Your search keyword '"Gao, Hongbo"' showing total 5 results

1. Evolution and Functional Differentiation of the C-terminal Motifs of FtsZs During Plant Evolution.

Author

An, Jinjie, Wang, Lulu, Hong, Conghao, and Gao, Hongbo

Subjects

DIVISION rings, PLANT evolution, SCAFFOLD proteins, RED algae, PROTEIN-protein interactions

Abstract

Filamentous temperature-sensitive Z (FtsZ) is a tubulin-like GTPase that is highly conserved in bacteria and plants. It polymerizes into a ring at the division site of bacteria and chloroplasts and serves as the scaffold protein of the division complex. While a single FtsZ is present in bacteria and cyanobacteria, there are two subfamilies, FtsZ1 and FtsZ2 in the green lineage, and FtsZA and FtsZB in red algae. In Arabidopsis thaliana , the C-terminal motifs of AtFtsZ1 (Z1C) and AtFtsZ2-1 (Z2C) display distinct functions in the regulation of chloroplast division. Z1C exhibits weak membrane-binding activity, whereas Z2C engages in the interaction with the membrane protein AtARC6. Here, we provide evidence revealing the distinct traits of the C-terminal motifs of FtsZ1 and FtsZ2 throughout the plant evolutionary process. In a range of plant species, the C-terminal motifs of FtsZ1 exhibit diverse membrane-binding properties critical for regulating chloroplast division. In chlorophytes, the C-terminal motifs of FtsZ1 and FtsZ2 exhibit both membrane-binding and protein interaction functions, which are similar to those of cyanobacterial FtsZ and red algal FtsZA. During the transition from algae to land plants, the functions of the C-terminal motifs of FtsZ1 and FtsZ2 exhibit differentiation. FtsZ1 lost the function of interacting with ARC6 in land plants, and the membrane-binding activity of FtsZ2 was lost in ferns. Our findings reveal the functional differentiation of the C-terminal motifs of FtsZs during plant evolution, which is critical for chloroplast division. [ABSTRACT FROM AUTHOR]

Published

2024

2. PDV2 has a dosage effect on chloroplast division in Arabidopsis

Author

Chang, Ning, Sun, Qingqing, Li, Yiqiong, Mu, Yajuan, Hu, Jinglei, Feng, Yue, Liu, Xiaomin, and Gao, Hongbo

Published

2017

3. Genetic mapping and isolation of two arc3 alleles in Arabidopsis

Author

Pan, Deng, Shi, Yuhong, Liu, Xia, Gao, Yuefang, Liu, Zhonghua, and Gao, Hongbo

Published

2013

4. Evolution of the chloroplast division machinery

Author

Gao, Hongbo and Gao, Fuli

Published

2011

5. Arabidopsis FRS4/ CPD25 and FHY3/ CPD45 work cooperatively to promote the expression of the chloroplast division gene ARC5 and chloroplast division.

Author

Gao, Yuefang, Liu, Han, An, Chuanjing, Shi, Yuhong, Liu, Xia, Yuan, Wanqiong, Zhang, Bing, Yang, Jin, Yu, Caixia, and Gao, Hongbo

Subjects

GUANOSINE triphosphatase, CHLOROPLASTS, ARABIDOPSIS, GENE expression in plants, MUTANT proteins, PHENOTYPES, TRANSCRIPTION factors

Abstract

ARC5 is a dynamin-related GTPase essential for the division of chloroplasts in plants. The arc5 mutant frequently exhibits enlarged, dumbbell-shaped chloroplasts, indicating a role for ARC5 in the constriction of the chloroplast division site. In a screen for chloroplast division mutants with a phenotype similar to arc5, two mutants, cpd25 and cpd45, were obtained. CPD45 was identified as being the same gene as FHY3, a key regulator of far-red light signaling recently shown to be involved in the regulation of ARC5. CPD25 was previously named FRS4 and is homologous to FHY3. We found that CPD25 is also required for the expression of ARC5, suggesting that its function is not redundant to that of FHY3. Moreover, cpd25 does not have the far-red light-sensing defect present in fhy3 and far1. Both FRS4/ CPD25 and FHY3/ CPD45 could bind to the FBS-like ' ACGCGC' motifs in the promoter region of ARC5, and the binding efficiency of FRS4/ CPD25 was much higher than that of FHY3/ CPD45. Unlike FHY3/ CPD45, FRS4/ CPD25 has no ARC5 activation activity. Our data suggest that FRS4/ CPD25 and FHY3/ CPD45 function as a heterodimer that cooperatively activates ARC5, that FRS4/ CPD25 plays the major role in promoter binding, and that FHY3/ CPD45 is largely responsible for the gene activation. This study not only provides insight into the mechanisms underlying the regulation of chloroplast division in higher plants, but also suggests a model that shows how members of a transcription factor family can evolve to have different DNA-binding and gene activation features. [ABSTRACT FROM AUTHOR]

Published

2013