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首页 > 过刊浏览>2025年第26卷第2期 >319-330. DOI:10.19462/j.cnki.1671-895x.2023.01.025
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玉米黄化突变基因Zmet 9的精细定位
作者:
作者单位:

甘肃省农业科学院作物研究所, 兰州 730070

作者简介:

研究方向为玉米遗传育种, E-mail: lys087@163.com

通讯作者:

刘忠祥, 研究方向为玉米遗传育种,E-mail: lzhxiang@sina.com

基金项目:

国家自然科学基金项目(32260473);甘肃省农业科学院生物育种专项(2024GAAS24、2022GAAS04);兰州市科技计划项目(2023-3-43)


Fine Mapping of the Etiolation Mutant Gene Zmet 9 in Maize
Author:
Affiliation:

Crops Research Institute, Gansu Academy of Agricultural Sciences, Lanzhou 730070

Fund Project:

Foundation projects: The Natural Science Foundation of China (32260473);The Biological Breeding Special Project of Gansu Academy of Agricultural Sciences(2024GAAS24, 2022GAAS04);Lanzhou Science and Technology Plan Project (2023-3-43)

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    摘要:

    光合作用是植物生存的基础,叶色突变体往往伴随着叶绿体结构异常、光合色素合成受阻等表型,因此,研究叶色突变体可为光合作用和光形态建成提供实验数据和理论支撑。本研究以2.48 Gy辐照剂量的快中子辐射诱变玉米自交系PH6WC筛选得到的玉米黄化突变体et9为材料,通过表型鉴定、叶片内叶绿素含量测定、叶绿体结构显微观察、光合特性等分析,与野生型PH6WC相比突变体et9株高、穗位高极显著降低,剑叶长、剑叶宽和倒三叶宽极显著减小,抽雄、散粉、吐丝期均比野生型推迟10~12 d;叶绿素a、叶绿素b及总叶绿素含量都显著低于野生型;叶绿体结构松散,类囊体分布混乱,垛堞基粒数量较少;净光合速率、气孔导度、蒸腾速率均极显著低于野生型,胞间二氧化碳浓度极显著高于野生型,叶绿体荧光参数除非光化学淬灭外均极显著低于野生型,遗传模式分析表明其黄化表型受一个核隐性基因所控制,命名为Zmet9。将其与玉米自交系B73杂交构建F2分离群体,通过BSR-seq方法将突变位点初步定位在玉米第9染色体20~22 Mb区间内。进一步在初定位区间内开发4个KASP标记及2个InDel标记,利用约1100个F2突变表型单株进行精细定位,最终将Zmet9精细定位于玉米第9染色体标记KASP19和2040之间约160 kb的区间内。该区间内含有5个候选基因,其中Zm00001d045384编码一个铁超氧化物歧化酶,与拟南芥中的同源基因FSD2、FSD3突变后出现叶色漂白的表型类似,推测Zm00001d045384可能是Zmet9的候选基因。

    Abstract:

    Photosynthesis is the basis for plant survival. Leaf color mutants are often accompanied by abnormal chloroplast structure and blocked photosynthetic pigment synthesis. Therefore, the study of leaf color mutants can provide experimental data and theoretical support for photosynthesis and photomorphogenesis. In this study, maize etiolation mutant et9, which was identified from maize inbred line PH6WC treated by 2.48 Gy fast neutron irradiation, was used as the material. Through phenotypic identification, determination of chlorophyll content in leaves, microscopic observation of chloroplast structure and analysis of photosynthetic characteristics, plant height and panicle height of et9 plants were very significantly lower than those of the wild type. The flag leaf length, flag leaf width and the third leaf width were very significantly reduced in mutant. The tasseling, pollen shedding and silking stages were delayed by 10-12 days compared with the wild type. The contents of chlorophyll a, chlorophyll b and total chlorophyll were obviously lower than those of the wild type. The chloroplast structure is loose, the distribution of thylakoids is chaotic, and the number of basal grains is small. In contrast to the wild type, the net photosynthetic rate, stomatal conductance and transpiration rate decreased significantly, while the intercellular carbon dioxide concentration increased significantly. The chloroplast fluorescence parameters were significantly lower than those of the wild type except for photochemical quenching. Genetic segregation analysis revealed that the yellowing phenotype was controlled by a nuclear recessive gene, named Zmet9. The F2 segregating population was generated by crossing it with maize inbred line B73, and the mutation site was initially located in the 20-22 Mb on chromosome 9 of maize using the BSR-seq method. Four KASP markers and two InDel markers were further developed in the initial mapping interval, and about 1100 plants showing mutant phenotype were used for fine mapping. Finally, Zmet9 was finely mapped to a region of about 160 kb between markers KASP19 and 2040. This interval contains five annotated candidate genes, of which Zm00001d045384 encodes an iron superoxide dismutase. Considering that mutation of its homologous genes FSD2 and FSD3 in Arabidopsis shows leaf color bleaching phenotype, we speculate that Zm00001d045384 may be a candidate gene for Zmet9.

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李永生,王晓娟,连晓荣,等.玉米黄化突变基因Zmet 9的精细定位[J].植物遗传资源学报,2025,26(2):319-330.

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