Emergence and Spread of Basal Lineages of Yersinia pestis during the Neolithic Decline

被引:153
|
作者
Rascovan, Nicolas [1 ]
Sjogren, Karl-Goran [2 ]
Kristiansen, Kristian [2 ]
Nielsen, Rasmus [3 ,4 ]
Willerslev, Eske [3 ,5 ,6 ]
Desnues, Christelle [1 ]
Rasmussen, Simon [7 ,8 ]
机构
[1] Aix Marseille Univ, IHU Mediterranee Infect, IRD 198, AP HM,MEPHI,CNRS,UMR,FRE2013, 19-21 Blvd Jean Moulin, F-13005 Marseille, France
[2] Univ Gothenburg, Dept Hist Studies, S-40530 Gothenburg, Sweden
[3] Univ Copenhagen, Nat Hist Museum Denmark, Ctr GeoGenet, DK-1350 Copenhagen, Denmark
[4] Univ Calif Berkeley, Dept Integrat Biol, Berkeley, CA 94720 USA
[5] Univ Cambridge, Dept Zool, Downing St, Cambridge CB2 3EJ, England
[6] Wellcome Trust Sanger Inst, Hinxton CB10 1SA, Cambs, England
[7] Tech Univ Denmark, Dept Bio & Hlth Informat, Kemitorvet 208, DK-2800 Lyngby, Denmark
[8] Univ Copenhagen, Fac Hlth & Med Sci, Novo Nordisk Fdn, Ctr Prot Res, Blegdamsvej 3B, DK-2200 Copenhagen, Denmark
来源
CELL | 2019年 / 176卷 / 1-2期
基金
新加坡国家研究基金会;
关键词
COMPLETE GENOME SEQUENCE; ANCIENT DNA; STRAIN; EVOLUTION; INSIGHTS; PLAGUE; PATTERNS; ORIGINS; HISTORY; FARMERS;
D O I
10.1016/j.cell.2018.11.005
中图分类号
Q5 [生物化学]; Q7 [分子生物学];
学科分类号
071010 ; 081704 ;
摘要
Between 5,000 and 6,000 years ago, many Neolithic societies declined throughout western Eurasia due to a combination of factors that are still largely debated. Here, we report the discovery and genome reconstruction of Yersinia pestis, the etiological agent of plague, in Neolithic farmers in Sweden, pre-dating and basal to all modern and ancient known strains of this pathogen. We investigated the history of this strain by combining phylogenetic and molecular clock analyses of the bacterial genome, detailed archaeological information, and genomic analyses from infected individuals and hundreds of ancient human samples across Eurasia. These analyses revealed that multiple and independent lineages of V. pestis branched and expanded across Eurasia during the Neolithic decline, spreading most likely through early trade networks rather than massive human migrations. Our results are consistent with the existence of a prehistoric plague pandemic that likely contributed to the decay of Neolithic populations in Europe.
引用
收藏
页码:295 / +
页数:21
相关论文
共 50 条
  • [31] Adaptive response of Yersinia pestis to extracellular effectors of innate immunity during bubonic plague
    Sebbane, Florent
    Lemaitre, Nadine
    Sturdevant, Daniel E.
    Rebeil, Roberto
    Virtaneva, Kimmo
    Porcella, Stephen F.
    Hinnebusch, B. Joseph
    PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 2006, 103 (31) : 11766 - 11771
  • [32] Prairie dog responses to vector control and vaccination during an initial Yersinia pestis invasion
    Eads, David A.
    Biggins, Dean E.
    Ramakrishnan, Shantini
    Goldberg, Amanda R.
    Eads, Samantha L.
    Rocke, Tonie E.
    INTERNATIONAL JOURNAL FOR PARASITOLOGY-PARASITES AND WILDLIFE, 2024, 23
  • [33] Adaptive strategies of Yersinia pestis to persist during inter-epizootic and epizootic periods
    Eisen, Rebecca J.
    Gage, Kenneth L.
    VETERINARY RESEARCH, 2009, 40 (02)
  • [34] Transcriptomic and Innate Immune Responses to Yersinia pestis in the Lymph Node during Bubonic Plague
    Comer, Jason E.
    Sturdevant, Daniel E.
    Carmody, Aaron B.
    Virtaneva, Kimmo
    Gardner, Donald
    Long, Dan
    Rosenke, Rebecca
    Porcella, Stephen F.
    Hinnebusch, B. Joseph
    INFECTION AND IMMUNITY, 2010, 78 (12) : 5086 - 5098
  • [35] Small Insertions and Deletions Drive Genomic Plasticity during Adaptive Evolution of Yersinia pestis
    Wu, Yarong
    Hao, Tongyu
    Qian, Xiuwei
    Zhang, Xianglilan
    Song, Yajun
    Yang, Ruifu
    Cui, Yujun
    MICROBIOLOGY SPECTRUM, 2022, 10 (03):
  • [36] Znu Is the Predominant Zinc Importer in Yersinia pestis during In Vitro Growth but Is Not Essential for Virulence
    Desrosiers, Daniel C.
    Bearden, Scott W.
    Mier, Ildefonso, Jr.
    Abney, Jennifer
    Paulley, James T.
    Fetherston, Jacqueline D.
    Salazar, Juan C.
    Radolf, Justin D.
    Perry, Robert D.
    INFECTION AND IMMUNITY, 2010, 78 (12) : 5163 - 5177
  • [37] A single introduction of Yersinia pestis to Brazil during the 3rd plague pandemic
    Vogler, Amy J.
    Sahl, Jason W.
    Leal, Nilma C.
    Sobreira, Marise
    Williamson, Charles H. D.
    Bollig, Molly C.
    Birdsell, Dawn N.
    Rivera, Andrew
    Thompson, Brian
    Nottingham, Roxanne
    Rezende, Antonio M.
    Keim, Paul
    Almeida, Alzira M. P.
    Wagner, David M.
    PLOS ONE, 2019, 14 (01):
  • [38] Experimental infection of ground squirrels (Citellus pygmaeus Pallas) with Yersinia pestis during hibernation
    Bizanov, Gazim
    Dobrokhotova, Nina D.
    JOURNAL OF INFECTION, 2007, 54 (02) : 198 - 203
  • [39] LABORATORY STUDIES ON YERSINIA-PESTIS DURING THE 1991 OUTBREAK OF PLAGUE IN LUSHOTO, TANZANIA
    LYAMUYA, EF
    NYANDA, P
    MOHAMMEDALI, H
    MHALU, FS
    JOURNAL OF TROPICAL MEDICINE AND HYGIENE, 1992, 95 (05): : 335 - 338
  • [40] Multiple Introductions of Yersinia pestis during Urban Pneumonic Plague Epidemic, Madagascar, 2017
    Andrianaivoarimanana, Voahangy
    Savin, Cyril
    Birdsell, Dawn N.
    Vogler, Amy J.
    Le Guern, Anne-Sophie
    Rahajandraibe, Soloandry
    Bremont, Sylvie
    Rahelinirina, Soanandrasana
    Sahl, Jason W.
    Ramasindrazana, Beza
    Rakotonanahary, Rado Jean Luc
    Rakotomanana, Fanjasoa
    Randremanana, Rindra
    Maheriniaina, Viviane
    Razafimbia, Vaoary
    Kwasiborski, Aurelia
    Baliere, Charlotte
    Ratsitorahina, Maherisoa
    Baril, Laurence
    Keim, Paul
    Caro, Valerie
    Rasolofo, Voahangy
    Spiegel, Andre
    Pizarro-Cerda, Javier
    Wagner, David M.
    Rajerison, Minoarisoa
    EMERGING INFECTIOUS DISEASES, 2024, 30 (02) : 289 - 298
12345