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SHORT‐ROOT 1 is critical to cell division and tracheary element development in rice roots
Author(s) -
Xing Yadi,
Wang Nan,
Zhang Tianquan,
Zhang Qiuli,
Du Dan,
Chen Xinlong,
Lu Xin,
Zhang Yingying,
Zhu Maodi,
Liu Mingming,
Sang Xianchun,
Li Yunfeng,
Ling Yinghua,
He Guanghua
Publication year - 2021
Publication title -
the plant journal
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.058
H-Index - 269
eISSN - 1365-313X
pISSN - 0960-7412
DOI - 10.1111/tpj.15095
Subject(s) - meristem , biology , microbiology and biotechnology , xylem , lateral root , cell division , root cap , root hair , botany , mutant , exocyst , arabidopsis , gene , genetics , cell , protein subunit , shoot
Summary The exocyst is a key factor in vesicle transport and is involved in cell secretion, cell growth, cell division and other cytological processes in eukaryotes. EXO70 is the key exocyst subunit. We obtained a gene, SHORT‐ROOT 1 ( SR1 ), through map‐based cloning and genetic complementation. SR1 is a conserved protein with an EXO70 domain in plants. SR1 mutation affected the whole root‐development process: producing shorter radicles, adventitious roots and lateral roots, and demonstrating abnormal xylem development, resulting in dwarfing and reduced water potential and moisture content. SR1 was largely expressed in the roots, but only in developing root meristems and tracheary elements. The shortness of the sr1 mutant roots was caused by the presence of fewer meristem cells. The in situ histone H4 expression patterns confirmed that cell proliferation during root development was impaired. Tracheary element dysplasia was caused by marked decreases in the inner diameters of and distances between the perforations of adjacent tracheary elements. The membrane transport of sr1 mutants was blocked, affecting cell division in the root apical region and the development of root tracheary elements. The study of SR1 will deepen our understanding of the function of EXO70 genes in Oryza sativa (rice) and guide future studies on the molecular mechanisms involved in plant root development.