Your search keyword '"Ma, Ligeng"' showing total 4 results

1. A transceptor–channel complex couples nitrate sensing to calcium signaling in Arabidopsis.

Author

Wang, Xiaohan, Feng, Changxin, Tian, LiLi, Hou, Congcong, Tian, Wang, Hu, Bin, Zhang, Qian, Ren, Zhijie, Niu, Qi, Song, Jiali, Kong, Dongdong, Liu, Liangyu, He, Yikun, Ma, Ligeng, Chu, Chengcai, Luan, Sheng, and Li, Legong

Abstract

Nitrate-induced Ca2+ signaling is crucial for the primary nitrate response in plants. However, the molecular mechanism underlying the generation of the nitrate-specific calcium signature remains unknown. We report here that a cyclic nucleotide-gated channel (CNGC) protein, CNGC15, and the nitrate transceptor (NRT1.1) constitute a molecular switch that controls calcium influx depending on nitrate levels. The expression of CNGC15 is induced by nitrate, and its protein is localized at the plasma membrane after establishment of young seedlings. We found that disruption of CNGC15 results in the loss of the nitrate-induced Ca2+ signature (primary nitrate response) and retards root growth, reminiscent of the phenotype observed in the nrt1. 1 mutant. We further showed that CNGC15 is an active Ca2+-permeable channel that physically interacts with the NRT1.1 protein in the plasma membrane. Importantly, we discovered that CNGC15–NRT1.1 interaction silences the channel activity of the heterocomplex, which dissociates upon a rise in nitrate levels, leading to reactivation of the CNGC15 channel. The dynamic interactions between CNGC15 and NRT1.1 therefore control the channel activity and Ca2+ influx in a nitrate-dependent manner. Our study reveals a new nutrient-sensing mechanism that utilizes a nutrient transceptor–channel complex assembly to couple nutrient status to a specific Ca2+ signature. In this study, authors demonstrate that CNGC15 interacts with the nitrate transceptor NRT1.1 to constitute a molecular switch that either closes or opens the calcium influx channel (CNGC15) upon the formation or dissociation of the NRT1.1–CNGC15 complex. This leads to generation of a nitrate-specific calcium signature that is evoked upon a rise in nitrate levels. Thus, this study reveals a new nutrient-sensing mechanism that utilizes a nutrient transceptor–channel complex assembly to couple nutrient status to a specific Ca2+ signature. [ABSTRACT FROM AUTHOR]

Published

2021

2. The SNW Domain of SKIP Is Required for Its Integration into the Spliceosome and Its Interaction with the Paf1 Complex in Arabidopsis.

Author

Li, Yan, Xia, Congcong, Feng, Jinlin, Yang, Dong, Wu, Fangming, Cao, Ying, Li, Legong, and Ma, Ligeng

Subjects

SPLICEOSOMES, CELL communication, ARABIDOPSIS

Abstract

SKIP is a conserved protein from yeasts to plants and humans. In plant cells, SKIP is a bifunctional regulator that works in the nucleus as a splicing factor by integrating into the spliceosome and as a transcriptional activator by interacting with the Paf1 complex. In this study, we identified two nuclear localization signals in SKIP and confirmed that each is sufficient to target SKIP to the nucleus. The SNW domain of SKIP is required for both its function as a splicing factor by promoting integration into the spliceosome in response to stress, and its function as a transcriptional activator by controlling its interaction with the Paf1 complex to participate in flowering. Truncated proteins that included the SNW domain and the N- or C-terminus of SKIP were still able to carry out the functions of the full-length protein in gene splicing and transcriptional activation in Arabidopsis . In addition, we found that SKIP undergoes 26S proteasome-mediated degradation, and that the C-terminus of SKIP is required to maintain the stability of the protein in plant cells. Together, our findings demonstrate the structural domain organization of SKIP and reveal the core domains and motifs underlying SKIP function in plants. [ABSTRACT FROM AUTHOR]

Published

2016

3. SKIP Interacts with the Paf1 Complex to Regulate Flowering via the Activation of FLC Transcription in Arabidopsis.

Author

Cao, Ying, Wen, Liguo, Wang, Zheng, and Ma, Ligeng

Subjects

ARABIDOPSIS, LOCUS in plant genetics, FLOWERING of plants

Abstract

The article talks about interaction of SKIP with the gene Paf1 Complex which is used for regulating the flowering through the Flowering Locus (FLC activation in Arabidopsis.

Published

2015

4. SKIP Confers Osmotic Tolerance during Salt Stress by Controlling Alternative Gene Splicing in Arabidopsis.

Author

Feng, Jinlin, Li, Jingjing, Gao, Zhaoxu, Lu, Yaru, Yu, Junya, Zheng, Qian, Yan, Shuning, Zhang, Wenjiao, He, Hang, Ma, Ligeng, and Zhu, Zhengge

Subjects

PLANT genetic engineering, ARABIDOPSIS, ABIOTIC stress, MESSENGER RNA, PLANT molecular biology

Abstract

Deciphering the mechanisms underlying plant responses to abiotic stress is key for improving plant stress resistance. Much is known about the regulation of gene expression in response to salt stress at the transcriptional level; however, little is known about this process at the posttranscriptional level. Recently, we demonstrated that SKIP is a component of spliceosome that interacts with clock gene pre-mRNAs and is essential for regulating their alternative splicing and mRNA maturation. In this study, we found that skip-1 plants are hypersensitive to both salt and osmotic stresses, and that SKIP is required for the alternative splicing and mRNA maturation of several salt-tolerance genes, including NHX1 , CBL1 , P5CS1 , RCI2A , and PAT10 . A genome-wide analysis revealed that SKIP mediates the alternative splicing of many genes under salt-stress conditions, and that most of the alternative splicing events in skip-1 involve intron retention and can generate a premature termination codon in the transcribed mRNA. SKIP also controls alternative splicing by modulating the recognition or cleavage of 5′ and 3′ splice donor and acceptor sites under salt-stress conditions. Therefore, this study addresses the fundamental question of how the mRNA splicing machinery in plants contributes to salt-stress responses at the posttranscriptional level, and provides a link between alternative splicing and salt tolerance. [ABSTRACT FROM AUTHOR]

Published

2015