Wang Xian-Ping, Chu Jing-Hua, Zhang Xiang-Qi
State Key Laboratory of Plant Cell and Chromosome Engineering, Institute of Genetics and Developmental Biology, Chinese Academy of Sciences, Beijing 100101, China.
Yi Chuan Xue Bao. 2003 Jul;30(7):619-24.
The Triticum aestivum-Leymus mollis and T. aestivum-Thinopyrum intermedium translocation lines were induced by gametocidal chromosome 3C derived from Aegilops triuncialis and gamma-ray irradiated pollens of a T. aestivum-Th. intermedium addition line TAI-14 with a lower dosage (10Gy), respectively. By genomic in situ hybridization (GISH) analysis, three T. aestivum-L. mollis translocation lines (WM-10, WM-43 and WM-47) and three deletion lines (WM-18, WM-43 and WM-44) were selected from 59 F2 plants derived from a cross combination of T. aestivum-L. mollis substitution line M8724-8-13 x T. aestivum-Ae. triunicalis 3C chromosome addition line. The frequency of translocation lines produced and total frequency of chromosome structural variation occurred were 5.08% and 8.47%, respectively. Two of the three translocation lines, WM-10 and WM-43 all were heterozygous translocation lines carrying one T. aestivum-L. mollis Robertsonian translocation chromosome, but the translocation chromosome in the two lines were different in morphology. The other one, WM-47 was a double heterozygous translocation with two different translocation chromosomes. By the C-banding, one of the three translocation lines was identified, the translocation chromosome consisted of 7DL of wheat and a chromosome arm of L. mollis. In addition, wheat chromosome deletions were observed in some plants. In another cross combination involved in common wheat and T. aestivum-Th. intermedium addition line, two alien terminal non-Robertsonian translocation lines (WI-21 and WI-68) were identified from 69 F2 plants by C-banding and GISH, and the percentage of translocation line was 2.90%. By C-banding analysis, the translocation chromosomes involved in wheat chromosomes 3A and 4A in the two lines, respectively. These results indicate that inducing wheat alien translocation line by gametocidal chromosome and irradiated pollens all are efficient methods.
通过源自节节麦的杀配子染色体3C和较低剂量(10Gy)的γ射线辐照的普通小麦-中间偃麦草附加系TAI-14的花粉,分别诱导出普通小麦-软粒赖草和普通小麦-中间偃麦草易位系。通过基因组原位杂交(GISH)分析,从普通小麦-软粒赖草代换系M8724-8-13×普通小麦-节节麦3C染色体附加系的杂交组合产生的59株F2植株中,筛选出3个普通小麦-软粒赖草易位系(WM-10、WM-43和WM-47)和3个缺失系(WM-18、WM-43和WM-44)。产生易位系的频率和发生染色体结构变异的总频率分别为5.08%和8.47%。3个易位系中的2个,WM-10和WM-43均为携带1条普通小麦-软粒赖草罗伯逊易位染色体的杂合易位系,但这两个系中的易位染色体在形态上不同。另一个,WM-47是具有两条不同易位染色体的双杂合易位系。通过C-分带,鉴定出3个易位系中的1个,其易位染色体由小麦的7DL和软粒赖草的一个染色体臂组成。此外,在一些植株中观察到小麦染色体缺失。在另一个涉及普通小麦和普通小麦-中间偃麦草附加系的杂交组合中,通过C-分带和GISH从69株F2植株中鉴定出2个外源末端非罗伯逊易位系(WI-21和WI-68),易位系的比例为2.90%。通过C-分带分析,这两个系中的易位染色体分别涉及小麦染色体3A和4A。这些结果表明,利用杀配子染色体和辐照花粉诱导小麦外源易位系都是有效的方法。
