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Basic Information
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CGSNL Gene Symbol
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TIL1
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Gene Symbol Synonym
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NAC2, OsNAC2, ONAC004, ONAC4, ONAC034, ONAC34, ONAC058, ONAC58, OMTN2, Ostil1, OsNAC2/ONAC004, OsORE1.2, DLN113, OsDLN113
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CGSNL Gene Name
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TILLERING 1
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Gene Name Synonym
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NAC domain-containing protein 004, NAC domain-containing protein 4, NAC domain-containing protein 34, NAC domain-containing protein 58, miR164-targeted NAC2, Oryza miR164-targeted NAC2, Oryza sativa tillering1, ORESARA 1.2, DLN repressor 113, DLN motif protein 113
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Protein Name
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NAC DOMAIN-CONTAINING PROTEIN 2
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Allele
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nac2, osnac2
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Chromosome No.
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4
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Explanation
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DQ520641. miR164c target gene. OsNAC2 in Kikuchi et al. 2000, Jiang et al. 2019. Ostil1 and OsNAC2 in Mao et al. 2007. OsNAC092/ ORE1 in Rahman & Ullah 2023. a homolog of Arabidopsis thaliana ORESARA 1. GO:1902512: positive regulation of apoptotic DNA fragmentation. GO:2000280: regulation of root development. TO:0000949: seedling growth and development trait. GO:1900140: regulation of seedling development. GO:1900425: negative regulation of defense response to bacterium. GO:2000031: regulation of salicylic acid mediated signaling pathway.
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Trait Class
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Vegetative organ - Leaf
Vegetative organ - Culm
Vegetative organ - Root
Reproductive organ - Heading date
Seed - Physiological traits - Dormancy
Tolerance and resistance - Disease resistance
Tolerance and resistance - Stress tolerance
Character as QTL - Yield and productivity
Character as QTL - Germination
Other
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Expression
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Sequence/Locus
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cDNA Accession No.
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AK104626
AK071020
AK061745
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MSU ID
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LOC_Os04g38720.1
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RAP ID
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Os04g0460600
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Links
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Oryzabase Chromosome View
(
IRGSP 1.0
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Build5
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RAP-DB
(
IRGSP 1.0
/
Build5
)
Related IDs List (
IRGSP 1.0
/
Build5
)
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INSD Accession List
(Test version)
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Link to INSD Accession List
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Map
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Locate(cM)
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Link map
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Classical linkage map
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References
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Zhong Q., Yu J., Wu Y., Yao X., Mao C., Meng X., Ming F.
Plant Physiol. 2023
Rice transcription factor OsNAC2 maintains the homeostasis of immune responses to bacterial blight.
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Duan E., Lin Q., Wang Y., Ren Y., Xu H., Zhang Y., Wang Y., Teng X., Dong H., Wang Y., Jiang X., Chen X., Lei J., Yang H., Chen R., Jiang L., Wang H., Wan J.
Plant Cell 2023
The transcriptional hub SHORT INTERNODES1 integrates hormone signals to orchestrate rice growth and development.
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Rahman M.A., Ullah H.
Plants (Basel) 2023 12(12)
Receptor for Activated C Kinase1B (RACK1B) Delays Salinity-Induced Senescence in Rice Leaves by Regulating Chlorophyll Degradation.
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Zhou S., Huang K., Zhou Y., Hu Y., Xiao Y., Chen T., Yin M., Liu Y., Xu M., Jiang X.
BMC Plant Biol. 2022 22(1) 269
Degradome sequencing reveals an integrative miRNA-mediated gene interaction network regulating rice seed vigor.
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Yu J., Mao C., Zhong Q., Yao X., Li P., Liu C., Ming F.
Front Plant Sci 2021 12 699303
OsNAC2 Is Involved in Multiple Hormonal Pathways to Mediate Germination of Rice Seeds and Establishment of Seedling.
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Mao C., He J., Liu L., Deng Q., Yao X., Liu C., Qiao Y., Li P., Ming F.
Plant Biotechnol. J. 2020 18(2) 429-442
OsNAC2 integrates auxin and cytokinin pathways to modulate rice root development.
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Sakuraba Y., Kim D., Han S.H., Kim S.H., Piao W., Yanagisawa S., An G., Paek N.C.
Plant Cell 2020 32(3) 630-649
Multilayered Regulation of Membrane-Bound ONAC054 Is Essential for Abscisic Acid-Induced leaf senescence in Rice.
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Jiang D., Zhou L., Chen W., Ye N., Xia J., Zhuang C.
Rice (N Y) 2019 12(1) 76
Overexpression of a microRNA-targeted NAC transcription factor improves drought and salt tolerance in Rice via ABA-mediated pathways.
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Kim T., Kang K., Kim S.H., An G., Paek N.C.
Int J Mol Sci 2019 20(18)
OsWRKY5 Promotes Rice leaf senescence via Senescence-Associated NAC and Abscisic Acid Biosynthesis Pathway.
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Singh P., Mathew I.E., Verma A., Tyagi A.K., Agarwal P.
Int J Mol Sci 2019 20(7)
Analysis of Rice Proteins with DLN repressor Motif/S.
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Mao C., Ding J., Zhang B., Xi D., Ming F.
Plant J. 2018 94(3) 454-468
OsNAC2 positively affects salt-induced cell death and binds to the OsAP37 and OsCOX11 promoters.
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Jiang D., Chen W., Dong J., Li J., Yang F., Wu Z., Zhou H., Wang W., Zhuang C.
J. Exp. Bot. 2018 69(7) 1533-1543
Overexpression of miR164b-resistant OsNAC2 improves plant architecture and grain yield in rice.
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He Q., Yang L., Hu W., Zhang J., Xing Y.
Sci Rep 2018 8(1) 14051
Overexpression of an auxin receptor OsAFB6 significantly enhanced grain yield by increasing cytokinin and decreasing auxin concentrations in rice panicle.
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Burman N., Bhatnagar A., Khurana J.P.
Plant Physiol. 2017
OsbZIP48, a HY5 transcription factor ortholog, exerts pleiotropic effects in light-regulated development.
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Mao C., Lu S., Lv B., Zhang B., Shen J., He J., Luo L., Xi D., Chen X., Ming F.
Plant Physiol. 2017 174(3) 1747-1763
A Rice NAC Transcription Factor Promotes leaf senescence via ABA Biosynthesis.
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Chen X., Lu S., Wang Y., Zhang X., Lv B., Luo L., Xi D., Shen J., Ma H., Ming F.
Plant J. 2015 82(2) 302-14
OsNAC2 encoding a NAC transcription factor that affects plant height through mediating the gibberellic acid pathway in rice.
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Fang Y., Xie K., Xiong L.
J. Exp. Bot. 2014 65(8) 2119-35
Conserved miR164-targeted NAC genes negatively regulate drought resistance in rice.
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Garcia-Morales S.a, Gomez-Merino F.C.b, Trejo-Tellez L.I.a
Acta Physiologiae Plantarum 2014 36 1927-1936
NAC transcription factor expression, amino acid concentration and growth of elite rice cultivars upon salt stress
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Lee S.H., Sakuraba Y., Lee T., Kim K.W., An G., Lee H.Y., Paek N.C.
J Integr Plant Biol 2014
Mutation of Oryza sativa CORONATINE INSENSITIVE 1b (OsCOI1b) delays leaf senescence.
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Ma B., He S.J., Duan K.X., Yin C.C., Chen H., Yang C., Xiong Q., Song Q.X., Lu X., Chen H.W., Zhang W.K., Lu T.G., Chen S.Y., Zhang J.S.
Mol Plant 2013 6(6) 1830-48
Identification of rice ethylene-response mutants and characterization of MHZ7/OsEIN2 in distinct ethylene response and yield trait regulation.
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Nuruzzaman M., Sharoni A.M., Kikuchi S.
Front Microbiol 2013 4 248
Roles of NAC transcription factors in the regulation of biotic and abiotic stress responses in plants.
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Shen H., Yin Y., Chen F., Xu Y., Richard A. Dixon
Bioenerg. Res. 2009 2 217–232
A Bioinformatic Analysis of NAC Genes for Plant Cell Wall Development in Relation to Lignocellulosic Bioenergy Production
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Fang Y., You J., Xie K., Xie W., Xiong L.
Mol. Genet. Genomics 2008 280(6) 547-63
Systematic sequence analysis and identification of tissue-specific or stress-responsive genes of NAC transcription factor family in rice.
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Mao C,Ding W,Wu Y,Yu J,He X,Shou H,Wu P
New Phytol. 2007 176 288-98
Overexpression of a NAC-domain protein promotes shoot branching in rice.
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Ooka H., Satoh K., Doi K., Nagata T., Otomo Y., Murakami K., Matsubara K., Osato N., Kawai J., Carninci P., Hayashizaki Y., Suzuki K., Kojima K., Takahara Y., Yamamoto K., Kikuchi S.
DNA Res. 2003 10(6) 239-47
Comprehensive analysis of NAC family genes in Oryza sativa and Arabidopsis thaliana.
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Kikuchi,K., Ueguchi-Tanaka,M., Yoshida,K.T., Nagato,Y., Matsusoka,M. and Hirano,H.Y.
Mol. Gen. Genet. 2000 262(6) 1047-1051
Molecular analysis of the NAC gene family in rice.
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DB Reference
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Gramene ID
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-
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Ontologies
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Gene Ontology
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regulation of transcription( GO:0045449 )
nucleus( GO:0005634 )
leaf senescence( GO:0010150 )
response to salt stress( GO:0009651 )
DNA binding( GO:0003677 )
regulation of transcription, DNA-dependent( GO:0006355 )
photoperiodism, flowering( GO:0048573 )
gibberellic acid mediated signaling( GO:0009740 )
transcription( GO:0006350 )
response to abscisic acid stimulus( GO:0009737 )
DNA fragmentation involved in apoptosis( GO:0006309 )
positive regulation of cell death( GO:0010942 )
response to auxin stimulus( GO:0009733 )
response to cytokinin stimulus( GO:0009735 )
root development( GO:0048364 )
regulation of cytokinin mediated signaling( GO:0080036 )
regulation of auxin mediated signaling pathway( GO:0010928 )
response to water deprivation( GO:0009414 )
response to osmotic stress( GO:0006970 )
abscisic acid mediated signaling( GO:0009738 )
regulation of seed germination( GO:0010029 )
negative regulation of seed germination( GO:0010187 )
response to ethylene stimulus( GO:0009723 )
positive regulation of ethylene biosynthetic process( GO:0010365 )
negative regulation of abscisic acid mediated signaling( GO:0009788 )
defense response to bacterium( GO:0042742 )
salicylic acid mediated signaling pathway( GO:0009863 )
response to salicylic acid stimulus( GO:0009751 )
regulation of salicylic acid biosynthetic process( GO:0080142 )
negative regulation of hydrogen peroxide biosynthetic process( GO:0010730 )
negative regulation of immune response( GO:0050777 )
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Trait Ontology
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drought tolerance( TO:0000276 )
tiller number( TO:0000346 )
plant height( TO:0000207 )
leaf senescence( TO:0000249 )
shoot branching( TO:0002639 )
tiller angle( TO:0000567 )
salt tolerance( TO:0006001 )
flowering time( TO:0002616 )
spikelet length( TO:0002768 )
internode length( TO:0000145 )
gibberellic acid sensitivity( TO:0000166 )
abscisic acid content( TO:0002667 )
abscisic acid sensitivity( TO:0000615 )
grain yield( TO:0000396 )
grain number( TO:0002759 )
panicle length( TO:0000040 )
grain yield per panicle( TO:0000450 )
anatomy and morphology related trait( TO:0000017 )
hydrogen peroxide content( TO:0000605 )
root development trait( TO:0000656 )
root length( TO:0000227 )
crown root number( TO:0002685 )
cytokinin content( TO:0002660 )
cytokinin sensitivity( TO:0000167 )
auxin sensitivity( TO:0000163 )
osmotic response sensitivity( TO:0000095 )
germination rate( TO:0000430 )
ethylene sensitivity( TO:0000173 )
bacterial blight disease resistance( TO:0000175 )
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Plant Ontology
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4 leaf senescence stage( PO:0001054 )
root tip( PO:0000025 )
crown root( PO:0000043 )
root primordium( PO:0005029 )
lateral root( PO:0020121 )
0 seed germination stage( PO:0007057 )
coleoptile emergence stage( PO:0007045 )
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Related Strains
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Phenotype images
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Last updated
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Mar 8, 2025
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Update info.