Calcium and protein kinase serve as the common mediators to regulate plant responses to multiple stresses including salt and ABA stimulus. Here we reported a novel protein kinase (CIPK14) that regulated the responses ...Calcium and protein kinase serve as the common mediators to regulate plant responses to multiple stresses including salt and ABA stimulus. Here we reported a novel protein kinase (CIPK14) that regulated the responses to ABA treatment and salt stress in Arabidopsis. CIPK14 transcripts, capable been checked in roots, stems, leaves and flowers, were highly expressed in flowers and roots. CIPK14 was induced by ABA and salt treatments. The disruption of CIPK14 altered the transcriptional pattern of a gene marker line related to ABA and salt responses, and the results suggested that CIPK14 probably was responsible to the control of the salt and ABA responses. Comparing with wild types, the lines inserted with the T-DNA in which CIPK14 gene expression was knocked out were also more sensitive to ABA and salt stimulus, showing low germination rate and the less root elongation. While, when these conditioned seeds were treated with norflurazon, their germination percentages could recover to a certain extent. We also found that exogenous calcium could have an effect on the transcription of CIPK14 under ABA and salt treatments, and it seemed that calcium ion might work upstream CIPK14 to regulate the plant response to ABA and salt response.展开更多
In this study, we show that CIPK14,a stress responsive CBL-interacting protein kinase gene,is involved in phytochrome A-mediated far-red light inhibition of greening in Arabidopsis seedlings. The CIPK14-impairment mut...In this study, we show that CIPK14,a stress responsive CBL-interacting protein kinase gene,is involved in phytochrome A-mediated far-red light inhibition of greening in Arabidopsis seedlings. The CIPK14-impairment mutant cipk14 grown in continuous far-red (FR) light did not show greening when exposed to white light illumination for 15 h. By contrast, the FR-grown phytochrome A null mutant phyA greened within 0.5 h of exposure to white light. Although greening of Col-4 (wild-type) was not completely abolished by FR, it exhibited a significantly decreased greening capacity compared with that of phyA. Further analyses demonstrated that the expression of protochlorophyllide reductase (POR) genes was correlated with the greening ability of the genotypes. In addition, CIPK14 appeared to be regulated by both the circadian clock and PhyA. Taken together, these results suggest that CIPK14 plays a role in PhyA-mediated FR inhibition of seedling greening, and that a Ca-related kinase may be involved in a previously undefined branch point in the phytochrome A signaling pathway.展开更多
Plastid-to-nucleus retrograde signaling is critical for normal growth and development in plants. The dualfunction and dual-located ssDNA binding protein WHIRLY1 (WHY1) has been proposed to coordinate the retrograde ...Plastid-to-nucleus retrograde signaling is critical for normal growth and development in plants. The dualfunction and dual-located ssDNA binding protein WHIRLY1 (WHY1) has been proposed to coordinate the retrograde signaling from plastids to the nucleus. However, the regulatory mechanism governing the functional switch of WHY1 for mediating plastid-to-nucleus retrograde signaling remains unknown. Here, we report that the Calcineurin B-Like-Interacting Protein Kinase14 (CIPK14) interacts with and phosphorylates WHY1 in Arabidopsis. Phosphorylation of WHY1 results in increased accumulation in the nucleus and enhanced binding with the promoter of WRKY53, which encodes a key transcription factor regulating leaf senescence in Arabidopsis. Transgenic plants overexpressing CIPK14 showed an increased nuclear isoform but decreased plastid isoform of WHY1, among which 95% of transgenic lines showed the stay-green phenotype and 5% of lines showed the variegated pale-green phenotype. Interestingly, the phenotypes of both types of transgenic plants could be recovered by overexpression of plastid-form WHY1. In contrast, knockdown of ClPK14 caused early senescence and even seedling-lethal phenotypes along with elevated expression of senescence-related genes such as WRKY53, SAG12, and NDHF but decreased expression of MER11, RAD50, and POR genes, which could be rescued by overexpression of CIPK14 but not by overexpressing plastid-form or nuclear-form WHY1; the stay-green plants overexpressing ClPK14 showed reduced expression of WRKY53, SAG12, NDHF, and large plastid rRNA. Consistently, the accu- mulation of nuclear-form WHY1 was significantly reduced in the CIPK14 knockdown lines, resulting in a low ratio of nuclear-/plastid-form WHY1. Taken together, our results demonstrate that CIPK14 regu- lates the phosphorylation and organeUar distributions of WHY1 and pinpoint that ClPK14 may function as a cellular switch between leaf senescence and plastid development for coordinating the intercellular signaling in Arabidopsis.展开更多
基金the "985" Program (China) for the higher education enhancement fund to Hunan University, Hunan Natural Science Foundation (Grant No. 05JJ30038)National Natural Science Foundation of China (Grant No. 30600368)
文摘Calcium and protein kinase serve as the common mediators to regulate plant responses to multiple stresses including salt and ABA stimulus. Here we reported a novel protein kinase (CIPK14) that regulated the responses to ABA treatment and salt stress in Arabidopsis. CIPK14 transcripts, capable been checked in roots, stems, leaves and flowers, were highly expressed in flowers and roots. CIPK14 was induced by ABA and salt treatments. The disruption of CIPK14 altered the transcriptional pattern of a gene marker line related to ABA and salt responses, and the results suggested that CIPK14 probably was responsible to the control of the salt and ABA responses. Comparing with wild types, the lines inserted with the T-DNA in which CIPK14 gene expression was knocked out were also more sensitive to ABA and salt stimulus, showing low germination rate and the less root elongation. While, when these conditioned seeds were treated with norflurazon, their germination percentages could recover to a certain extent. We also found that exogenous calcium could have an effect on the transcription of CIPK14 under ABA and salt treatments, and it seemed that calcium ion might work upstream CIPK14 to regulate the plant response to ABA and salt response.
基金supported by Project 985 of China via a higher education enhancement fund awarded to Hunan Universitythe National Project of Scientific and Technical Supporting Programs funded by Ministry of Science and Technology of China (Grant No.2007BAD41B)
文摘In this study, we show that CIPK14,a stress responsive CBL-interacting protein kinase gene,is involved in phytochrome A-mediated far-red light inhibition of greening in Arabidopsis seedlings. The CIPK14-impairment mutant cipk14 grown in continuous far-red (FR) light did not show greening when exposed to white light illumination for 15 h. By contrast, the FR-grown phytochrome A null mutant phyA greened within 0.5 h of exposure to white light. Although greening of Col-4 (wild-type) was not completely abolished by FR, it exhibited a significantly decreased greening capacity compared with that of phyA. Further analyses demonstrated that the expression of protochlorophyllide reductase (POR) genes was correlated with the greening ability of the genotypes. In addition, CIPK14 appeared to be regulated by both the circadian clock and PhyA. Taken together, these results suggest that CIPK14 plays a role in PhyA-mediated FR inhibition of seedling greening, and that a Ca-related kinase may be involved in a previously undefined branch point in the phytochrome A signaling pathway.
文摘Plastid-to-nucleus retrograde signaling is critical for normal growth and development in plants. The dualfunction and dual-located ssDNA binding protein WHIRLY1 (WHY1) has been proposed to coordinate the retrograde signaling from plastids to the nucleus. However, the regulatory mechanism governing the functional switch of WHY1 for mediating plastid-to-nucleus retrograde signaling remains unknown. Here, we report that the Calcineurin B-Like-Interacting Protein Kinase14 (CIPK14) interacts with and phosphorylates WHY1 in Arabidopsis. Phosphorylation of WHY1 results in increased accumulation in the nucleus and enhanced binding with the promoter of WRKY53, which encodes a key transcription factor regulating leaf senescence in Arabidopsis. Transgenic plants overexpressing CIPK14 showed an increased nuclear isoform but decreased plastid isoform of WHY1, among which 95% of transgenic lines showed the stay-green phenotype and 5% of lines showed the variegated pale-green phenotype. Interestingly, the phenotypes of both types of transgenic plants could be recovered by overexpression of plastid-form WHY1. In contrast, knockdown of ClPK14 caused early senescence and even seedling-lethal phenotypes along with elevated expression of senescence-related genes such as WRKY53, SAG12, and NDHF but decreased expression of MER11, RAD50, and POR genes, which could be rescued by overexpression of CIPK14 but not by overexpressing plastid-form or nuclear-form WHY1; the stay-green plants overexpressing ClPK14 showed reduced expression of WRKY53, SAG12, NDHF, and large plastid rRNA. Consistently, the accu- mulation of nuclear-form WHY1 was significantly reduced in the CIPK14 knockdown lines, resulting in a low ratio of nuclear-/plastid-form WHY1. Taken together, our results demonstrate that CIPK14 regu- lates the phosphorylation and organeUar distributions of WHY1 and pinpoint that ClPK14 may function as a cellular switch between leaf senescence and plastid development for coordinating the intercellular signaling in Arabidopsis.
