水稻种子快速萌发突变体rgs1的鉴定及调控基因克隆

doi:10.3724/SP.J.1006.2023.22056

Abstract

Abstract:

Rice seed absorbed water and germinated rapidly in the paddy field, which could reduce the probability of damage from the pest and germs by shortening the stay time in soil, and thus enhancing seed surviving rate and facilitating the formation of strong seedlings. To exploer the molecular mechanism of seed germination, a mutant rgs1 (exhibiting rapid seed germination, dwarfism, and multi-tillers etc) was identified by screening the EMS (ethyl methanesulfonate) induced library of Jinhui 10 (WT). The dwarfism of rgs1 originated from the shortened internodes and the characteristic of multi-tiller was caused by the rapid growth of tiller buds. Genetic analysis showed that the mutational traits of rgs1 was controlled by a single recessive nuclear gene. LOC_Os12g21710, encoding a chloroplast ζ-carotene isomerase in the mapping region, had a base substitution (G in rgs1 and A in wild type) in the third exon, resulting in the earlier termination of protein translation, which was regarded as the candidate gene of RGS1. The qRT-PCR analysis showed that, compared with WT, the relative expression levels of HTD1, D27, and D10 controlling strigolactone (SLs) synthesis and of D14 and TB1 regulating SLs signal transduction decreased significantly and the relative expression level of D53 acting as a repressor of SLs signaling increased significantly, suggesting that the mutational characteristics of rgs1 were related with the SLs pathway. The transcriptional level of OsNCED1, encoding a key enzyme of abscisic acid (ABA) synthesis, was almost absent in rgs1, while the relative expression levels of MOC3 and FON1 were significantly enhanced, indicating that the rapid seed germination of rgs1 was associated with the defect of ABA synthesis. Therefore, we predicted that RGS1 should be a key gene regulating the cooperation of SL and ABA pathway, thus regulating seed germination, plant height, and tiller number in rice.

Key words: rice (Oryza sativa L.), tillering dwarf, seed germination, chloroplast ζ-carotene isomerase (T20/MIT1), abscisic acid (ABA)

JIA Lu-Qi, SUN You, TIAN Ran, ZHANG Xue-Fei, DAI Yong-Dong, CUI Zhi-Bo, LI Yang-Yang, FENG Xin-Yu, SANG Xian-Chun, and WANG Xiao-Wen. Identification of the rgs1 mutant with rapid germination of seed and isolation of the regulated gene in rice[J].Acta Agronomica Sinica, 2023, 49(8): 2288-2295.

Figures/Tables 5

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引物名称 Primer name	正向引物 Forward primer (5°-3°)	反向引物 Reverse primer (5°-3°)
In12-1	GCTATGTCAAACACGGTCTTATT	CTGGTGTATCCAACGCTTGT
In12-2	AGAGAGAGGAGAGGCTAGAG	AAGTAGTTTGATTCTTTCATCCC
ACTIN	GACCCAGATCATGTTTGAGACCT	CAGTGTGGCTGACACCATCAC
HTD1	TCAAGCTGCTCCTACCAGTGGTT	TGGTTGGCGTAGCTTGGGTTT
D27	GATGGCTACGAGAGCCTGATAGAT	AGATTCCATAACCTCACACGGC
D10	CGTTCGTGACGTTCCACTTCATC	TGTTGGCGTTGTGCTCGCA
D14	TTCTTGAACGACAGCGACTACCAC	TTGAAGAGGGTGCGGCTGAA
D53	AAACGGTCACCTCTTGCTGCA	TGTCATTCCTGTTAGGACCACGG
D3	TCAACCCACGGTTCAGCGATT	TCCAGCACATTGTGCTGGAGAT
TB1	ATGGACATACCGCTTTACCAACAG	GGTGGTAGTAGAAGAAGGTGGAATG
MOC3	GATCAAGATCCTGCGGGAGCTGTAC	GAGGCGCTTCTTCTGGCGCTC
FON1	TGCGTGAAGGAGGACAACATCATC	AGCAGCAGGTTCGTCTCCCTGTT

Identification of the rgs1 mutant with rapid germination of seed and isolation of the regulated gene in rice

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