Research on Improving Wheat Mutagenesis Efficiency by Combining Carbon Ion Beam with Tissue Culture

doi:10.11924/j.issn.1000-6850.casb2025-0531

Abstract

Abstract:

To investigate the effects of carbon (C) ion beam treatment on the tissue culture of wheat immature embryos and the somaclonal variation in their progeny, and to provide a reference for increasing the variation frequency of wheat somatic clones to address germplasm scarcity and accelerate new cultivar breeding, this study was conducted. Using the pure-line seed 15-676, which exhibits excellent agronomic traits but relatively tall plant height, immature embryos were treated with a carbon ion beam at a radiation dose of 80 Gy and then subjected to tissue culture. Untreated tissue-cultured embryos served as the control. The induction frequency, differentiation frequency, variations in major agronomic traits in the M₂S₁ and S₁generations, and the glutenin subunit composition were systematically examined. The results revealed that the differentiation frequency in the carbon ion beam-treated group was 11.6%, which was significantly lower than that in the control group (20.6%). In the M₂S₁ generation, the plant height in the carbon ion beam-treated group decreased by 11.74 cm compared to the control, a difference that was highly significant. Meanwhile, the treated group demonstrated increases in the number of grains per main spike, grain weight per main spike, and grain weight per plant. Additionally, both the M₂S₁and S₁progeny grains retained the same high-quality glutenin subunits (5+10) as the original 15-676 variety. In conclusion, the combination of carbon ion beam treatment with tissue culture can effectively enhance the level of genetic variation in somatic clones, thereby expanding screening opportunities for beneficial mutants and providing abundant genetic materials for wheat germplasm innovation and new variety breeding.

Key words: heavy ion, carbon ion beam, wheat, radiation, mutagenesis, tissue culture, glutenin

CLC Number:

S512.1小麦

SUN Yan, ZHANG Hongji, LIU Wenlin, TANG Jingquan, YANG Shuping. Research on Improving Wheat Mutagenesis Efficiency by Combining Carbon Ion Beam with Tissue Culture[J]. Chinese Agricultural Science Bulletin, 2026, 42(10): 1-5.

Figures/Tables 7

References 25

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处理	辐照剂量/Gy	接种数/枚	出愈数/枚	诱导率/%	胚性愈伤数/枚	苗数/株	分化率/%
未处理组培	0	500	500	100	364	75	20.6
C离子束+组培	80	500	500	100	467	54	11.6

处理	辐照剂量/Gy	接种数/枚	出愈数/枚	诱导率/%	胚性愈伤数/枚	苗数/株	分化率/%
未处理组培	0	500	500	100	364	75	20.6
C离子束+组培	80	500	500	100	467	54	11.6

处理	株高/cm	穗长/cm	主穗小穗数/个	分蘖数/个	主穗粒数/个	主穗粒重/g	单株粒重/g
CK	116.45±4.39	12.65±0.67	17.90±1.37	8.90±2.03	41.40±7.78	1.52±0.36	12.64±3.77
CK+组培	114.32±3.71	12.67±0.87	17.92±1.42	8.86±2.37	43.63±9.35	1.59±0.38	13.11±3.94
C离子束+组培	104.71±8.28^**	12.63±1.07	17.78±1.58	9.29±2.75	45.54±10.31	1.69±0.42	13.42±4.17

处理	株高/cm	穗长/cm	主穗小穗数/个	分蘖数/个	主穗粒数/个	主穗粒重/g	单株粒重/g
CK	116.45±4.39	12.65±0.67	17.90±1.37	8.90±2.03	41.40±7.78	1.52±0.36	12.64±3.77
CK+组培	114.32±3.71	12.67±0.87	17.92±1.42	8.86±2.37	43.63±9.35	1.59±0.38	13.11±3.94
C离子束+组培	104.71±8.28^**	12.63±1.07	17.78±1.58	9.29±2.75	45.54±10.31	1.69±0.42	13.42±4.17

处理	株系	HMW-GS亚基
C离子束+组培	M₂S₁-1	2*，7+9,5+10
	M₂S₁-2	2*，7+9,5+10
	M₂S₁-3	2*，7+9,5+10
CK	4	2*，7+9,5+10
CK+组培	S₁-5	2*，7+9,5+10
	S₁-6	2*，7+9,5+10
	S₁-7	2*，7+9,5+10