西南地区家鸡线粒体DNA控制区遗传多样性和基因渗入

doi:10.17520/biods2026003

生物多样性

西南地区家鸡线粒体DNA控制区遗传多样性和基因渗入

贾晓旭¹, 陈皖强¹, 唐修君¹, 樊艳凤¹, 张静¹, 王海威^2*, 高玉时^1*

1. 江苏省家禽科学研究所，江苏扬州 225125; 2. 重庆市畜牧科学院，重庆402460

收稿日期:2026-01-04 修回日期:2026-04-02
通讯作者: 王海威, 高玉时
基金资助:
国家重点研发计划(2021YFD1200302); 国家自然科学基金(32372869)

Genetic diversity and gene introgression of mitochondrial DNA control region in indigenous chickens from Southwest China

Xiaoxu Jia¹, Wanqiang Chen¹, Xiujun Tang¹, Yanfeng Fan¹, Jing Zhang¹, Haiwei Wang^2*, Yushi Gao^1*

1 Jiangsu lnstitute of Poultry Science, Yangzhou, 225125, China

2 Chongqing Academy of Animal Sciences, Chongqing 402460, China

Received:2026-01-04 Revised:2026-04-02
Contact: Haiwei Wang, Yushi Gao

摘要/Abstract

摘要： 我国西南地区地形复杂、生态类型多样，是家鸡（Gallus gallus）遗传资源高度富集的重要区域。系统评估西南地区地方鸡的遗传多样性及外源血缘渗入状况，对于维护家鸡遗传资源安全具有重要意义。本研究以重庆、四川、贵州、云南和西藏等地21个代表性地方鸡品种和常用商业鸡品种为研究对象，对其线粒体DNA控制区（D-loop）全序列进行测序，并开展遗传多样性、单倍型组成及母系血缘渗入分析。共获得1,146条完整D-loop序列，总体单倍型多样度和核苷酸多样度分别为0.943和0.00699，整体上表现出较高的多样性水平，但不同品种间遗传多样性水平存在差异。大围山微型鸡和平武红鸡的Tajima’s D值显著偏离中性，提示其可能经历过选择作用或群体历史事件。共检测到70个多态性位点和105种单倍型，可划分为A、B、C、D、E、F和G共7个单倍型类群，其中A、B和E类群为优势类群。系统进化树和中介网络图分析表明，各单倍型类群形成相对独立的谱系结构；群体间亲缘关系与优势单倍型构成密切相关，而与地理分布并不完全一致。部分单倍型在不同地区和品种间广泛共享，反映出复杂的历史分化与基因交流过程。外来商业鸡种均属于E单倍型类群；除茶花鸡和独龙鸡外，其余地方鸡品种均检测到不同数量的E类群单倍型，并与商业鸡种共享核心单倍型。部分群体中E类群比例偏高，提示其母系遗传结构可能受到外源血缘影响。总体而言，西南地区地方鸡仍保留了较为丰富的母系遗传变异。为维持其遗传多样性和谱系完整性，建议加强保种群体规范化管理，合理控制外来血缘导入比例。本研究为西南地区地方鸡遗传资源的科学保护与合理利用提供了重要的分子遗传学参考。

关键词: 西南地区, 地方鸡, 遗传多样性, 线粒体DNA, D-loop区

Abstract

Aims: Southwest China is characterized by complex topography, diverse ecological conditions, and abundant indigenous chicken genetic resources. A systematic evaluation of the genetic diversity of local chicken populations in this region, together with potential introgression from exotic commercial breeds, is essential for the conservation and sustainable utilization of these valuable genetic resources.

Methods: In this study, 21 representative indigenous chicken breeds from Chongqing, Sichuan, Guizhou, Yunnan, and Tibet, together with commonly used commercial chicken breeds, were investigated. The complete mitochondrial DNA control region (D-loop) was amplified and sequenced, and the resulting sequences were used to assess genetic diversity, haplotype composition, phylogenetic relationships, and potential maternal introgression from commercial breeds.

Results: A total of 1,146 complete D-loop sequences were obtained. The overall haplotype diversity (Hd) and nucleotide diversity (π) were 0.943 and 0.00699, respectively, indicating a relatively high level of maternal genetic diversity across indigenous chicken populations in Southwest China, although diversity differed among breeds. Tajima’s D values for Daweishan Mini Chicken and Pingwu Red Chicken deviated significantly from neutrality, suggesting possible selection or demographic events. In total, 70 polymorphic sites and 105 haplotypes were identified, which were assigned to seven haplogroups (A, B, C, D, E, F, and G), with haplogroups A, B, and E being dominant. Phylogenetic and median-joining network analyses showed that the haplogroups formed relatively independent lineages, and that the genetic relationships among populations were more closely associated with dominant haplotype composition than with geographic distribution. Several haplotypes were widely shared among breeds and regions, indicating complex historical differentiation and gene flow. All commercial breeds belonged to haplogroup E. Except for Chahua Chicken and Dulong Chicken, all indigenous breeds contained varying proportions of haplogroup E haplotypes and shared core haplotypes with commercial breeds. In several populations, the proportion of haplogroup E was relatively high, suggesting possible maternal introgression from exotic lineages.

Conclusion: Indigenous chickens in Southwest China still retain abundant maternal genetic variation overall. However, the elevated proportion of haplogroup E in some populations indicates that maternal genetic structure may have been influenced by exogenous commercial lineages. Strengthening the standardized management of conservation populations and carefully regulating the introduction of exotic bloodlines will therefore be important for maintaining genetic diversity and lineage integrity. These findings provide an important molecular genetic basis for the scientific conservation and rational utilization of indigenous chicken resources in Southwest China.

Key words: Southwest China, indigenous chickens, genetic diversity, mitochondrial DNA, D-loop region

贾晓旭, 陈皖强, 唐修君, 樊艳凤, 张静, 王海威, 高玉时. 西南地区家鸡线粒体DNA控制区遗传多样性和基因渗入. 生物多样性, DOI: 10.17520/biods2026003.

Xiaoxu Jia, Wanqiang Chen, Xiujun Tang, Yanfeng Fan, Jing Zhang, Haiwei Wang, Yushi Gao. Genetic diversity and gene introgression of mitochondrial DNA control region in indigenous chickens from Southwest China. Biodiversity Science, DOI: 10.17520/biods2026003.

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