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Basic Information
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CGSNL Gene Symbol
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TOM1
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Gene Symbol Synonym
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OsTOM1, ZIFL4, OsZIFL4
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CGSNL Gene Name
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TRANSPORTER OF MUGINEIC ACID 1
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Gene Name Synonym
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Transporter of mugineic acids 1, zinc-induced facilitator-like 4
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Protein Name
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TRANSPORTER OF MUGINEIC ACID 1
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Allele
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Chromosome No.
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11
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Explanation
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Efflux transporter of phytosiderophore. MAs (mugineic acid family phytosiderophores) efflux transporter. GO:0080167:response to karrikin. GO:1990641: response to iron ion starvation.
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Trait Class
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Biochemical character
Tolerance and resistance - Stress tolerance
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Expression
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Sequence/Locus
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cDNA Accession No.
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AK069533
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MSU ID
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LOC_Os11g04020.1
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RAP ID
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Os11g0134900
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Links
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Oryzabase Chromosome View
(
IRGSP 1.0
/
Build5
)
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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-
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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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Wang W., He F., Zhang H., Yang Y., Wang X., Fu Y., Shou H., Zheng L.
Abiotech 2025 6(2) 215-231
OsbHLH062 regulates iron homeostasis by inhibiting iron deficiency responses in rice.
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Zhu J., Li J., Hu X., Wang J., Fang J., Wang S., Shou H.
J. Exp. Bot. 2024 75(3) 1112-1127
Role of transcription factor complex OsbHLH156-OsIRO2 in regulating manganese, copper, and zinc transporters in rice.
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Wang W., Shinwari K.I., Zhang H., Zhang H., Dong L., He F., Zheng L.
Int J Mol Sci 2022 23(23)
The bHLH Transcription Factor OsbHLH057 Regulates Iron Homeostasis in Rice.
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Kobayashi T., Maeda K., Suzuki Y., Nishizawa N.K.
Rice (N Y) 2022 15(1) 54
Simultaneous Enhancement of iron Deficiency Tolerance and Iron Accumulation in Rice by Combining the Knockdown of OsHRZ Ubiquitin Ligases with the Introduction of Engineered Ferric-chelate Reductase.
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Regon P., Dey S., Rehman M., Pradhan A.K., Chowra U., Tanti B., Talukdar A.D., Panda S.K.
Front Plant Sci 2022 13 798580
Transcriptomic Analysis Revealed Reactive Oxygen Species Scavenging Mechanisms Associated With Ferrous Iron Toxicity in Aromatic Keteki Joha Rice.
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Wang S., Li L., Ying Y., Wang J., Shao J.F., Yamaji N., Whelan J., Ma J.F., Shou H.
New Phytol. 2020 225(3) 1247-1260
A transcription factor OsbHLH156 regulates Strategy II iron acquisition through localising IRO2 to the nucleus in rice.
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Liang G., Zhang H., Li Y., Pu M., Yang Y., Li C., Lu C., Xu P., Yu D.
J Integr Plant Biol 2020 62(5) 668-689
Oryza sativa FER-LIKE FE DEFICIENCY-INDUCED TRANSCRIPTION FACTOR (OsFIT/OsbHLH156) interacts with OsIRO2 to regulate iron homeostasis.
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Mirdar Mansuri R., Shobbar Z.S., Babaeian Jelodar N., Ghaffari M.R., Nematzadeh G.A., Asari S.
Rice (N Y) 2019 12(1) 13
Dissecting molecular mechanisms underlying salt tolerance in rice: a comparative transcriptional profiling of the contrasting genotypes.
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Che J., Yokosho K., Yamaji N., Jian Feng Ma
Plant Physiol. 2019 181(1) 276-288
A Vacuolar Phytosiderophore Transporter Alters Iron and Zinc Accumulation in Polished Rice Grains.
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Kobayashi T., Ozu A., Kobayashi S., An G., Jeon J.S., Nishizawa N.K.
Plant Mol. Biol. 2019 101(4-5) 471-486
OsbHLH058 and OsbHLH059 transcription factors positively regulate iron deficiency responses in rice.
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Aung M.S., Kobayashi T., Masuda H., Nishizawa N.K.
Physiol Plant 2018
Rice HRZ ubiquitin ligases are crucial for response to excess iron.
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Masuda H., Shimochi E., Hamada T., Senoura T., Kobayashi T., Aung M.S., Ishimaru Y., Ogo Y., Nakanishi H., Nishizawa N.K.
PLoS ONE 2017 12(3) e0173441
A new transgenic rice line exhibiting enhanced ferric iron reduction and phytosiderophore production confers tolerance to low iron availability in calcareous soil.
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Kobayashi T., Itai R.N., Senoura T., Oikawa T., Ishimaru Y., Ueda M., Nakanishi H., Nishizawa N.K.
Plant Mol. Biol. 2016 91(4-5) 533-47
Jasmonate signaling is activated in the very early stages of iron deficiency responses in rice roots.
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Kobayashi T.a b, Nakanishi Itai R.c, Nishizawa N.K.b
Rice 2014 7
Iron deficiency responses in rice roots
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Wang L., Ying Y., Narsai R., Ye L., Zheng L., Tian J., Whelan J., Shou H.
Plant Cell Environ. 2012 36(1) 224-36.
Identification of OsbHLH133 as a regulator of iron distribution between roots and shoots in Oryza sativa.
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Kobayashi T., Naoko K Nishizawa
Annu Rev Plant Biol 2012 63 131-52
Iron uptake, translocation, and regulation in higher plants.
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Nozoye T,Nagasaka S,Kobayashi T,Takahashi M,Sato Y,Sato Y,Uozumi N,Nakanishi H,Nishizawa NK
J. Biol. Chem. 2011 286(7) 5446-54
Phytosiderophore efflux transporters are crucial for iron acquisition in graminaceous plants.
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Ricachenevsky F.K., Sperotto R.A., Menguer P.K., Sperb E.R., Lopes K.L., Fett J.P.
BMC Plant Biology 2011 11 -
ZINC-INDUCED FACILITATOR-LIKE family in plants: Lineage-specific expansion in monocotyledons and conserved genomic and expression features among rice (Oryza sativa) paralogs
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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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response to iron(II) ion( GO:0010040 )
response to starvation( GO:0042594 )
response to nematode( GO:0009624 )
plant-type vacuole membrane( GO:0009705 )
response to zinc ion( GO:0010043 )
integral to membrane( GO:0016021 )
transmembrane transport( GO:0055085 )
zinc ion homeostasis( GO:0055069 )
cellular response to iron ion starvation( GO:0010106 )
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Trait Ontology
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iron sensitivity( TO:0000224 )
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Plant Ontology
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root( PO:0009005 )
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Related Strains
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Phenotype images
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Last updated
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Feb 18, 2026
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Update info.