http://orcid.org/0000-0003-0968-400X
Figures
Abstract
The Qinghai-Tibet plateau is a natural plague focus and is the largest such focus in China. In this area, while Marmota himalayana is the primary host, a total of 18 human plague outbreaks associated with Tibetan sheep (78 cases with 47 deaths) have been reported on the Qinghai-Tibet plateau since 1956. All of the index infectious cases had an exposure history of slaughtering or skinning diseased or dead Tibetan sheep. In this study, we sequenced and compared 38 strains of Yersinia pestis isolated from different hosts, including humans, Tibetan sheep, and M. himalayana. Phylogenetic relationships were reconstructed based on genome-wide single-nucleotide polymorphisms identified from our isolates and reference strains. The phylogenetic relationships illustrated in our study, together with the finding that the Tibetan sheep plague clearly lagged behind the M. himalayana plague, and a previous study that identified the Tibetan sheep as a plague reservoir with high susceptibility and moderate sensitivity, indicated that the human plague was transmitted from Tibetan sheep, while the Tibetan sheep plague originated from marmots. Tibetan sheep may encounter this infection by contact with dead rodents or through being bitten by fleas originating from M. himalayana during local epizootics.
Author summary
Plague is mainly a disease of wild rodents, and their parasitic fleas are considered the transmitting vectors. However, human plague originating from Ovis aries (Tibetan sheep) is found in the Qinghai-Tibet plateau in China, where Marmota. himalayana is the primary plague host. Tibetan sheep-related human plague infection is always associated with slaughtering or skinning diseased or dead Tibetan sheep. The plague in Tibetan sheep clearly lags that in M. himalayana. In this study, we performed a genome-wide single nucleotide polymorphism analysis of Tibetan sheep-related plague events, including pathogens isolated from humans, Tibetan sheep, and marmots. Through genomic analysis, together with the epidemiological connections, we confirmed that human plague came from Tibetan sheep, and the Tibetan sheep plague originated from marmots. Tibetan sheep account for about 1/3 of the total number of sheep in China. Tibetan sheep and goats are important domestic livestock on the Qinghai-Tibet plateau. Therefore, the hazards of Tibetan sheep plague should not be underestimated.
Citation: Dai R, Wei B, Xiong H, Yang X, Peng Y, He J, et al. (2018) Human plague associated with Tibetan sheep originates in marmots. PLoS Negl Trop Dis 12(8): e0006635. https://doi.org/10.1371/journal.pntd.0006635
Editor: Didier Raoult, Faculté de Médecine,Aix-Marseille Université, FRANCE
Received: April 21, 2018; Accepted: June 25, 2018; Published: August 16, 2018
Copyright: © 2018 Dai et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: This work was supported by grants from the National Natural Science Foundation of China (81260438 and 81290340), a Provincial Applied Basic Research Project of Qinghai (2016-ZJ-789), and a National Priority Development Project on Key Science Instruments (2012YQ09019706). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Plague is an acute infectious disease caused by Yersinia pestis that killed millions of people in Europe in the 14th century and tens of thousands in China in the 19th century [1]. Plague is mainly a disease of wild rodents, and their parasitic fleas are considered the transmitting vectors. So far, four subspecies of Y. pestis have been recognized on the basis of their biochemical properties: Y. pestis antiqua, mediaevalis, orientalis, and pestoides (microtus) [2,3]. To date, at least 12 plague foci covering >1.4 million km2 have been identified in China [4]; the largest focus is the Marmota himalayana focus on the Qinghai-Tibet plateau in northwestern China. The overwhelming majority of Y. pestis pathogens on the Qinghai-Tibet plateau are biovar antiqua, with the exception of biovar microtus (qinghaiensis) in the Microtus fuscus focus, which is located in Chengduo county in Qinghai Province and in Shiqu county in Sichuan Province [4].
The Qinghai-Tibet plateau is the highest risk area for human plague in China and M. himalayana is the primary host in this area. The pathogen Y. pestis (biovar antiqua) in the Qinghai-Tibet plateau M. himalayana natural plague focus frequently causes pneumonic and septicemic plague with high mortality. Other rodents (Allactaga sibirica, Mus musculus, Cricetulus migratorius, Microtus oeconomus, and Ochotona daurica), some wild animals (foxes, lynxes, and badgers), and domestic animals (sheep, cats, and dogs) have been found to be infected by Y. pestis [5]. Human plague originating from Ovis aries (Tibetan sheep) was first reported in 1956 in Qinghai Province [5], though no bacterial evidence was obtained at that time. Tibetan sheep account for ~1/3 of the total number of sheep in China [6]. And the distribution areas of Tibetan sheep plague broadly overlap with the habitat of marmots in the Qinghai-Tibet plateau M. himalayana plague focus [6,7]. In August 1975, a patient suffered from plague after butchering a dead Tibetan sheep in Yushu Prefecture, Qinghai Province. The meat of the sheep was eaten by 10 people; two individuals suffered intestinal plague that then developed into pneumonic plague, and one died [5]. Three Y. pestis strains were isolated from the dead individual, Tibetan sheep, and Capra aegagrus hircus (Tibetan goat). This incident was the first time that human plague associated with Tibetan sheep or Tibetan goats was confirmed with bacteriological evidence in China [5]. In this study, we report human plague cases associated with Tibetan sheep on the Qinghai-Tibet plateau since the 1950s. Meanwhile, to further determine the ecological function of Tibetan sheep in Y. pestis endemic epidemics, we performed a genome-wide single nucleotide polymorphism (SNP) analysis of Tibetan sheep-related plague events, including pathogens isolated from humans, Tibetan sheep, and marmots. The genome-wide SNP analysis confirmed that the human plague strains were transmitted from Tibetan sheep, while the Tibetan sheep plague strains originated from marmots.
Materials and methods
Ethics statement
This study was approved by the Ethics Committee of the Qinghai Institute for Endemic Disease Control and Prevention (FLW2013-001) and the Institute for Communicable Disease Control and Prevention (ACUC2013-002). All animal plague surveillance procedures were performed in accordance with the National Regulations for the Administration of Affairs Concerning Experimental Animals approved by the State Council. All procedures were in accordance with the ethical standards of the National Research Committee.
Isolation and identification of Y. pestis
Y. pestis was isolated and identified by Gram staining, the reverse indirect hemagglutination assay, and the bacteriophage lysis test. All Y. pestis strains isolated from Tibetan sheep (15) or humans (7) associated with Tibetan sheep on the Qinghai-Tibet plateau were included (S1 Fig and S2 Table). The 18 outbreaks of human infection were designated from A to R (Fig 1 and S1 Table). The Tibetan sheep involved in human plague outbreaks based on epidemiological investigations were designated using the same alphabetic code (see S1 Table). In addition, 14 Y. pestis strains isolated from M. himalayana were selected; whenever possible, they were from the same region as the Tibetan sheep and in the same year in order to match the isolates from Tibetan sheep plague and human plague. Furthermore, two Y. pestis strains isolated from patients infected by M. himalayana in Nangqian County (2004) were also included [7]. All the strains were collected from the Qinghai Institute for Endemic Disease Control and Prevention, Xining, China. In addition, we plotted the geographical distribution of human plague, Tibetan sheep plague, and the isolates involved on a satellite map sourced from the Institute of Geographical Sciences and Natural Resources Research, Chinese Academy of Sciences, and we have received permission to publish it under a CC BY license from the institute.
DNA preparation
A total of 38 Y. pestis strains isolated from Tibetan sheep or humans or M. himalayana were included in this study. Genomic DNA from each bacterium was extracted using the following method in a Biosafety Level 3 Laboratory of the Qinghai Institute for Endemic Disease Control and Prevention. Y. pestis strains were cultivated in Luria–Bertani broth at 28°C for 48 h, and the collected strains were suspended in 0.5 ml of TE buffer (10.0 mM Tris-HCl [pH 8], 1.0 mM EDTA) and incubated at 28°C for 20 min, Then 80 μl of 10% SDS was added to the preparation (10 μg in 1 ml PBS), and maintained at 65°C for 10 min. Next, 20 μl RNase (10 mg/ml) was added, and the solution incubated at 37°C for 2 h. Following the addition of 10 μl of proteinase K, the preparation was incubated at 37°C for 2 h. The DNA was extracted twice with equal volumes of phenol and once with an equal volume of chloroform. The DNA was precipitated by adding two volumes of absolute ethanol. The precipitated DNA was washed with 70% ethanol and re-suspended in TE buffer (pH 8.0).
Genome sequencing and SNP analysis
The 38 isolates were sequenced using the Illumina HiSeq 2000 platform (Illumina, San Diego, CA). Two paired-end libraries were constructed with average insertion lengths of 500 bp and 3,000 bp. The raw data were filtered by FastQC, and then the clean data were assembled into contigs using SPAdes v3.9.1. Gene prediction was performed using Glimmer with the default parameters. The whole-genome raw SNPs were detected through pairwise comparisons of Y. pestis genomes to the reference genome of the Angola strain (NC_010159) [8] using Bowtie 2 software [9] and MUMmer [10] with the default parameters. Twenty-one completed genomes or draft genomes obtained from the NCBI database were also included in the analysis [1,11–17] (S2 Table). Then the SNPs were combined, and those of low quality (read depth <5) and those located within 5 bp on the same chromosome were removed to avoid the effect of recombination. A phylogenetic tree of Y. pestis was established based on these SNPs with the Bayesian evolutionary method in BEAST software [18] using the 38 Y. pestis genomes from our study and the 21 genome sequences of Y. pestis from GenBank and rooted with Y. pseudotuberculosis (IP32953) [1,13].
Results
Human plague associated with Tibetan sheep on the Qinghai-Tibet plateau
According to the epidemic history of plague on the Qinghai-Tibet plateau and the annual national plague surveillance data in China, a total of 18 human outbreaks (events, designated A to R) associated with Tibetan sheep have occurred since 1956 (S1 Table and S1 Fig). Among these events, a total of 78 human cases associated with Tibetan sheep (cases of original infection and successive secondary generation) and 47 deaths were reported, of which 70 cases and 42 deaths occurred in Qinghai. In addition, 8 human cases (5 deaths) associated with Tibetan sheep occurred in Tibet. All index infectious cases had an exposure history of butchering or skinning diseased or dead Tibetan sheep. Massive deaths or larger numbers of infection cases mainly occurred in four events before 1975; for example in 1956, the index case (Tianjun county) suffered pneumonic plague and died after skinning a dead Tibetan sheep, and this individual infected a total of 13 individuals of whom 11 died. Eating meat from infected sheep that is not fully cooked is another cause of human plague infection, such as those in 1961 (Dulan county), 1963 (Yushu county), and 1965 (Zhaduo county), that caused 26 cases of infection due to eating the meat; only the index individual in each outbreak slaughtered or skinned a diseased or dead Tibetan sheep.
Considering the months in which Tibetan sheep plague, M. himalayana plague, and human plague events have occurred on the plateau since 1956, 14 of the 27 Tibetan sheep plague events occurred during October and November. In contrast, the peak occurrence of M. himalayana plague was during June and July and usually ended in October (National Plague Surveillance data and reference [5]). The plague in Tibetan sheep clearly lagged that in M. himalayana (Wilcoxon signed rank test, P <0.05). In addition, 9 of the 18 human plague events in which the index case(s) originated from Tibetan sheep occurred during October and November, while the peak months of human plague originating from M. himalayana were during August and September [5] (Fig 1). From 1997 to 2016, no human plague cases were caused by Tibetan sheep due to active prevention and intervention measures in Qinghai, even though Y. pestis was still isolated from local Tibetan sheep and Tibetan goats on the Qinghai-Tibet plateau.
Identification of SNPs and the phylogenetic relationships of Y. pestis
The genomic sequences of the 38 isolates of Y. pestis were assembled de novo, producing 52 contigs and 70 scaffolds on average. The number of genes per strain ranged from 2,623 to 2,990. The phylogenetic tree of Y. pestis was established using all isolates in our study as well as 21 complete genomes or draft genome sequences from the NCBI GenBank database (S2 Table). We identified 1663 high-quality SNPs compared with the reference genomes and 216 within our isolates, with 39–63 SNPs per genome. Among these SNPs, 149 were located in 143 genes, including 41 synonymous SNPs and 108 nonsynonymous SNPs, with 1–2 in each gene, whereas the remaining 67 SNPs were located in intergenic regions. The 108 nonsynonymous sites were distributed among 106 genes.
The phylogenetic relationships we constructed (Fig 2A) were very similar to the genomic maximum parsimony tree reported previously [1]. The nomenclature of the lineages in the phylogenetic tree are according to the literature [1,19]. The pathogens associated with Tibetan sheep plague were clustered into the 1.IN2 lineage in the phylogenetic tree. These strains were comparatively closer to Y. pestis Z176003, which was isolated from M. himalayana in Naqu County, Tibet, in 1976 [11]. In addition, strains H21 and H22 (human plague isolates originating from M. himalayana in Bangqian Village, Nangqian County in 2004) were clustered in 2.ANT1.
Phylogenetic relationships and population structure were determined by Bayesian evolutionary analysis based on genomic SNPs. Lower left (A): phylogenetic tree of Y. pestis yielded by genome-wide SNPs in 38 Y. pestis from our study and 21 genomic sequences of Y. pestis from GenBank, rooted in Y. pseudotuberculosis (IP32953). Black text: names of genomic sequences (S2 Table); colored text: branch and population names. Strains isolated from Tibetan sheep or associated human plague cases as well as a panel of isolates from M. himalayana are marked in red. Right (B): reconstruction of the population structure of 36 Y. pestis in the 1.IN2 lineage from the SNP assignments.
Population structure of Y. pestis isolates associated with Tibetan sheep
Y. pestis isolated from Tibetan sheep or local M. himalayana all fermented glycerin and reduced nitrate to nitrite, i.e., they belonged to biovar antique, the same as human plague in this focus. Combining the epidemiological information (S1 Table and S2 Table) and the population structure based on the genome-wide SNP analysis, we divided the 36 Y. pestis in the 1.IN2 lineage (including those originating from Tibetan sheep (15) and humans (7) associated with Tibetan sheep, as well as 14 Y. pestis strains isolated from M. himalayana) into four clusters (I–IV), corresponding to eight clades (1–8) (Fig 2B). Generally, the clade-based classification agreed well with the geographical area, i.e., the strains isolated from the same area were found in the same clade (Fig 2B). In fact, where no geographic barrier existed between adjacent areas, the pathogens isolated from adjacent areas also grouped together; for example, Juela Village in Nangqian County and Xialaxiu Village in Yushu are adjacent, and the strains isolated from the two villages grouped into Clade-1; Shanglaxiu, Batang, and Guoqing Villages are neighbors, and the lineages were grouped in Clade-4. This shows that the genomic phylogenetic analysis of the Tibetan sheep-related strains have territory-specific characteristics.
In addition, in Clade-1 and Clade-4, the strains isolated in different years were grouped together. For example, the human plague cases and those corresponding to Tibetan sheep plague occurring in 1979 (in Xialaxiu Village, Yushu County) and in 1997 (in Juela Village, Nangqian County) were grouped together into Clade-1. In 1975, in Yushu County, the first human plague associated with Tibetan sheep was confirmed by bacteriological evidence. However, in 2005 in Yushu County, a larger-scale Tibetan sheep plague occurred, in which a total of 13 Tibetan sheep and 1 Tibetan goat in the same flock died. The isolates from these two events were grouped into Clade-4. This indicated that the same strains of Y. pestis successively caused Tibetan sheep or human plague outbreaks in these areas. Of course, some isolates could not be grouped together by event although the strains were isolated in the same area, such as lineages M8 and S20. In fact, finding any clear epidemiological connection between these two isolates and the rest was difficult. One possible explanation is the genomic diversity of the strains in these foci.
Phylogenetic relationships among isolates from patients, Tibetan sheep, and marmots
In Clade-1, the Y. pestis isolated from patients (H19) and Tibetan sheep (S30 and S24) in Juela Village, Nangqian County in 1997, as well as isolates from M. himalayana (M39), were grouped together. According to the epidemiological information, the diseased herdsman (H19) suffered pneumonic plague after processing a dead Tibetan sheep (S24), and isolate S30 was obtained from a sheep in the same breeding herd as the dead sheep (S24). In addition, one strain (M39) from a dead M. himalayana in a sheep grazing area had been isolated four months earlier. In fact, a raging animal plague epidemic had occurred one year previously (in 1996) in Juela Village, and a total of three strains (M18, M32, and M38) were collected in the area (National Plague Surveillance data). The above isolates were grouped together in Clade-1. Two strains (S31 and S23) isolated from Tibetan sheep in Xialaxiu Village, Yushu County (adjacent to Nangqian County) also grouped into Clade-1. Furthermore, the strain (H5) from the human plague in 1979, the corresponding Tibetan sheep strains (S6 and S7), and some strains isolated from M. himalayana also clustered into Clade-1.
As noted above, in 2005, three Y. pestis isolates (S11, G12, and S13) were identified in two Tibetan sheep and one Tibetan goat from an outbreak of Tibetan sheep plague in Guoqing Village, Yushu. The Y. pestis isolated from the dead M. himalayana found in the same village and in the same year (2005) were clustered into the same clade (Clade-4). In fact, it was in Shanglaxiu Village, Yushu County, that the first human plague case associated with Tibetan sheep was confirmed in 1975. In addition, three Y. pestis strains isolated from dead patients and Tibetan sheep and Tibetan goats in the same herd were also clustered in Clade-4. Similar clustering of Tibetan sheep and M. himalayana was also found in Zongwulong Village, Delingha County, in 1996 (Clade-5). The above findings, together with the epidemiological connections, support the conclusion that human plague came from Tibetan sheep and Tibetan sheep plague originated from marmots.
Discussion
Human plague associated with Tibetan sheep plague in Qinghai
The Qinghai M. himalayana natural plague focus was first identified in 1954 as a result of the isolation of Y. pestis from a dead marmot in Qinghai Province [20]. M. himalayana is the primary plague host in this area [5]. According to plague surveillance data in Qinhai Province, a total of 468 human plague cases with 240 deaths were reported, of which 162 cases originated from M. himalayana (34.62%), 39 from Tibetan sheep (8.33%), 16 from carnivorous animals (3.42%), and 216 from successive infection of pneumonic plague by person-to-person transmission (46.15%)[5]. Tibetan sheep plague was sporadic on the Qinghai-Tibet plateau, and was restricted to areas that had M. himalayana plague epidemics. One previous investigation in Yushu Prefecture in 2005 found that the infection rate of Y. pestis in Tibetan sheep was 6.08% (64/1051) with serum titers in the range of 1:20 to 1:1280 [7]. Tibetan sheep-related human plague infection is always associated with slaughtering or skinning diseased or dead Tibetan sheep. Eating incompletely cooked meat from infected sheep or goats is another cause of human infection [5]. In previously research, the incidence of Tibetan sheep-related human plague outbreaks occurring in Qinghai Province between 1975–2009 were counted, and a total of 10 Tibetan sheep-related human plague outbreaks occurred during this period, resulting in 25 cases and 10 deaths, including bubonic plague (9), primary pneumonic plague (6), secondary pneumonic plague (6), septicemic plague (3), and intestinal plague(1) [2,3].
Tibetan sheep infection from marmots
The even-toed ungulates (Artiodactyla), including camels and goats [21–24], donkeys, and cows [25], can be naturally infected by Y. pestis. Previous studies have shown that the sheep is a plague reservoir with high susceptibility and moderate sensitivity [26,27]. And, under natural circumstances, only individual Tibetan sheep in a flock are infected, and they do not become infected directly by sheep-to-sheep contact, even when the same flock contains a mixture of sick and healthy sheep [26]. These findings indicate that the ecological function of the Tibetan sheep in associated human plague should be considered as an intermediate or accidental host.
Another piece of supporting evidence is the fact that the occurrence of Tibetan sheep plague during the year lags behind the occurrence of M. himalayana plague. October and November were the high incidence months for the Tibetan sheep plague and human plague originated from Tibetan sheep. On the Qinghai-Tibet plateau, marmots begin hibernation from October to early November. One possible reason is that the fleas living in the caves escape after the marmots enter hibernation in October and attack other animals, such as Tibetan sheep. A minor peak for the human plague associated with Tibetan sheep occurs in June to July and presumably is caused by the massive death of marmots. Such an ecological change could also result in more fleas escaping from dead hosts and colonizing Tibetan sheep or human beings.
Several possible scenarios may explain how Tibetan sheep become infected by marmots. First, they could be infected by contact with the bodies of dead marmots. Our field observations showed that Tibetan sheep have a habit of licking the bodies of dead rodents such as marmots, which may be a means of ingesting micronutrients in the plateau environment. Previously, a study successfully induced plague infection by feeding or smearing Y. pestis in the mouths of Tibetan sheep [27]. Another possible cause is that Tibetan sheep could be infected by fleas such as Callopsylla dolabris or Oropsylla silantiewi. These are the main parasitic fleas in M. himalayana. Even though they have comparatively specific host selection, they have been found to attack human beings or other animals after the death of their preferred host [6]. Previous research has shown that C. dolabris and O. silantiewi bite and can suck the blood of Tibetan sheep in the laboratory, and the sheep can become infected and die after being challenged for 10 days [27]. The above evidence shows that fleas play an important role in Y. pestis transmission from marmots to Tibetan sheep.
Through genomic analysis, we confirmed that human plague came from Tibetan sheep, and Tibetan sheep plague originated from marmots. To the best of our knowledge, natural infection of sheep with Y. pestis is rare elsewhere in the world. The Tibetan sheep plague epizootic has some novel features, such as a complex transmission route, an extended epizootic period, and the possibility of transmission across long distances. Therefore, the hazards of Tibetan sheep plague should not be underestimated.
Supporting information
S1 Fig. Distribution of human plague associated with Tibetan sheep on the Qinghai-Tibet plateau.
Yellow squares: 18 human plague outbreak events associated with sheep on the plateau since 1956. Numbers in brackets: number of human cases (including original infection and cases of successive secondary generation) followed by the number of deaths per event; red dots: areas of occurrence of human plague associated with sheep and the strains involved in this study. Lower left: location of the Qinghai-Tibet plateau; upper left: a Tibetan sheep (female). The satellite figure sourced from the Institute of Geographical Sciences and Natural Resources Research, Chinese Academy of Sciences, and we have received permission to publish this figure under a CC BY license from the institute.
https://doi.org/10.1371/journal.pntd.0006635.s001
(JPG)
S1 Table.
Human plague associated with Tibetan sheep on the Qinghai-Tibet plateau, 1956–2016.
https://doi.org/10.1371/journal.pntd.0006635.s002
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S2 Table. Y. pestis and corresponding animal or human plague outbreaks in this study.
https://doi.org/10.1371/journal.pntd.0006635.s003
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S3 Table. SNPs detected in the sequenced Y. pestis strain.
https://doi.org/10.1371/journal.pntd.0006635.s004
(XLSX)
Acknowledgments
We thank Mrs. YiXian Chen from the Institute of Geographical Sciences and Natural Resources Research, Chinese Academy of Sciences, for help with geographic information. We are also grateful to all the participants in natural plague surveillance, especially the Base of Plague and Brucella in the China CDC, Yunnan Institute for Endemic Diseases Prevention and Control, as well as the Center for Disease Control and Prevention of Tibet Autonomous Region, Xinjiang Uygur Autonomous Region, Sichuan Province.
References
- 1. Morelli G, Song Y, Mazzoni CJ, Eppinger M, Roumagnac P, Wagner DM, Feldkamp M, Kusecek B, Vogler AJ, Li Y, Cui Y, Thomson NR,Jombart T, Leblois R, Lichtner P, Rahalison L, Petersen JM, Balloux F, Keim P, Wirth T, Ravel J, Yang R, Carniel E, Achtman M. Yersinia pestis genome sequencing identifies patterns of global phylogenetic diversity. Nat Genet. 2010. 42(12):1140–3. pmid:21037571
- 2. Anisimov AP, Lindler LE, Pier GB. Intraspecific diversity of Yersinia pestis. Clin Microbiol Rev. 2004 Apr;17(2):434–64. Review. Erratum in: Clin Microbiol Rev. 2004 Jul;17(3):695. PubMed Central PMCID: PMC387406. pmid:15084509
- 3. Zhou D, Tong Z, Song Y, Han Y, Pei D, Pang X, Zhai J, Li M, Cui B, Qi Z, Jin L, Dai R, Du Z, Wang J, Guo Z, Wang J, Huang P, Yang R. Genetics of metabolic variations between Yersinia pestis biovars and the proposal of a new biovar, microtus. J Bacteriol. 2004 Aug;186(15):5147–52. pmid:15262951; PubMed Central PMCID: PMC451627.
- 4. Cui Y, Li Y, Gorgé O, Platonov ME, Yan Y, Guo Z, Pourcel C, Dentovskaya SV,Balakhonov SV, Wang X, Song Y, Anisimov AP, Vergnaud G, Yang R. Insight into microevolution of Yersinia pestis by clustered regularly interspaced short palindromic repeats. PLoS One. 2008;3: e2652. pmid:18612419
- 5. Wang ZY, Cui BZ, Qi ZZ, Chen HJ, Wei RJ. Plague in Qinghai, 2016. (in Chinese)
- 6. Wang ZY. The control policy of Tibetan sheep plague in Qinghai. Chinese Journal of Zoonoses 1999, 15: (6) 95,106. (in Chinese)
- 7. Wei BQ, Xiong HM, Yang XY, Yang YH, Qi MY, Jin J, Xin YQ, Li X, Yang HQ, Han XM, Dai RX. The epidemiology and etiology research of Tibetan sheep plague in Qinghai plateau Chin J Epidemiol, 2015:36(3): 271–274. (in Chinese)
- 8. Eppinger M, Worsham PL, Nikolich MP, Riley DR, Sebastian Y, Mou S, Achtman M, Lindler LE, Ravel J. Genome sequence of the deep-rooted Yersinia pestis strain Angola reveals new insights into the evolution and pangenome of the plague bacterium. J Bacteriol. 2010 Mar;192(6):1685–99. pmid:20061468
- 9. Li R, Li Y, Fang X, Yang H, Wang J, Kristiansen K, Wang J. 2009. SNP detection for massively parallel whole-genome resequencing. Genome Res. 19:1124–1132. pmid:19420381
- 10. Kurtz S, Phillippy A, Delcher A, Smoot M, Shumway M, Antonescu C, Salzberg SL. 2004. Versatile and open software for comparing large genomes. Genome Biol. 5:R12. pmid:14759262
- 11. Shen X, Wang Q, Xia L, et al.: Complete genome sequences of Yersinia pestis from natural foci in China. J Bacteriol 192: 3551–3552, 2010. pmid:20453098
- 12. Parkhill J, Wren BW, Thomson NR, Titball RW, Holden MT, Prentice MB, Sebaihia M, James KD, Churcher C, Mungall KL, Baker S, Basham D, Bentley SD, Brooks K, Cerdeño-Tárraga AM, Chillingworth T, Cronin A, Davies RM, Davis P, Dougan G, Feltwell T, Hamlin N, Holroyd S, Jagels K, Karlyshev AV, Leather S, Moule S, Oyston PC, Quail M, Rutherford K, Simmonds M, Skelton J, Stevens K, Whitehead S, Barrell BG. Genome sequence of Yersinia pestis, the causative agent of plague. Nature. 2001;413(6855):523–7. pmid:11586360
- 13. Yan Y, Wang H, Li D, Yang X, Wang Z, Qi Z, Zhang Q, Cui B, Guo Z, Yu C, Wang J, Wang J, Liu G, Song Y, Li Y, Cui Y,Yang R. Two-step source tracing strategy of Yersinia pestis and its historical epidemiology in a specific region. PLoS One. 2014. 9;9(1):e85374. pmid:24416399
- 14. Chain PS, Hu P, Malfatti SA, Radnedge L, Larimer F, Vergez LM, Worsham P, Chu MC, Andersen GL. Complete genome sequence of Yersinia pestis strains Antiqua and Nepal516: evidence of gene reduction in an emerging pathogen. J Bacteriol. 2006;188(12):4453–63. pmid:16740952
- 15. Deng W, Burland V, Plunkett G 3rd, Boutin A, Mayhew GF, Liss P, Perna NT, Rose DJ, Mau B, Zhou S, Schwartz DC, Fetherston JD, Lindler LE, Brubaker RR, Plano GV, Straley SC, McDonough KA, Nilles ML, Matson JS, Blattner FR, Perry RD. Genome sequence of Yersinia pestis KIM. J Bacteriol. 2002;184(16):4601–11. pmid:12142430
- 16. Garcia E, Worsham P, Bearden S, Malfatti S, Lang D, Larimer F, Lindler L, Chain P. Pestoides F, an atypical Yersinia pestis strain from the former Soviet Union. Adv Exp Med Biol. 2007;603:17–22. pmid:17966401
- 17. Johnson SL, Daligault HE, Davenport KW, Jaissle J, Frey KG, Ladner JT, Broomall SM, Bishop-Lilly KA, Bruce DC, Coyne SR, Gibbons HS, Lo CC, Munk AC, Rosenzweig CN, Koroleva GI, Palacios GF, Redden CL, Xu Y, Minogue TD, Chain PS. Thirty-Two Complete Genome Assemblies of Nine Yersinia Species, Including Y. pestis, Y. pseudotuberculosis, and Y. enterocolitica. Genome Announc. 2015; 3(2). pii: e00148-15.
- 18. Didelot X, Falush D. 2007. Inference of bacterial microevolution using multilocus sequence data. Genetics 175:1251–1266. pmid:17151252
- 19. Achtman M, Morelli G, Zhu P, Wirth T, Diehl I, Kusecek B, Vogler AJ, Wagner DM, Allender CJ, Easterday WR, Chenal-Francisque V, Worsham P, Thomson NR, Parkhill J, Lindler LE, Carniel E, Keim P. Microevolution and history of the plague bacillus, Yersinia pestis. Proc Natl Acad Sci U S A. 2004 Dec 21;101(51):17837–42. Epub 2004 Dec 14. pmid:15598742; PubMed Central PMCID: PMC535704.
- 20. He J, Xiong HM, Qi MY, et.al. Analysis of epidemics and risk factors of human plague caused by Tibetan sheep in Qinghai Province. Chinese J of Endemiology. 2016; 35: (5). 26–28. (in Chinese)
- 21. Leslie T, Whitehouse CA, Yingst S, Baldwin C, Kakar F, Mofleh J, Hami AS, Mustafa L, Omar F, Ayazi E, Rossi C, Noormal B, Ziar N,Kakar R. Outbreak of gastroenteritis caused by Yersinia pestis in Afghanistan. Epidemiol Infect. 2011;139(5):728–35. pmid:20663260
- 22. Edmunds DR1, Williams ES, O'Toole D, Mills KW, Boerger-Fields AM, Jaeger PT, Bildfell RJ, Dearing P, Cornish TE. Ocular plague (Yersinia pestis) in mule deer (Odocoileus hemionus) from Wyoming and Oregon. J Wildl Dis. 2008; 44(4):983–7. pmid:18957655
- 23. Arbaji A1, Kharabsheh S, Al-Azab S, Al-Kayed M, Amr ZS, Abu Baker M, Chu MC. A 12-case outbreak of pharyngeal plague following the consumption of camel meat, in north-eastern Jordan. Ann Trop Med Parasitol. 2005; 99(8):789–93. pmid:16297292
- 24. Christie AB, Chen TH, Elberg SS. Plague in camels and goats: their role in human epidemics. J Infect Dis. 1980;141(6):724–6. pmid:7391614
- 25. Lien-Teh W, Chun J, Pollitzer R, Wu C. Plague: a manual for medical and public health workers. Am J Public Health Nations Health. 1936;26(10):1049–50.
- 26. Wang WH, Li C. The study of Tibetan sheep plague. Chinese Journal of Endemiology. 2001, 20(6); 467–468. (in Chinese)
- 27. Wang WH, Chen BS, Zhan XR, Liu ZM. Study on susceptibility and sheep to Yersinia pestis. Chinese Journal of zoonoses. 1994;10(6).8–11. (in Chinese)