生物技术通报 ›› 2026, Vol. 42 ›› Issue (6): 77-86.doi: 10.13560/j.cnki.biotech.bull.1985.2026-0247

• 薯类生物技术专题 • 上一篇    下一篇

流式细胞术的优化及其在甘薯倍性鉴定中的应用

李建功(), 邓逸桐, 赵路宽, 王珧, 曹清河()   

  1. 中国农业科学院甘薯研究中心 江苏徐淮地区徐州农业科学研究所,徐州 221131
  • 收稿日期:2026-03-01 出版日期:2026-06-26 发布日期:2026-07-11
  • 通讯作者: 曹清河,男,研究员,研究方向:甘薯种质资源鉴定与新种质创制;E-mail: caoqinghe@jaas.ac.cn
  • 作者简介:李建功,男,硕士研究生,研究方向:甘薯种质资源鉴定与甘薯分子生物学;E-mail: 15863131721@163.com
  • 基金资助:
    国家重点研发计划(2023YFD1202702);现代农业产业技术体系专项(CARS-10);江苏省种业振兴“揭榜挂帅”项目(JBGS(2021)010)

Optimization of Flow Cytometry and Its Application in Ploidy Identification of Sweetpotato

LI Jian-gong(), DENG Yi-tong, ZHAO Lu-kuan, WANG Yao, CAO Qing-he()   

  1. Sweetpotato Research Center of Chinese Academy of Agriculture Sciences, Xuzhou Institute of Agricultural Sciences in Jiangsu Xuhuai District, Xuzhou 221131
  • Received:2026-03-01 Published:2026-06-26 Online:2026-07-11

摘要:

目的 染色体倍性鉴定是甘薯种质资源评价过程中的重要环节,为了克服传统方法在甘薯取材中的局限性,优化流式细胞术在甘薯倍性鉴定中的应用,建立一种高效的倍性鉴定方法,为后续不同倍性甘薯材料大规模鉴定提供基础。 方法 以‘徐紫薯8号’为试材,系统比较液氮研磨叶片法与刀片切碎根尖法在细胞核悬液制备中的效果,重点评估两种方法在细胞核得率、样品制备耗时及流式检测图谱质量方面的差异;同时,针对珍贵材料取材难的问题,通过调整裂解液中MgSO4‧7H2O、DTT及Triton X-100的浓度,探索利用甘薯成熟展开叶进行倍性鉴定的可行性,并利用不同倍性材料对液氮研磨叶片法进行了单独及混合检测验证。 结果 液氮研磨叶片法在保证检测精度的同时,显著提升制备效率,单个样品在破碎环节和上机检测环节的耗时均明显缩短。在成熟叶鉴定中,将裂解液中DTT和Triton X-100浓度加倍后,有效细胞核释放量显著增加,成功克服成熟叶难以检测的问题。该方法在二倍体、四倍体及六倍体材料的单独及混合检测中均表现出优异的区分度,荧光强度比值与理论倍性比(1∶2∶3)高度吻合,验证了其稳定性和普适性。 结论 基于液氮研磨法改进后的流式细胞术在甘薯倍性鉴定中,不受根尖等取材限制,可以快速、准确检测倍性和筛选材料。

关键词: 甘薯, 流式细胞术, 倍性鉴定, 液氮研磨叶片法

Abstract:

Objective Chromosome ploidy identification is an important step in evaluating sweetpotato germplasm resources. To overcome the limitations of traditional methods in sweetpotato sampling, this study optimized the application of flow cytometry for ploidy identification, established an efficient method, and provided a foundation for subsequent large-scale identification of sweetpotato materials with different ploidy levels. Method Using ‘Xuzishu 8’ as the experimental material, this study systematically compared the effects of the liquid nitrogen-ground leaf method and the blade-chopped root tip method in preparing cell nucleus suspensions. The comparison focused on nucleus yield, sample preparation time, and the quality of flow cytometry profiles. To address the difficulty of sampling precious materials, we explored the feasibility of ploidy identification using fully expanded mature sweetpotato leaves by adjusting the concentrations of MgSO₄·7H₂O, DTT, and Triton X-100 in the lysis buffer. The method was validated by individual and mixed detection of materials with different ploidy levels. Result The liquid nitrogen-ground leaf method significantly improved preparation efficiency while maintaining detection accuracy, and both the crushing step and the on-machine detection time per sample were markedly reduced. For mature leaf identification, doubling the concentrations of DTT and Triton X-100 in the lysis buffer remarkably increased the release of intact nuclei, successfully overcoming the difficulty of detecting mature leaves. This method showed excellent resolution in both individual and mixed detection of diploid, tetraploid, and hexaploid materials, and the observed fluorescence intensity ratio was highly consistent with the theoretical ploidy ratio (1:2:3), confirming its stability and universality. Conclusion For sweetpotato ploidy identification, the flow cytometry method improved by the liquid nitrogen-ground leaf approach is not restricted by sampling limitations such as root tip dependence, and can rapidly and accurately determine the ploidy of sweetpotato materials and facilitate material screening.

Key words: sweetpotato, flow cytometry, ploidy identification, liquid nitrogen-ground leaf method