Genomic Analyses Reveal Demographic History and Temperate Adaptation of the Newly Discovered Honey Bee Subspecies Apis mellifera sinisxinyuan n. ssp

文献类型: 外文期刊

第一作者: Chen, Chao

作者: Chen, Chao;Liu, Zhiguang;Chen, Xiao;Wang, Huihua;Guo, Haikun;Shi, Wei;Chen, Chao;Liu, Zhiguang;Shi, Wei;Pan, Qi;Lu, Hongfeng;Tian, Shilin;Li, Ruiqiang;Liu, Shidong;Li, Ruiqiang;Li, Ruiqiang

作者机构:

关键词: Apis mellifera sinisxinyuan;new subspecies;temperate climates;population history;adaptation

期刊名称:MOLECULAR BIOLOGY AND EVOLUTION ( 影响因子:16.24; 五年影响因子:18.67 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Studying the genetic signatures of climate-driven selection can produce insights into local adaptation and the potential impacts of climate change on populations. The honey bee (Apis mellifera) is an interesting species to study local adaptation because it originated in tropical/subtropical climatic regions and subsequently spread into temperate regions. However, little is known about the genetic basis of its adaptation to temperate climates. Here, we resequenced the whole genomes of ten individual bees from a newly discovered population in temperate China and downloaded resequenced data from 35 individuals from other populations. We found that the new population is an undescribed subspecies in the M-lineage of A. mellifera (Apis mellifera sinisxinyuan). Analyses of population history show that long-term global temperature has strongly influenced the demographic history of A. m. sinisxinyuan and its divergence from other subspecies. Further analyses comparing temperate and tropical populations identified several candidate genes related to fat body and the Hippo signaling pathway that are potentially involved in adaptation to temperate climates. Our results provide insights into the demographic history of the newly discovered A. m. sinisxinyuan, as well as the genetic basis of adaptation of A. mellifera to temperate climates at the genomic level. These findings will facilitate the selective breeding of A. mellifera to improve the survival of overwintering colonies.

分类号: Q7

  • 相关文献

[1]Mitochondrial DNA variation, effective female population size and population history of the endangered Chinese sturgeon, Acipenser sinensis. Zhang, SM,Wang, DQ,Zhang, YP.

[2]Genetic variation and phylogeography of Psammosilene tunicoides (Caryophyllaceae), a narrowly distributed and endemic species in south-western China. Zhang, Qing-Ying,Zhao, Yu-Juan,Gong, Xun,Zhang, Qing-Ying.

[3]The complete mitochondrial genome sequence of Coilia ectenes (Clupeiformes: Engraulidae). Qiao, Huiying,Cheng, Qiqun,Chen, Ying,Chen, Wenming,Zhu, Yuxia,Qiao, Huiying,Chen, Ying,Chen, Wenming,Zhu, Yuxia.

[4]The strategy of Na+ compartmentation and growth of Atriplex centralasiatica in adaptation to saline environments. Qiu, N.,Wang, Y.,Peng, X.,Qiu, N.,Zhou, F.,Hua, C.. 2014

[5]Multiple amino acid substitutions involved in the adaptation of H6N1 avian influenza virus in mice. Yu, Zhijun,Qin, Chuan,Xia, Xianzhu,Yu, Zhijun,Qin, Chuan,Xia, Xianzhu,Yu, Zhijun,Cheng, Kaihui,Xin, Yue,Sun, Weiyang,Li, Xue,Huang, Jing,Zhang, Kun,Yang, Songtao,Wang, Tiecheng,Zheng, Xuexing,Wang, Hualei,Qin, Chuan,Xia, Xianzhu,Cheng, Kaihui,Chai, Hongliang.

[6]Rapid acquisition adaptive amino acid substitutions involved in the virulence enhancement of an H1N2 avian influenza virus in mice. Yu, Zhijun,Sun, Weiyang,Zhang, Xinghai,Xia, Xianzhu,Gao, Yuwei,Xia, Xianzhu,Gao, Yuwei,Cheng, Kaihui,Zhao, Chuqi.

[7]Heritable alteration in DNA methylation induced by nitrogen-deficiency stress accompanies enhanced tolerance by progenies to the stress in rice (Oryza sativa L.). Von Wettstein, D.,Kou, H. P.,Li, Y.,Song, X. X.,Ou, X. F.,Liu, B.,Kou, H. P.,Li, Y.,Song, X. X.,Ou, X. F.,Liu, B.,Kou, H. P.,Ma, J.,Xing, S. C.. 2011

[8]Evolution of the PEBP gene family and selective signature on FT-like clade. Zheng, Xiao-Ming,Wu, Fu-Qing,Zhang, Xin,Lin, Qi-Bing,Wang, Jie,Guo, Xiu-Ping,Lei, Cai-Lin,Cheng, Zhi-Jun,Zou, Cheng,Wan, Jian-Min,Wan, Jian-Min. 2016

[9]The Sinocyclocheilus cavefish genome provides insights into cave adaptation. Yang, Junxing,Jiang, Wansheng,Pan, Xiaofu,Wang, Xiaoai,Chen, Xiaoyong,Zheng, Lanping,Chen, Xiaoli,Bai, Jie,Fang, Dongming,Qiu, Ying,Yuan, Hui,Bian, Chao,Lu, Jiang,He, Shiyang,Zhang, Yaolei,You, Xinxin,Wang, Yongsi,Sun, Ying,Mao, Danqing,Liu, Yong,Fan, Guangyi,Zhang, He,Zhang, Xinhui,Wang, Jintu,Chen, Jieming,Ruan, Zhiqiang,Li, Jia,Yu, Hui,Peng, Chao,Wang, Jian,Yang, Huanming,Wang, Jun,Xu, Xun,Bai, Jie,Qiu, Ying,Bian, Chao,You, Xinxin,Zhang, Xinhui,Chen, Jieming,Ruan, Zhiqiang,Li, Jia,Yu, Hui,Peng, Chao,Bai, Jie,Whitten, Tony,Qiu, Ying,Sun, Ying,Cheng, Le,Fang, Dongming,Lu, Jiang,He, Shiyang,Li, Jia,Yu, Hui,Zhang, Yaolei,Cheng, Le,Ma, Xingyu,Xu, Junmin,Shi, Qiong,Ma, Xingyu,Xu, Junmin,Shi, Qiong,He, You,Xu, Zhengfeng,Xu, Pao,Wang, Jian,Yang, Huanming,Wang, Jun. 2016

[10]Gene expression changes leading extreme alkaline tolerance in Amur ide (Leuciscus waleckii) inhabiting soda lake. Xu, Jian,Li, Qiang,Xu, Liming,Jiang, Yanliang,Zhao, Zixia,Zhang, Yan,Li, Jiongtang,Dong, Chuanju,Xu, Peng,Sun, Xiaowen,Wang, Shaolin,Dong, Chuanju. 2013

[11]Ecogeographic analysis of pea collection sites from China to determine potential sites with abiotic stresses. Li, Ling,Redden, Robert J.,Zong, Xuxiao,Berger, J. D.,Bennett, Sarita Jane.

[12]OsCOL16, encoding a CONSTANS-like protein, represses flowering by up regulating Ghd7 expression in rice. Wu, Weixun,Chen, Daibo,Zhang, Yingxin,Sun, Limping,Yang, Zhengfu,Zhao, Chunde,Zhan, Xiaodeng,Shen, Xihong,Yu, Ping,Fu, Yaping,Cao, Liyong,Cheng, Shihua,Wu, Weixun,Chen, Daibo,Zhang, Yingxin,Sun, Limping,Yang, Zhengfu,Zhao, Chunde,Zhan, Xiaodeng,Shen, Xihong,Yu, Ping,Fu, Yaping,Cao, Liyong,Cheng, Shihua,Zheng, Xiao-Ming,Ma, Weiwei,Zhang, Huan,Zhu, Shanshan.

[13]ALS herbicide resistance mutations in Raphanus raphanistrum: evaluation of pleiotropic effects on vegetative growth and ALS activity. Li, Mei,Yu, Qin,Han, Heping,Vila-Aiub, Martin,Powles, Stephen B.,Li, Mei,Vila-Aiub, Martin.

[14]DNA methylation pattern of Photoperiod-B1 is associated with photoperiod insensitivity in wheat (Triticum aestivum). Sun, Han,Guo, Zhiai,Gao, Lifeng,Zhao, Guangyao,Zhang, Wenping,Zhou, Ronghua,Wu, Yongzhen,Jia, Jizeng,Sun, Han,An, Hailong,Wang, Haiyang.

[15]Climate change impacts on crop yield and quality with CO2 fertilization in China. Lin, ED,Xiong, W,Ju, H,Xu, YL,Li, Y,Bai, LP,Xie, LY.

[16]Adaptation of the externally feeding bug Elasmucha necopinata (Hemiptera: Acanthosomatidae) to its fig host. Huang, Da-Wei,Ma, Guang-Chang,Hu, Hao-Yuan,Ma, Guang-Chang,Niu, Li-Ming,Fu, Yue-Guan,Peng, Zheng-Qiang,Bu, Wen-Jun,Huang, Da-Wei.

[17]High/low nitrogen adapted hybrid of rice cultivars and their physiological responses. Li Xia,Sun Zhiwei,Jin Lei,Han Lei,Ren Chenggang,Wang Man,Lu Chuangen. 2011

[18]Chinese Food Security and Climate Change: Agriculture Futures. Ye, Liming,Tang, Huajun,Wu, Wenbin,Yang, Peng,Nelson, Gerald C.,Mason-D'Croz, Daniel,Palazzo, Amanda. 2014

[19]The impact of weather variations on maize yields and household income: Income diversification as adaptation in rural China. Ma, Jiliang,Maystadt, Jean-Francois.

[20]Adopting higher-yielding varieties to ensure Chinese food security under climate change in 2050. Ye, Liming,Tang, Huajun,Yang, Guixia,Van Ranst, Eric,Ye, Liming,Tang, Huajun,Yang, Guixia,Ye, Liming,Van Ranst, Eric. 2015

作者其他论文 更多>>

微信小程序