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红勋1号与重瓣海棠杂交F1代花性状遗传分析OA

Genetic analysis of floral traits in F1 hybrids of Hongxun No.1×Double-flowering crabapple

中文摘要英文摘要

[目的]深入分析并挖掘红勋1号和重瓣海棠杂交F1代花相关性状的遗传变异和遗传规律,为观赏海棠选育提供依据.[方法]通过田间调查,统计分析红勋1号和重瓣海棠杂交F1代204个株系的5个数值型性状(花直径、花瓣数、雄蕊数、雌蕊数、花梗长度)和2个描述型性状(花色和单、重瓣),分析其遗传规律.[结果]红勋1号与重瓣海棠F1代5个数值型性状的遗传变异分析结果表明,花直径的变异系数最小(14.13%),遗传传递力达89.84%,表明表型变异受遗传因素主导,最佳遗传模型为2MG-EA.花瓣数遗传传递力为72.43%,杂种优势率为-27.57%,主基因模型为2MG-AD.雄蕊数超高亲率达27.76%,主基因遗传率为92.00%,最佳模型为2MG-AD.雌蕊数变异系数达386.35%,主基因模型为2MG-A.花梗长度变异系数最大(417.24%),但主基因遗传率仅24.34%,表现出较低的遗传稳定性.F1代花色出现极为明显的性状分离,分离表现为白(4.46%)、粉红(50.50%)、红(33.66%)和紫红(11.38%);F1代单瓣(82.57%)和重瓣(17.43%).[结论]利用红勋1号×重瓣海棠F1群体,研究揭示了观赏海棠花器官性状的遗传差异.其中,花直径与雄蕊数遗传力高,花瓣数受主基因与显性抑制效应共同调控,雌蕊数具有遗传改良潜力,而花梗长度的选择性较弱.

[Objective]Ornamental crabapples(Malus spp.)are primarily distributed across the Eur-asian continent and North America.Due to their vivid flower colors,concentrated blooming periods,and abundant flowering,ornamental crabapples have been widely applied in scenic areas,gardens,ur-ban greening,and container gardening.Many ornamental crabapples in China were introduced from North America and Europe,and hybrid breeding was primarily focused on improving fruit traits of des-sert apples.As a result,the breeding of crabapples started relatively late and mainly targeted descriptive traits such as flowering time,phenology,and flower color.Heridity of quantitative floral organ traits has been far from clear.A deeper analysis of the genetic variation and inheritance patterns of floral traits in the F1 progeny derived from the cross between Hongxun No.1 and Double-flowering crabapple can pro-vide a foundation for breeding ornamental apple cultivars.[Methods]A total of 204 F1 hybrid individu-als derived from the cross between Hongxun No.1(Malus spp.)and Double-flowering crabapple(Ma-lus spp.)were investigated for five quantitative floral traits(flower diameter,petal count,stamen count,pistil count,and peduncle length)and two descriptive traits(flower color and petal type:single or dou-ble).We organized experimental data using IBM SPSS Statistics 27,and generated figures with Origin 2018.The parental values(P1 and P2),variances(Vp1 and Vp2),mid-parent value(MP),hybrid population mean(F),standard deviation(S),variance(VH),coefficient of variation(CV,%),transmissibility(Ta,%),broad-sense heritability(Hb2,%),heterosis rate(H,%),and high-parent rate(HH,%)were calculated to analyze the inheritance patterns.The mixed major gene plus polygene inheritance model was used to an-alyze the genetic models of the five quantitative traits in the F1 population using the SEA software pack-age.The optimal genetic model was selected based on the minimum Akaike's Information Criterion(AIC),and the corresponding major gene effects were estimated using the least squares method.[Re-sults]Phenotypic identification of five quantitative and two descriptive traits in 204 F1 progeny re-vealed rich genetic diversity.The flower color in the F1 population showed clear segregation into four phenotypes:white(4.46%),pink(50.50%),red(33.66%),and purplish-red(11.38%).The petal type segregated into single-petaled(82.57%)and double-petaled(17.43%)individuals.Variants such as white single-petaled and red double-petaled were observed,demonstrating the high potential for select-ing elite ornamental germplasm.All five quantitative traits showed varying degrees of phenotypic varia-tion.The flower diameter had the lowest coefficient of variation(14.13%)and exhibited high genetic transmissibility and broad-sense heritability.Its optimal inheritance model was 2MG-EA,with a posi-tive additive major gene effect and a major gene heritability as high as 98.79%.The petal count exhibit-ed relatively high heritability and transmissibility,but with a negative heterosis(-27.57%).Most F1 indi-viduals had fewer petals than the mid-parent value,and the double-petal phenotype was unstable.The adaptability test suggested the optimal inheritance model for petal count was 2MG-AD.The stamen and pistil count both showed substantial variation in the F1 generation,indicating the potential for genetic improvement.The stamen count exhibited strong positive heterosis,high-parent value,and high herita-bility.Its optimal model was 2MG-AD,with a positive additive effect(3.72)and a negative dominance effect(-2.45),indicating a degree of suppression from dominant genes.The major gene heritability was 92%,showing stable inheritance primarily under additive genetic control.The pistil count had a high co-efficient of variation,heritability,and broad-sense heritability.The best model was 2MG-A,indicating the inheritance was dominated by additive effects,suggesting good selection potential.The peduncle length conformed to a normal distribution but had the highest coefficient of variation(417.24%),indi-cating strong phenotypic plasticity in response to environmental factors.It had relatively low transmissi-bility(20.5%)and broad-sense heritability(52.75%).The F1 mean value was slightly lower than the mid-parent value,showing negative heterosis.The optimal genetic model was 2MG-AD,but the addi-tive and dominance effects of the major genes were weak.[Conclusion]The floral traits of the F1 proge-ny from the cross between Hongxun No.1 and Double-flowering crabapple displayed varying degrees of genetic variation and segregation.The flower diameter and stamen count showed high heritability and stable major gene control,making them priority traits for selection and fixation.The petal count was governed by a complex genetic mechanism involving both major genes and dominant suppression effects.Thus,breeding for double flowers should involve double-flowered parents on both sides.The pistil count exhibited significant variation and was regulated by additive effects of major genes,show-ing the potential for improvement.The peduncle length demonstrated low heritability and selectability,indicating the need for comprehensive evaluation integrating phenotype and environmental response.This study clarified the inheritance patterns of floral quantitative traits in the F1 population from Hongx-un No.1×Double-flowering crabapple and would provide theoretical support and reference models for future floral organ trait improvement and molecular-assisted breeding.

李子琛;尚薇;高源;王大江;王昆;孙思邈;田雯;王霖;孙延明;刘昭;郭含欣

中国农业科学院果树研究所·农业农村部园艺作物种质资源利用重点实验室,辽宁兴城 125100中国农业科学院果树研究所·农业农村部园艺作物种质资源利用重点实验室,辽宁兴城 125100中国农业科学院果树研究所·农业农村部园艺作物种质资源利用重点实验室,辽宁兴城 125100中国农业科学院果树研究所·农业农村部园艺作物种质资源利用重点实验室,辽宁兴城 125100中国农业科学院果树研究所·农业农村部园艺作物种质资源利用重点实验室,辽宁兴城 125100中国农业科学院果树研究所·农业农村部园艺作物种质资源利用重点实验室,辽宁兴城 125100中国农业科学院果树研究所·农业农村部园艺作物种质资源利用重点实验室,辽宁兴城 125100||石河子大学农学院·新疆生产建设兵团特色果树栽培生理与种质资源利用重点实验室,新疆石河子 832000中国农业科学院果树研究所·农业农村部园艺作物种质资源利用重点实验室,辽宁兴城 125100中国农业科学院果树研究所·农业农村部园艺作物种质资源利用重点实验室,辽宁兴城 125100中国农业科学院果树研究所·农业农村部园艺作物种质资源利用重点实验室,辽宁兴城 125100||石河子大学农学院·新疆生产建设兵团特色果树栽培生理与种质资源利用重点实验室,新疆石河子 832000中国农业科学院果树研究所·农业农村部园艺作物种质资源利用重点实验室,辽宁兴城 125100

农业科技

观赏海棠F1代性状遗传

Malusspp.F1 progeniesFlowerTraitHeredity

《果树学报》 2026 (2)

237-245,9

辽宁省"兴辽人才工程"项目(XLYC2203177)农业科技创新计划项目(CAAS-ASTIP-2022-RIP-02)

10.13925/j.cnki.gsxb.20250351

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