2024年中国林木遗传育种研究进展

doi:10.11707/j.1001-7488.LYKX20250349

摘要/Abstract

摘要：

2024年，面向国家“双碳”战略与森林质量提升需求，我国林木遗传育种取得系列标志性进展，推动育种体系向精准化、智能化加速转型。在基因组学方面，完成杨树、二球悬铃木、橡胶树等11种代表性树种的高质量单倍型或端粒到端粒的基因组组装，构建了涵盖多个代表性类群的超泛基因组，推进比较、群体与泛基因组研究，解析物种地理分化机制与染色体演化路径，实现了种质资源与性状基因的深度整合。围绕木材形成、抗逆响应与产量积累等关键性状，借助多组学联合解析，构建了调控细胞增殖分化、激素信号、环境适应等过程的分子网络。基因编辑技术实现无外源遗传物质的精准改造，建立了适用于多种树种的高效编辑体系，加速了功能基因验证与优异突变体的创制。全基因组选择结合全基因组关联分析先验信息，实现林木复杂性状预测准确率的显著提升，增强了选育效率。在育种技术方面，远缘杂交与染色体加倍相结合的多倍体育种，打破生殖障碍，拓展了速生、抗逆种质的创新路径。全年审定23个突破性良种，覆盖经济林树种与用材树种等主要类型，适宜区域覆盖全国50%以上可造林地。我国林木遗传育种正逐步构建以‘组学资源积累—功能基因挖掘—精准预测模型—分子设计育种—优异种质创制’为主线的育种技术路径体系，并同步推进多树种、多组学、多尺度集成的数据平台与共享系统建设，持续增强支撑复杂性状解析与高效育种的基础能力，为森林碳汇提升、林地提质和国家生态安全提供了坚实科技支撑。

关键词: 林木遗传育种, 基因组学, 性状调控, 基因编辑, 全基因组选择, 品种选育

Abstract:

In 2024, driven by China’s “dual carbon” strategy and the demand for improving forest quality, the forest genetic breeding research in China has made a series of landmark progress, promoting the accelerated transition of the breeding system toward precision and intelligence. In terms of genomics, chromosome-level haplotype-resolved or telomere-to-telomere (T2T) genome assemblies have been completed for 11 representative tree species, including Populus spp., Platanus acerifolia, and Hevea brasiliensis, along with the construction of a super-pangenome spanning major taxonomic groups. These advances have facilitated comparative, population, and pangenomic analyses, revealing species-level geographic divergence mechanisms and chromosomal evolutionary trajectories, and enabling the integration of germplasm resources with key genes underlying important traits. Through multi-omics integration, a molecular network has been constructed to regulate processes such as cell proliferation and differentiation, hormone signaling, and environmental adaptation, focusing on key traits such as wood formation, stress adaptation, and biomass accumulation. Advances in genome editing technology have enabled precise gene modification without exogenous genetic material, establishing versatile editing platforms suitable for diverse tree species and accelerating the functional validation of genes and elite allele development. Genomic selection, combined with prior information from genome-wide association study (GWAS), has significantly improved the predictive accuracy for complex traits, enhancing selection efficiency and accelerating genetic gain. In breeding innovation, polyploid breeding combining distant hybridization with chromosome doubling has overcome reproductive barriers. Polyploid strategies, including 2n gamete induction and somatic chromosome doubling, have broadened the genetic base for developing fast-growing and stress-resilient germplasm. A total of 23 breakthrough cultivars were officially approved in 2024, covering major types such as fast-growing, economic, and timber tree species, with potential deployment across more than 50% of China’s afforestation zones. China is progressively building a breeding framework integrating omics resource accumulation, functional gene discovery, gene functional dissection, accurate genomic prediction, molecular design breeding, elite germplasm creation. Meanwhile, the development of integrated data platforms of multi-species, multi-omics, and multi-scale is strengthening the foundation for complex trait dissection and precision breeding. These efforts are reinforcing national capacity to enhance forest carbon sinks, improve forestland productivity, and safeguard ecological security.

Key words: tree genetics and breeding, genomics, trait regulation, gene editing, genomic selection, breeding variety selection

中图分类号:

王军辉,丁昌俊,李伟,罗克明,王君,张伟溪,钮世辉,张苗苗,赵曦阳,薛良交,殷恒福. 2024年中国林木遗传育种研究进展[J]. 林业科学, 2025, 61(7): 35-51.

Junhui Wang,Changjun Ding,Wei Li,Keming Luo,Jun Wang,Weixi Zhang,Shihui Niu,Miaomiao Zhang,Xiyang Zhao,Liangjiao Xue,Hengfu Yin. Advances in Genetic Breeding Research of Chinese Forest Trees in 2024[J]. Scientia Silvae Sinicae, 2025, 61(7): 35-51.

图/表 1

表1

2024年度国家林木良种信息表"

良种名称 Cultivar name	树种 Species	良种编号 Registration code	选育单位 Breeding institution
‘中桐1号’泡桐 Paulownia fortunei ‘Zhongtong 1’	泡桐 P. tomentosa	国S-SV-PF-001-2024 Guo S-SV-PF-001-2024	中国林业科学研究院经济林研究所 Research Institute of Non-timber Forestry, Chinese Academy of Forestry
‘中桐16号’泡桐 Paulownia fortunei × P. tomentosa ‘Zhongtong 16’	泡桐 P. tomentosa	国S-SV-PF-002-2024 Guo S-SV-PF-002-2024	中国林业科学研究院经济林研究所 Research Institute of Non-timber Forestry, Chinese Academy of Forestry
欧洲云杉捷克种源 Picea abies ‘Czech Provenance’	欧洲云杉 P. abies	国S-SP-PA-003-2024 Guo S-SP-PA-003-2024	中国林业科学研究院林业研究所等 Research Institute of Forestry, Chinese Academy of Forestry, et al.
‘热林518’尾叶桉 Eucalyptus urophylla ‘Relin 518’	尾叶桉 E. urophylla	国S-SC-EU-004-2024 Guo S-SC-EU-004-2024	中国林业科学研究院热带林业研究所 Research Institute of Tropical Forestry, Chinese Academy of Forestry
‘京丰2号’杨 Populus ‘Jingfeng 2’	杨树 Populus spp.	国S-SC-PJ-005-2024 Guo S-SC-PJ-005-2024	北京林业大学等 Beijing Forestry University, et al.
火炬松家系 W11 Pinus taeda Family ‘W11’	火炬松 P. taeda	国S-SF-PT-006-2024 Guo S-SF-PT-006-2024	华南农业大学 South China Agricultural University
火炬松家系 W14 Pinus taeda Family ‘W14’	火炬松 P. taeda	国S-SF-PT-007-2024 Guo S-SF-PT-007-2024	华南农业大学 South China Agricultural University
‘红粉’大岛樱 Prunus speciosa × P. campanulata ‘Hongfen’	大岛樱 P. speciosa	国S-SV-PS-008-2024 Guo S-SV-PS-008-2024	浙江省林业科学研究院等 Zhejiang Academy of Forestry, et al.
‘华仲30号’杜仲 Eucommia ulmoides ‘Huazhong 30’	杜仲 E. ulmoides	国S-SV-EU-009-2024 Guo S-SV-EU-009-2024	中国林业科学研究院经济林研究所 Research Institute of Non-timber Forestry, Chinese Academy of Forestry
‘凤选1号’花椒 Zanthoxylum bungeanum ‘Fengxuan 1’	花椒 Z. bungeanum	国S-SV-ZB-010-2024 Guo S-SV-ZB-010-2024	西北农林科技大学 Northwest A& F University
‘宝光’葡萄 Vitis vinifera × V. labrusca ‘Baoguang’	葡萄 Vitis vinifera	国S-SV-VV-011-2024 Guo S-SV-VV-011-2024	河北省农林科学院昌黎果树研究所 Changli Fruit Tree Research Institute, Hebei Academy of Agriculture and Forestry
‘蜜光’葡萄 Vitis vinifera×V. labrusca ‘Miguang’	葡萄 V. vinifera	国S-SV-VV-012-2024 Guo S-SV-VV-012-2024	河北省农林科学院昌黎果树研究所 Changli Fruit Tree Research Institute, Hebei Academy of Agriculture and Forestry
‘礼品2号’核桃 Juglans regia ‘Lipin 2’	核桃 J. regia	国S-SV-JR-013-2024 Guo S-SV-JR-013-2024	辽宁省经济林研究所等 Liaoning Institute of Economic Forestry and Research Institute of Forestry, Chinese Academy of Forestry, et al.
‘辽宁1号’核桃 Juglans regia ‘Liaoning 1’	核桃 J. regia	国S-SV-JR-014-2024 Guo S-SV-JR-014-2024	辽宁省经济林研究所等 Liaoning Institute of Economic Forestry and Research Institute of Forestry, Chinese Academy of Forestry, et al.
‘中宁奇’核桃 Juglans hindsii × J. regia ‘zhongningqi’	核桃 J. regia	国S-SV-JH-015-2024 Guo S-SV-JH-015-2024	中国林业科学研究院林业研究所 Research Institute of Forestry, Chinese Academy of Forestry
‘强桑3号’桑 Morus alba ‘Qiangsang 3’	桑树 Morus alba	国S-SV-MA-016-2024 Guo S-SV-MA-016-2024	浙江省农业科学院 Zhejiang Academy of Agricultural Sciences
‘强桑5号’桑 Morus alba ‘Qiangsang 5’	桑树 M. alba	国S-SV-MA-017-2024 Guo S-SV-MA-017-2024	浙江省农业科学院 Zhejiang Academy of Agricultural Sciences
‘皖叶5号’桑 Morus alba ‘Wanye 5’	桑树 M. alba	国S-SV-MA-018-2024 Guo S-SV-MA-018-2024	安徽省农业科学院蚕桑研究所 Sericulture Research Institute, Anhui Academy of Agricultural Sciences
‘皖叶6号’桑 Morus alba ‘Wanye 6’	桑树 M. alba	国S-SV-MA-019-2024 Guo S-SV-MA-019-2024	安徽省农业科学院蚕桑研究所 Sericulture Research Institute, Anhui Academy of Agricultural Sciences
‘豆果’油橄榄 Olea europaea ‘Arbequina’	油橄榄 O. europaea	国S-ETS-OE-020-2024 Guo S-ETS-OE-020-2024	中国林业科学研究院林业研究所等 Research Institute of Forestry, Chinese Academy of Forestry, et al.
‘科罗莱卡’油橄榄 Olea europaea ‘Koroneiki’	油橄榄 O. europaea	国S-ETS-OE-021-2024 Guo S-ETS-OE-021-2024	中国林业科学研究院林业研究所等 Research Institute of Forestry, Chinese Academy of Forestry, et al.
吴城油松一代无性系种子园种子 Pinus tabuliformis ‘wuchengyousongyidaiwuxingxizhongziyuanzhongzi’	油松 P. tabuliformis	国R-CSO（1）-PT-001-2024 Guo R-CSO（1）-PT-001-2024	山西省关帝山国有林管理局吴城种子园 Wucheng Seed Orchard, Guandi Mountain National Forest Administration of Shanxi Province
‘中成4号’杨 Populus deltoides ‘Zhongcheng 4’	美洲黑杨 P. deltoides	国R-SC-PD-002-2024 Guo R-SC-PD-002-2024	中国林业科学研究院林业研究所 Research Institute of Forestry, Chinese Academy of Forestry

表1

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