Department of Field Crops, Faculty of Agriculture, Necmettin Erbakan University, Konya, Türkiye.
Department of Field Crops, Faculty of Agriculture, Ataturk University, Erzurum, Türkiye.
Mol Biol Rep. 2022 Nov;49(11):10165-10174. doi: 10.1007/s11033-022-07896-y. Epub 2022 Aug 27.
Breeding studies are commonly conducted to develop new cultivars with high yield levels and improved quality traits. Chemically-induced mutations are used to create genetic variations in wheat genomes. Various physical and chemical mutagens are used to increase frequency of mutations and facilitate the selection processes. Sodium azide (SA) is largely employed to induce mutations of the genes regulating essential traits. Such mutations may also elucidate gene functions of the mutant phenotypes. Present experiments were conducted to investigate potential use of conventional chemical mutagenesis technique through SA for mature embryo culture in wheat.
Sodium azide mutagenesis was experimented with 4 treatment durations (1, 2, 3 and 4 h) and 5 treatment concentrations (0, 1, 2, 3 and 4 mM). Mature embryos were subjected to experimental treatments to detect optimum doses of mutagenesis and to estimate polymorphism and genomic instability. Primarily, 50% reduction in number of regenerated plants as compared to the control (LD) was adopted as the optimum dose. Based on LD criterion, the optimum value was achieved at 1 h duration of 4 mM SA concentration. Afterwards, inter-primer binding site markers were applied to investigate polymorphism and genomic instability in the regenerated plants.
Present findings revealed that efficiency of chemical mutagenesis could be improved through the use of molecular technology and such mutations may assist plant breeders in developing high-yield cultivars.
培育研究通常用于开发具有高产水平和改良品质特性的新品种。化学诱导突变用于在小麦基因组中创造遗传变异。各种物理和化学诱变剂用于增加突变频率并促进选择过程。叠氮化钠(SA)被广泛用于诱导调节必需性状的基因发生突变。这些突变也可能阐明突变表型的基因功能。本实验旨在研究通过 SA 对小麦成熟胚培养进行常规化学诱变技术的潜在应用。
对 4 种处理时间(1、2、3 和 4 小时)和 5 种处理浓度(0、1、2、3 和 4 mM)进行了 SA 诱变实验。将成熟胚进行实验处理,以检测最佳诱变剂量,并评估多态性和基因组不稳定性。首先,将再生植株数量相对于对照(LD)减少 50%作为最佳剂量。基于 LD 标准,在 4 mM SA 浓度下 1 小时的处理时间达到最佳值。然后,应用引物结合位点标记物来研究再生植株中的多态性和基因组不稳定性。
本研究结果表明,通过使用分子技术可以提高化学诱变的效率,并且这些突变可能有助于植物育种家开发高产品种。
