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简单序列重复区间(ISSR)分子标记和解剖结构有助于快速、定向筛选唇形科药用和观赏植物的耐冷幼苗突变体。

ISSR molecular markers and anatomical structures can assist in rapid and directional screening of cold-tolerant seedling mutants of medicinal and ornamental plant in L.

作者信息

Li Yirui, Cheng Xu, Lai Junlin, Zhou Yunzhu, Lei Ting, Yang Lijuan, Li Jiani, Yu Xiaofang, Gao Suping

机构信息

College of Landscape Architecture, Sichuan Agricultural University, Chengdu, China.

出版信息

Front Plant Sci. 2023 Jul 3;14:1149669. doi: 10.3389/fpls.2023.1149669. eCollection 2023.

DOI:10.3389/fpls.2023.1149669
PMID:37465387
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10350533/
Abstract

L. is a perennial herb with ornamental and anticancer medicinal functions widely distributed in the tropics. It is affected by temperature and cannot bloom normally in colder subtropical regions, which seriously affects its ornamental value. To create low-temperature resistance mutants and enrich new germplasm resources, this study used tissue culture and chemical reagent (0.5 mmol/L NaN) and low-temperature stress (0°C, full darkness for 48h) induction to target and screen for cold-resistance mutants. The results showed that the ISSR band polymorphism ratio of the 24 suspected mutant materials was 87.5%. The DNA profiles of the 9 mutants initially identified were altered. The content of plumbagin in the stems and leaves of the mutants was examined, and it was found that the accumulation in the leaves of the mutant SA24 could be as high as 3.84 times that of the control, which was 0.5991%. There were significant differences in the anatomical structures of roots, stems and leaves. The mutants mostly exhibited reduced root diameter (only 0.17-0.69 times that of CK), increased stem diameter (up to 2.19 times that of CK), enlarged mesophyll cells, increased thickness (up to 1.83 times that of CK) and high specificity, which are thought to be important for the different cold resistance obtained by the mutants. In the cold resistance experiment, four cold-tolerant mutants were successfully screened according to their morphological characteristics and physiological indexes, and the mutagenesis efficiency could be as high as 2.22% and did not affect the accumulation of plumbagin in their stems and leaves, even higher than CK. The responses of the screened mutants SA15, SA19, SA23 and SA24 to low temperature showed slower leaf wilting, higher light energy conversion efficiency, less accumulation of MDA content, increased enzymatic activities of antioxidant enzymes (SOD, CAT, POD) and more accumulation of soluble sugars and proline content. These characteristics are consistent with the response of cold-resistance plants to low temperatures. The cold- resistance mutants cultivated in soil were observed of agronomic and ornamental traits for one year, mainly manifested as delayed flowering and delayed entry into the senescence stage. This study provides a more rapid and accurate technique for identifying and screening cold-tolerant mutants, and lays the foundation for future experiments on the creation of new cold-resistant varieties.

摘要

L.是一种多年生草本植物,具有观赏和抗癌药用功能,广泛分布于热带地区。它受温度影响,在较寒冷的亚热带地区不能正常开花,这严重影响了其观赏价值。为了创造耐低温突变体并丰富新的种质资源,本研究采用组织培养、化学试剂(0.5 mmol/L NaN)和低温胁迫(0°C,完全黑暗48小时)诱导来靶向筛选抗寒突变体。结果表明,24份疑似突变材料的ISSR条带多态性比率为87.5%。初步鉴定出的9个突变体的DNA图谱发生了改变。检测了突变体茎和叶中萘醌的含量,发现突变体SA24叶片中的积累量可达对照的3.84倍,即0.5991%。根、茎和叶的解剖结构存在显著差异。突变体大多表现为根直径减小(仅为对照的0.17 - 0.69倍)、茎直径增加(高达对照的2.19倍)、叶肉细胞增大、厚度增加(高达对照的1.83倍)且具有高度特异性,这些被认为对突变体获得不同的抗寒性很重要。在抗寒实验中,根据形态特征和生理指标成功筛选出4个耐寒突变体,诱变效率高达2.22%,且不影响其茎和叶中萘醌的积累,甚至高于对照。筛选出的突变体SA15、SA19、SA23和SA24对低温的响应表现为叶片萎蔫较慢、光能转换效率较高、MDA含量积累较少、抗氧化酶(SOD、CAT、POD)的酶活性增加以及可溶性糖和脯氨酸含量积累较多。这些特征与抗寒植物对低温的响应一致。对在土壤中培育的抗寒突变体进行了一年的农艺和观赏性状观察,主要表现为开花延迟和进入衰老阶段延迟。本研究为鉴定和筛选耐寒突变体提供了一种更快速、准确的技术,并为未来创造新的抗寒品种的实验奠定了基础。

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