基于COⅠ基因序列的蜜蜂属系统发育分析及其舞蹈和筑巢行为进化分析

doi:10.16380/j.kcxb.2018.12.010

昆虫学报 ›› 2018, Vol. 61 ›› Issue (12): 1453-1461.doi: 10.16380/j.kcxb.2018.12.010

基于COⅠ基因序列的蜜蜂属系统发育分析及其舞蹈和筑巢行为进化分析

任晓晓^1,2, 贺兴江³, 龚雪阳¹, 赵文正¹, 刘意秋^1,*, 董坤^1,*

(1. 云南农业大学东方蜜蜂研究所, 云南农业大学动物科学技术学院, 云南省蜜蜂资源可持续利用工程研究中心, 昆明 650201; 2. 贵州省农业科学院蚕业研究所, 贵阳 550006; 3. 贵州省农业科学院现代农业发展研究所, 贵阳 550006)

出版日期:2018-12-20 发布日期:2019-01-22

Phylogenetic analysis of Apis (Hymenoptera: Apidae) based on COI gene sequences and an evolutionary analysis of its dancing and nesting behavior

REN Xiao-Xiao^1,2, HE Xing-Jiang³, GONG Xue-Yang¹, ZHAO Wen-Zheng¹, LIU Yi-Qiu^1,*, DONG Kun^1,*

(1. Yunnan Provincial Engineering and Research Center for Sustainable Utilization of Honeybee Resources, Eastern Bee Research Institute, College of Animal Science and Technology, Yunnan Agricultural University, Kunming 650201, China; 2. Sericultural Institute, GuizhouAcademyof Agricultural Sciences,Guiyang550006,China; 3. Institute of Rural Development Research,GuizhouAcademyof Agricultural Sciences,Guiyang550006,China)

Online:2018-12-20 Published:2019-01-22

摘要/Abstract

摘要： 【目的】分析蜜蜂属Apis的系统发育关系，并在此基础上探讨蜜蜂属舞蹈方向、舞蹈声音、营巢环境、巢脾结构的祖先状态和演变过程。【方法】PCR扩增并测定中国分布的蜜蜂属内东方蜜蜂A. cerana、西方蜜蜂A. mellifera、大蜜蜂A. dorsata、黑大蜜蜂A. laboriosa、小蜜蜂A. florea和黑小蜜蜂A. andreniformis的线粒体COⅠ基因序列，并从NCBI数据库中下载分布于其他国家或地区的上述6种蜜蜂以及绿努蜂A. nulunsis、苏拉威西蜂A. nigrocinta、沙巴蜂A. koschevnikovi、炳式大蜜蜂A. dorsata binghami的COⅠ同源序列。分别利用最大简约法(MP)、最大似然法(ML)和贝叶斯分析(BI)依据这些序列数据构建蜜蜂属系统发育关系。对蜜蜂属上述种的舞蹈语言和筑巢行为进行编码并作为性状特征标记到系统发育树中，利用简约法对祖先状态进行追溯。【结果】系统发育分析结果表明，蜜蜂属可划分为3大类群，即穴居蜜蜂类群(东方蜜蜂、西方蜜蜂、苏拉威西蜂、绿努蜂、沙巴蜂)、大蜜蜂类群(大蜜蜂、黑大蜜蜂)和小蜜蜂类群(小蜜蜂、黑小蜜蜂)；小蜜蜂类群更加接近于祖型，大蜜蜂类群和穴居蜜蜂类群是两支单系；炳式大蜜蜂是独立于大蜜蜂和黑大蜜蜂的蜂种，且与黑大蜜蜂的亲缘关系更近。祖先状态重建结果显示：蜜蜂属祖先在露天环境下筑造垂直的单脾，且在传播食物或巢址信息时跳水平方向的无声摆尾舞，有嗡嗡声的舞蹈及筑造复脾是后来形成的。【结论】COⅠ基因可作为分子标记用于分析蜜蜂属的舞蹈和筑巢行为的祖先状态及进化过程；蜜蜂筑造复脾、跳有嗡嗡声的舞蹈是后期的适应性进化行为。

关键词: 蜜蜂属')">">蜜蜂属, COⅠ基因')">">Ⅰ基因, 系统发育')">">系统发育, 舞蹈语言')">">舞蹈语言, 筑巢行为')">">筑巢行为

Abstract: 【Aim】 To analyze the phylogeny of the genus Apis, and to investigate the ancestral state and the evolutionary process of dance direction, dance sound, nesting environment and comb structure in Apis based on the phylogenetic relationships. 【Methods】 The COI gene fragments of A. cerana, A. mellifera, A. dorsata, A. laboriosa, A. florea and A. andreniformis distributed inChinawere amplified by PCR and sequenced. The homologous sequences of COI gene of the above six species in other states or regions and those of A. nulunsis, A. nigrocinta, A. koschevnikovi and A. dorsata binghami were downloaded from NCBI databases. The phylogenetic relationships were established using maximum parsimony (MP), maximum likelihood (ML) and Bayesian inference (BI) based on these sequence data. The dance language and nesting behavior of each Apis species mentioned above were coded and treated as trait markers, and added correspondingly into the phylogenetic trees. The ancestral state was traced with the ML model. 【Results】 The results of phylogenetic analysis demonstrated that Apis species can be divided into three clusters, i.e., cavity-nesting honeybees (A. cerana, A. mellifera, A. nigrocinta, A. nulunsis, and A. koschevnikovi), giant honeybees (A. dorsata, and A. laboriosa) and dwarf honeybees (A. florea, and A. andreniformis). The dwarf honeybees are more ancestral, and the giant and cavity-nesting species are monophyletic. Our results also suggest that the giant bee A. dorsata binghami is a separate species from A. dorsata and A. laboriosa and closer to A. laboriosa. Prototype inference indicated that ancestral honeybee species nested in the open with a vertical single comb. They disseminate information about food sources and nesting sites using a silent horizontal waggle dance. The behavior of dancing with buzz and nesting with multi-combs appeared subsequently. 【Conclusion】 As a molecular marker, COI gene can be used to analyze the ancestral state and the evolution of dancing and nesting of Apis species. The buzzing dance language and multi-comb nesting behavior could be an outcome of adaptive evolution during the later stage.

Key words: Apis, COI gene, phylogeny, dance language, nesting behavior

任晓晓, 贺兴江, 龚雪阳, 赵文正, 刘意秋, 董坤 . 基于COⅠ基因序列的蜜蜂属系统发育分析及其舞蹈和筑巢行为进化分析[J]. 昆虫学报, 2018, 61(12): 1453-1461.

REN Xiao-Xiao, HE Xing-Jiang, GONG Xue-Yang, ZHAO Wen-Zheng, LIU Yi-Qiu, DONG Kun. Phylogenetic analysis of Apis (Hymenoptera: Apidae) based on COI gene sequences and an evolutionary analysis of its dancing and nesting behavior[J]. Acta Entomologica Sinica, 2018, 61(12): 1453-1461.

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基于COⅠ基因序列的蜜蜂属系统发育分析及其舞蹈和筑巢行为进化分析

Phylogenetic analysis of Apis (Hymenoptera: Apidae) based on COI gene sequences and an evolutionary analysis of its dancing and nesting behavior

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