AUTHOR=Wang Tiankang , Li Yixing , Fu Yuefeng , Xie Hongjun , Song Shufeng , Qiu Mudan , Wen Jiong , Chen Muwen , Chen Ge , Tian Yan , Li Chengxia , Yuan Dingyang , Wang Jianlong , Li Li 

TITLE=Mutation at Different Sites of Metal Transporter Gene OsNramp5 Affects Cd Accumulation and Related Agronomic Traits in Rice (Oryza sativa L.)

JOURNAL=Frontiers in Plant Science

VOLUME=10

YEAR=2019

URL=https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2019.01081

DOI=10.3389/fpls.2019.01081

ISSN=1664-462X

ABSTRACT=<p><italic>OsNramp5</italic> is a key gene involved in the control of the uptake of Cd, Mn, and other metal ions by rice root cells. The functional deficiency of this gene can significantly reduce the accumulation of Cd in rice grains, but the effects of its mutation on agronomic traits such as yield and quality have not been investigated comprehensively yet. In the present study, three Huanghuazhan-based <italic>OsNramp5</italic> mutants [<italic>LCH1</italic> (<italic>Low Cadmium Huanghuazhan 1</italic>), <italic>LCH2</italic> (<italic>Low Cadmium Huanghuazhan 2</italic>), and <italic>LCH3</italic> (<italic>Low Cadmium Huanghuazhan 3</italic>)] were obtained using clustered regularly interspaced short palindromic repeats/CRISPR-associated protein 9 (CRISPR/Cas9) technology. The mutation-type analysis showed that <italic>LCH1</italic>, <italic>LCH2</italic>, and <italic>LCH3</italic> encoded defective OsNramp5 protein sequences containing only 76aa, 176aa, and 266aa, respectively. The determination of metal content and the statistics of related agronomic traits revealed that the functionally deficient <italic>OsNramp5</italic> not only significantly reduced the accumulation of Cd in the grains of the mutants but also affected rice yield and quality. However, with the decrease of <italic>OsNramp5</italic> mutation degree, its effects on chlorenchyma Mn accumulation, yield, and quality were also diminished. Additionally, we also found that the increase in the concentration of Mn in the soil restored the phenotype of the declined yield and quality due to the functional deficiency of <italic>OsNramp5</italic>. Our findings provide novel insights into and new materials for breeding rice varieties with low Cd accumulation and excellent agronomic traits under severe Cd pollution environment.</p>