- Information
- Symbol: LIC,OsLIC1,OsLIC,OsFLA6
- MSU: LOC_Os06g49080
- RAPdb: Os06g0704300
- Publication
- Dynamics of brassinosteroid response modulated by negative regulator LIC in rice, 2012, PLoS Genet.
- OsLIC, a Novel CCCH-Type Zinc Finger Protein with Transcription Activation, Mediates Rice Architecture via Brassinosteroids Signaling, 2008, PLoS One.
- OsRELA Regulates Leaf Inclination by Repressing the Transcriptional Activity of OsLIC in Rice, 2021, Front Plant Sci.
- OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak., 2022, J Integr Plant Biol.
- An Analysis of Natural Variation Reveals That OsFLA2 Controls Flag Leaf Angle in Rice Oryza sativa L.., 2022, Front Plant Sci.
- Genbank accession number
- Key message
- Suppression of endogenous OsLIC expression resulted in drastically increased leaf and tiller angles, shortened shoot height, and consequently reduced grain production in rice
- Here, we demonstrate that Oryza sativa LEAF and TILLER ANGLE INCREASED CONTROLLER (LIC) acts as an antagonistic transcription factor of BRASSINAZOLE-RESISTANT 1 (BZR1) to attenuate the BR signaling pathway
- OsLIC, a Novel CCCH-Type Zinc Finger Protein with Transcription Activation, Mediates Rice Architecture via Brassinosteroids Signaling
- Quantitative PCR revealed LIC transcription rapidly induced by BR treatment
- Image analysis and immunoblotting showed that upon BR treatment LIC proteins translocate from the cytoplasm to the nucleus in a phosphorylation-dependent fashion
- Molecular and physiology assays revealed that LIC plays a dominant role at high BR levels, whereas BZR1 is dominant at low levels
- Here we describe a novel CCCH-type zinc finger gene, OsLIC (Oraza sativaleaf and tiller angle increased controller), which is involved in the regulation of rice plant architecture
- OsLIC may be a transcription activator to control rice plant architecture
- OsLIC is predominantly expressed in rice collar and tiller bud
- The gain-of-function mutant lic-1 and LIC-overexpressing lines showed erect leaves, similar to BZR1-depleted lines, which indicates the opposite roles of LIC and BZR1 in regulating leaf bending
- LIC directly regulated target genes such as INCREASED LEAF INCLINATION 1 (ILI1) to oppose the action of BZR1
- Thus, LIC regulates rice leaf bending as an antagonistic transcription factor of BZR1
- Dynamics of brassinosteroid response modulated by negative regulator LIC in rice
- The phenotypes of lic-1 and LIC-overexpressing lines in erect leaves contribute to ideal plant architecture
- OsRELA Regulates Leaf Inclination by Repressing the Transcriptional Activity of OsLIC in Rice
- Therefore, our results suggest that OsRELA can act as a transcriptional regulator and is involved in the regulation of leaf inclination by regulating the transcriptional activity of OsLIC
- OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak.
- Rice OsLIC encoding a CCCH zinc finger transcription factor plays an important role in immunity
- Genetic assays confirmed that the osilc knockout mutants and OsWRKY30-overexpressing plants exhibited enhanced resistance to Xoo and Xoc, knocking out OsWRKY30 in the oslic mutants attenuated the resistance against bacterial pathogens
- OsMAPK6 physically interacted with and phosphorylated OsLIC leading to decreased OsLIC DNA-binding activity, therefore, overexpression of OsLIC partially suppressed OsMAPK6-mediated rice resistance
- Collectively, these results reveal that OsMAPK6-mediated phosphorylation of OsLIC positively regulates rice resistance to Xoo and Xoc by modulating OsWRKY30 transcription, suggesting that OsMAPK6-OsLIC-OsWRKY30 module is an immune signaling pathway in response to the bacterial pathogens
- Connection
- ILI1, LIC~OsLIC1~OsLIC~OsFLA6, Dynamics of brassinosteroid response modulated by negative regulator LIC in rice, LIC directly regulated target genes such as INCREASED LEAF INCLINATION 1 (ILI1) to oppose the action of BZR1
- ILI1, LIC~OsLIC1~OsLIC~OsFLA6, Dynamics of brassinosteroid response modulated by negative regulator LIC in rice, Repression of LIC in ILI1 transcription in protoplasts was partially rescued by BZR1
- LIC~OsLIC1~OsLIC~OsFLA6, OsBZR1~BZR1, Dynamics of brassinosteroid response modulated by negative regulator LIC in rice, Here, we demonstrate that Oryza sativa LEAF and TILLER ANGLE INCREASED CONTROLLER (LIC) acts as an antagonistic transcription factor of BRASSINAZOLE-RESISTANT 1 (BZR1) to attenuate the BR signaling pathway
- LIC~OsLIC1~OsLIC~OsFLA6, OsBZR1~BZR1, Dynamics of brassinosteroid response modulated by negative regulator LIC in rice, The gain-of-function mutant lic-1 and LIC-overexpressing lines showed erect leaves, similar to BZR1-depleted lines, which indicates the opposite roles of LIC and BZR1 in regulating leaf bending
- LIC~OsLIC1~OsLIC~OsFLA6, OsBZR1~BZR1, Dynamics of brassinosteroid response modulated by negative regulator LIC in rice, For negative feedback, LIC bound to the core element CTCGC in the BZR1 promoter on gel-shift and chromatin immunoprecipitation assay and repressed its transcription on transient transformation assay
- LIC~OsLIC1~OsLIC~OsFLA6, OsBZR1~BZR1, Dynamics of brassinosteroid response modulated by negative regulator LIC in rice, LIC directly regulated target genes such as INCREASED LEAF INCLINATION 1 (ILI1) to oppose the action of BZR1
- LIC~OsLIC1~OsLIC~OsFLA6, OsBZR1~BZR1, Dynamics of brassinosteroid response modulated by negative regulator LIC in rice, Repression of LIC in ILI1 transcription in protoplasts was partially rescued by BZR1
- LIC~OsLIC1~OsLIC~OsFLA6, OsBZR1~BZR1, Dynamics of brassinosteroid response modulated by negative regulator LIC in rice, Phenotypic analysis of the crossed lines depleted in both LIC and BZR1 suggested that BZR1 functionally depends on LIC
- LIC~OsLIC1~OsLIC~OsFLA6, OsBZR1~BZR1, Dynamics of brassinosteroid response modulated by negative regulator LIC in rice, Molecular and physiology assays revealed that LIC plays a dominant role at high BR levels, whereas BZR1 is dominant at low levels
- LIC~OsLIC1~OsLIC~OsFLA6, OsBZR1~BZR1, Dynamics of brassinosteroid response modulated by negative regulator LIC in rice, Thus, LIC regulates rice leaf bending as an antagonistic transcription factor of BZR1
- LIC~OsLIC1~OsLIC~OsFLA6, SRS3~OsKINESIN-13A~BHS1, The kinesin-13 protein BR HYPERSENSITIVE 1 is a negative brassinosteroid signaling component regulating rice growth and development., Furthermore, we found that the BR-induced degradation of BHS1 was attenuated in Osbri1 and Osbak1 mutants, but not in Osbzr1 and Oslic mutants
- LIC~OsLIC1~OsLIC~OsFLA6, OsWRKY30, OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak., OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak.
- LIC~OsLIC1~OsLIC~OsFLA6, OsWRKY30, OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak., Biochemical assays showed that OsLIC bound to OsWRKY30 promoter and suppressed its transcription
- LIC~OsLIC1~OsLIC~OsFLA6, OsWRKY30, OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak., Genetic assays confirmed that the osilc knockout mutants and OsWRKY30-overexpressing plants exhibited enhanced resistance to Xoo and Xoc, knocking out OsWRKY30 in the oslic mutants attenuated the resistance against bacterial pathogens
- LIC~OsLIC1~OsLIC~OsFLA6, OsWRKY30, OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak., In addition, both OsMAPK6-phosphorylated activation of OsLIC and phosphorylation-mimic OsLIC(5D) had reduced DNA-binding activity towards OsWRKY30 promoter, thereby promoting OsWRKY30 transcription
- LIC~OsLIC1~OsLIC~OsFLA6, OsWRKY30, OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak., Collectively, these results reveal that OsMAPK6-mediated phosphorylation of OsLIC positively regulates rice resistance to Xoo and Xoc by modulating OsWRKY30 transcription, suggesting that OsMAPK6-OsLIC-OsWRKY30 module is an immune signaling pathway in response to the bacterial pathogens
- LIC~OsLIC1~OsLIC~OsFLA6, OsMPK1~OsMAPK6~OsSIPK, OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak., OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak.
- LIC~OsLIC1~OsLIC~OsFLA6, OsMPK1~OsMAPK6~OsSIPK, OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak., Here, we show that OsLIC, as a substrate for OsMAPK6, negatively regulates resistance to Xanthomonas oryzae pv
- LIC~OsLIC1~OsLIC~OsFLA6, OsMPK1~OsMAPK6~OsSIPK, OsMAPK6 phosphorylates a zinc finger protein OsLIC to promote downstream OsWRKY30 for rice resistance to bacterial blight and leaf streak., OsMAPK6 physically interacted with and phosphorylated OsLIC leading to decreased OsLIC DNA-binding activity, therefore, overexpression of OsLIC partially suppressed OsMAPK6-mediated rice resistance
- FLA, LIC~OsLIC1~OsLIC~OsFLA6, An Analysis of Natural Variation Reveals That OsFLA2 Controls Flag Leaf Angle in Rice Oryza sativa L.., We identified two causal gene loci for FLA, namely, OsFLA6 and OsFLA2; OsFLA6 was co-localized with the gene OsLIC
- FLA, LIC~OsLIC1~OsLIC~OsFLA6, An Analysis of Natural Variation Reveals That OsFLA2 Controls Flag Leaf Angle in Rice Oryza sativa L.., In addition, the accessions with large and small FLA values have corresponding high and low OsFLA6 expressions
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