Hypocotyl length is regarded to be a crucial seedling trait,influencing many subsequent plant development processes.However,little is known about this trait in Brassica campestris syn.Brasscia rapa.Here,we performed a...Hypocotyl length is regarded to be a crucial seedling trait,influencing many subsequent plant development processes.However,little is known about this trait in Brassica campestris syn.Brasscia rapa.Here,we performed a comparative observation on the early hypocotyl development between two cultivars,‘SZQ’belonging to pak-choi(B.campestris ssp.chinensis var.communis)with longer hypocotyls,and‘WTC’belonging to Tacai(B.campestris L.ssp.chinensis var.rosularis)with shortter hypocotyls,and found that the difference in auxin biosynthesis might contribute to the varied hypocotyl phenotype between these two cultivars.By applying GWAS analysis using a total of 226 B.campestris accessions,we identified that the AT-Hook motif nuclear localized(AHL)gene BcAHL24-MF1 contributed to the natural variation in hypocotyl length.Functional variation of BcAHL24-MF1 was attributed to four haplotypes featuring four SNPs within the promoter region,of which Hap I accumulated more transcripts with shorter hypocotyls.Constitutive overexpression of BcAHL24-MF1 in B.campestris caused decreased hypocotyl length under light circumstances and even constant darkness,as BcAHL24-MF1 repressed the PIFmediated transcriptional activation of auxin biosynthesis genes BcYUC6-MF2 and BcYUC8-LF.Our research uncovered the important role of BcAHL24-MF1 in regulating light-triggered inhibition of hypocotyl elongation,therefore presenting a valuable genetic target for crop breeding.展开更多
PHOTOPERIODIC CONTROL OF HYPOCOTYL 1(PCH1)and PCH1-LIKE(PCHL)were shown to directly bind to phytochrome B(phyB)and suppress phyB thermal reversion,resulting in plants with dramatically enhanced light sensitivity.Here,...PHOTOPERIODIC CONTROL OF HYPOCOTYL 1(PCH1)and PCH1-LIKE(PCHL)were shown to directly bind to phytochrome B(phyB)and suppress phyB thermal reversion,resulting in plants with dramatically enhanced light sensitivity.Here,we show that PCH1 and PCHL also positively regulate various light responses,including seed germination,hypocotyl gravitropism,and chlorophyll biosynthesis,by physically interacting with PHYTOCHROME INTERACTING FACTOR 1(PIF1)and CONSTITUTIVE PHOTOMORPHO-GENIC 1(COP1).PCH1 and PCHL interact with PIF1 both in the dark and light,and regulate PIF1 abundance.Moreover,PCH1 and PCHL facilitate the physical interaction between phyB and PIF1 in vivo to promote the light-induced degradation of PIF1.PCH1 and PCHL also inhibit the DNA-binding ability of PIF1 to negatively regulate the expressions of PIF1 target genes.In addition,PCH1 and PCHL interact with COP1 and undergo degradation through the 26S proteasome pathway in the dark.Consistently,pch1 suppresses cop1 phenotype in darkness.Collectively,our study reveals a novel mechanism by which PCH1 and PCHL regulate diverse light responses not only by stabilizing phyB Pfrform but also by directly interacting with PIF1 and COP1,providing a molecular understanding of the control of hypocotyl growth by these proteins.展开更多
基金supported by grants from the Key R and D Program of Zhejiang(Grant Nos.2022C02032 and 2022C02030)the SanNong JiuFang Science and Technology Cooperation Project of Zhejiang Province(Grant No.2023SNJF008)+1 种基金the Grand Science and Technology Special Project of Zhejiang Province(Grant No.2021C02065)the Science and Technology Plan Project of Jiaxing(Grant No.2023AZ11002).
文摘Hypocotyl length is regarded to be a crucial seedling trait,influencing many subsequent plant development processes.However,little is known about this trait in Brassica campestris syn.Brasscia rapa.Here,we performed a comparative observation on the early hypocotyl development between two cultivars,‘SZQ’belonging to pak-choi(B.campestris ssp.chinensis var.communis)with longer hypocotyls,and‘WTC’belonging to Tacai(B.campestris L.ssp.chinensis var.rosularis)with shortter hypocotyls,and found that the difference in auxin biosynthesis might contribute to the varied hypocotyl phenotype between these two cultivars.By applying GWAS analysis using a total of 226 B.campestris accessions,we identified that the AT-Hook motif nuclear localized(AHL)gene BcAHL24-MF1 contributed to the natural variation in hypocotyl length.Functional variation of BcAHL24-MF1 was attributed to four haplotypes featuring four SNPs within the promoter region,of which Hap I accumulated more transcripts with shorter hypocotyls.Constitutive overexpression of BcAHL24-MF1 in B.campestris caused decreased hypocotyl length under light circumstances and even constant darkness,as BcAHL24-MF1 repressed the PIFmediated transcriptional activation of auxin biosynthesis genes BcYUC6-MF2 and BcYUC8-LF.Our research uncovered the important role of BcAHL24-MF1 in regulating light-triggered inhibition of hypocotyl elongation,therefore presenting a valuable genetic target for crop breeding.
基金supported by grants from the National Institutes of Health(GM-114297)National Science Foundation(MCB-1543813)to E.H.and by a grant from the German Research Foundation(DFG)to A.H.(HI 1369/7-1)by the DFG under Germany’s Excellence Strategy(CIBSS-EXC-2189-Project ID 390939984).
文摘PHOTOPERIODIC CONTROL OF HYPOCOTYL 1(PCH1)and PCH1-LIKE(PCHL)were shown to directly bind to phytochrome B(phyB)and suppress phyB thermal reversion,resulting in plants with dramatically enhanced light sensitivity.Here,we show that PCH1 and PCHL also positively regulate various light responses,including seed germination,hypocotyl gravitropism,and chlorophyll biosynthesis,by physically interacting with PHYTOCHROME INTERACTING FACTOR 1(PIF1)and CONSTITUTIVE PHOTOMORPHO-GENIC 1(COP1).PCH1 and PCHL interact with PIF1 both in the dark and light,and regulate PIF1 abundance.Moreover,PCH1 and PCHL facilitate the physical interaction between phyB and PIF1 in vivo to promote the light-induced degradation of PIF1.PCH1 and PCHL also inhibit the DNA-binding ability of PIF1 to negatively regulate the expressions of PIF1 target genes.In addition,PCH1 and PCHL interact with COP1 and undergo degradation through the 26S proteasome pathway in the dark.Consistently,pch1 suppresses cop1 phenotype in darkness.Collectively,our study reveals a novel mechanism by which PCH1 and PCHL regulate diverse light responses not only by stabilizing phyB Pfrform but also by directly interacting with PIF1 and COP1,providing a molecular understanding of the control of hypocotyl growth by these proteins.
