISKCK  180
RNNKNQDSQK IPVVFEDLGS DLLDQLLGTS EISSSSSTNS
3D Structure ? help Back to Top
Structure
PDB ID Evalue Query Start Query End Hit Start Hit End Description
1gcc_A4e-2686142561ETHYLENE RESPONSIVE ELEMENT BINDING FACTOR 1
Search in ModeBase
Functional Description ? help Back to Top
Source Description
UniProtActs as a transcriptional activator. Binds to the GCC-box pathogenesis-related promoter element. Involved in the regulation of gene expression during the plant development, and/or mediated by stress factors and by components of stress signal transduction pathways. Seems to be a key integrator of ethylene and jasmonate signals in the regulation of ethylene/jasmonate-dependent defenses. Can mediate resistance to necrotizing fungi (Botrytis cinerea and Plectosphaerella cucumerina) and to soil borne fungi (Fusarium oxysporum conglutinans and Fusiarium oxysporum lycopersici), but probably not to necrotizing bacteria (Pseudomonas syringae tomato). {ECO:0000269|PubMed:11950980, ECO:0000269|PubMed:12060224, ECO:0000269|PubMed:12509529, ECO:0000269|PubMed:15242170, ECO:0000269|PubMed:9851977}.
Regulation -- Description ? help Back to Top
Source Description
UniProtINDUCTION: Induced by Pseudomonas syringae tomato (both virulent and avirulent avrRpt2 strains), independently of PAD4. Ethylene induction is completely dependent on functional ETHYLENE-INSENSITIVE2 (EIN2), ETHYLENE-INSENSITIVE3 (EIN3), which is itself a transcription factor and CORONATIVE-INSENSITIVE1 (COI1) proteins. Induction by jasmonate, B.cinerea or F.oxysporum as well as the synergistic induction by ethylene and jasmonate requires EIN2 and COI1. Induction by methyl jasmonate (MeJA) is independent of JAR1. Induction by salicylic acid (SA) is dependent on NPR1 but not on PAD4. Seems not to be induced by Alternaria brassicicola. {ECO:0000269|PubMed:11950980, ECO:0000269|PubMed:12060224, ECO:0000269|PubMed:12509529, ECO:0000269|PubMed:12805630, ECO:0000269|PubMed:15242170, ECO:0000269|PubMed:9851977}.
Annotation -- Protein ? help Back to Top
Source Hit ID E-value Description
RefseqXP_023760105.11e-163ethylene-responsive transcription factor 1B-like
SwissprotQ8LDC86e-47ERF92_ARATH; Ethylene-responsive transcription factor 1B
TrEMBLA0A2J6LLV51e-152A0A2J6LLV5_LACSA; Uncharacterized protein
STRINGMigut.K00942.1.p1e-51(Erythranthe guttata)
Publications ? help Back to Top
  1. Zarate SI,Kempema LA,Walling LL
    Silverleaf whitefly induces salicylic acid defenses and suppresses effectual jasmonic acid defenses.
    Plant Physiol., 2007. 143(2): p. 866-75
    [PMID:17189328]
  2. Vahabi K,Camehl I,Sherameti I,Oelmüller R
    Growth of Arabidopsis seedlings on high fungal doses of Piriformospora indica has little effect on plant performance, stress, and defense gene expression in spite of elevated jasmonic acid and jasmonic acid-isoleucine levels in the roots.
    Plant Signal Behav, 2013. 8(11): p. e26301
    [PMID:24047645]
  3. Kim HG, et al.
    GDSL LIPASE1 modulates plant immunity through feedback regulation of ethylene signaling.
    Plant Physiol., 2013. 163(4): p. 1776-91
    [PMID:24170202]
  4. Li J,Jia H,Wang J
    cGMP and ethylene are involved in maintaining ion homeostasis under salt stress in Arabidopsis roots.
    Plant Cell Rep., 2014. 33(3): p. 447-59
    [PMID:24306353]
  5. Zhong S, et al.
    Ethylene-orchestrated circuitry coordinates a seedling's response to soil cover and etiolated growth.
    Proc. Natl. Acad. Sci. U.S.A., 2014. 111(11): p. 3913-20
    [PMID:24599595]
  6. Kim HG, et al.
    GDSL lipase 1 regulates ethylene signaling and ethylene-associated systemic immunity in Arabidopsis.
    FEBS Lett., 2014. 588(9): p. 1652-8
    [PMID:24631536]
  7. Schellingen K, et al.
    Cadmium-induced ethylene production and responses in Arabidopsis thaliana rely on ACS2 and ACS6 gene expression.
    BMC Plant Biol., 2014. 14: p. 214
    [PMID:25082369]
  8. Ellouzi H, et al.
    A comparative study of the early osmotic, ionic, redox and hormonal signaling response in leaves and roots of two halophytes and a glycophyte to salinity.
    Planta, 2014. 240(6): p. 1299-317
    [PMID:25156490]
  9. Nguyen AH, et al.
    Loss of Arabidopsis 5'-3' Exoribonuclease AtXRN4 Function Enhances Heat Stress Tolerance of Plants Subjected to Severe Heat Stress.
    Plant Cell Physiol., 2015. 56(9): p. 1762-72
    [PMID:26136597]
  10. Cheng MC,Kuo WC,Wang YM,Chen HY,Lin TP
    UBC18 mediates ERF1 degradation under light-dark cycles.
    New Phytol., 2017. 213(3): p. 1156-1167
    [PMID:27787902]
  11. Timmermann T, et al.
    Paraburkholderia phytofirmans PsJN Protects Arabidopsis thaliana Against a Virulent Strain of Pseudomonas syringae Through the Activation of Induced Resistance.
    Mol. Plant Microbe Interact., 2017. 30(3): p. 215-230
    [PMID:28118091]
  12. Yu Y,Huang R
    Integration of Ethylene and Light Signaling Affects Hypocotyl Growth in Arabidopsis.
    Front Plant Sci, 2017. 8: p. 57
    [PMID:28174592]
  13. Lestari R, et al.
    Overexpression of Hevea brasiliensis ethylene response factor HbERF-IXc5 enhances growth and tolerance to abiotic stress and affects laticifer differentiation.
    Plant Biotechnol. J., 2018. 16(1): p. 322-336
    [PMID:28626940]
  14. Dinolfo MI,Castañares E,Stenglein SA
    Resistance of Fusarium poae in Arabidopsis leaves requires mainly functional JA and ET signaling pathways.
    Fungal Biol, 2017. 121(10): p. 841-848
    [PMID:28889908]