期刊论文

Yunling Peng

英文

Genes

2073-4425

2023

14

1

31-

10.3390/genes14010031

Conceptualization, S.F.A.G., Y.P. and A.R.; methodology, S.F.A.G., Y.M., A.A. and M.A.; software, S.F.A.G. and A.R.; validation, Y.P. and M.U.H.; formal analysis, S.F.A.G. and S.H.Q.; investigation, Y.P. and N.B.; resources, Y.P. and N.A.T.A.K.; data curation, S.F.A.G., A.A. and A.R.; writing—original draft preparation, S.F.A.G., A.A., M.A., M.M.T. and A.R.; writing—review and editing, S.F.A.G., Y.M., A.A., N.A.T.A.K. and N.B.; visualization, Y.P. and M.U.H.; supervision, Y.P.; project administration, Y.P.; funding acquisition, Y.P. All authors have read and agreed to the published version of the manuscript. This research was supported by the National Key research and development project (2022YFD1201804), Talent Fuxi Project of Gansu Agricultural University, (No. GAUFX-47102Y09), and the Lanzhou Science and Technology Bureau (No. 2020-RC-122).

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Drought stress is a significant abiotic factor influencing maize growth and development. Understanding the molecular mechanism of drought tolerance is critical to develop the drought tolerant genotype. The identification of the stress responsive gene is the first step to developing a drought tolerant genotype. The aim of the current research was to pinpoint the genes that are essential for conserved samples in maize drought tolerance. In the current study, inbred lines of maize, 478 and H21, a drought-tolerant and susceptible line, were cultivated in the field and various treatments were appli...