Jump to content
SARS-CoV2 BA.2.86 Derivative Sequences Map

MERS Recombination First Imported Case in China: Phylogenetics and Coalescence Analysis - mBio

niman

By niman
in MERS

 Share

Recommended Posts

niman Grand Master

niman

Posted
Posted (edited)

Origin and Possible Genetic Recombination of the Middle East Respiratory Syndrome Coronavirus from the First Imported Case in China: Phylogenetics and Coalescence Analysis

  1. Wenjie Tana

+Author Affiliations

  1. aKey Laboratory of Medical Virology, Ministry of Health, National Institute for Viral Disease Control and Prevention, Chinese Center for Disease Control and Prevention, Beijing, China
  2. bCAS Key Laboratory of Pathogenic Microbiology and Immunology, Institute of Microbiology, Chinese Academy of Sciences, Beijing, China
  3. cNetwork Information Center, Institute of Microbiology, Chinese Academy of Sciences, Beijing, China
  4. dInstitute of Pathogen Biology, Taishan Medical College, Taian, China
  5. eState Key Laboratory of Pathogen and Biosecurity, Beijing, China
  6. fOffice of Director-General, Chinese Center for Disease Control and Prevention, Beijing, China
  1. Address correspondence to George F. Gao, [email protected], or Wenjie Tan,[email protected].

  1. Yanqun Wang, Di Liu, Weifeng Shi, and Roujian Lu contributed equally to this work.

  2. Editor Michael J. Buchmeier, University of California, Irvine

http://mbio.asm.org/content/6/5/e01280-15

FOOTNOTES

  • Citation Wang Y, Liu D, Shi W, Lu R, Wang W, Zhao Y, Deng Y, Zhou W, Ren H, Wu J, Wang Y, Wu G, Gao GF, Tan W. 2015. Origin and possible genetic recombination of the Middle East respiratory syndrome coronavirus from the first imported case in China: phylogenetics and coalescence analysis. mBio 6(5):e01280-15. doi:10.1128/mBio.01280-15.

  • This article is a direct contribution from a Fellow of the American Academy of Microbiology.

  • Received 28 July 2015 
  • Accepted 30 July 2015 
  • Published 8 September 2015
Edited by niman
Link to comment
Share on other sites
niman Grand Master

niman

Posted
  • Author
Posted (edited)

ABSTRACT

The Middle East respiratory syndrome coronavirus (MERS-CoV) causes a severe acute respiratory tract infection with a high fatality rate in humans. Coronaviruses are capable of infecting multiple species and can evolve rapidly through recombination events. Here, we report the complete genomic sequence analysis of a MERS-CoV strain imported to China from South Korea. The imported virus, provisionally named ChinaGD01, belongs to group 3 in clade B in the whole-genome phylogenetic tree and also has a similar tree topology structure in the open reading frame 1a and -b (ORF1ab) gene segment but clusters with group 5 of clade B in the tree constructed using the S gene. Genetic recombination analysis and lineage-specific single-nucleotide polymorphism (SNP) comparison suggest that the imported virus is a recombinant comprising group 3 and group 5 elements. The time-resolved phylogenetic estimation indicates that the recombination event likely occurred in the second half of 2014. Genetic recombination events between group 3 and group 5 of clade B may have implications for the transmissibility of the virus.

 

Edited by niman
Link to comment
Share on other sites
niman Grand Master

niman

Posted
  • Author
Posted

IMPORTANCE

The recent outbreak of MERS-CoV in South Korea has attracted global media attention due to the speed of spread and onward transmission. Here, we present the complete genome of the first imported MERS-CoV case in China and demonstrate genetic recombination events between group 3 and group 5 of clade B that may have implications for the transmissibility of MERS-CoV.

Link to comment
Share on other sites
niman Grand Master

niman

Posted
  • Author
Posted

INTRODUCTION

Middle East respiratory syndrome coronavirus (MERS-CoV), first detected in the Kingdom of Saudi Arabia (KSA) in 2012, causes severe acute respiratory tract infection in humans, with a high case fatality rate (CFR) (14). Dromedary camels are believed to be important reservoir hosts or vectors for human infection; bats may also be implicated (58). As of 17 July 2015, 1,368 laboratory-confirmed cases of human infection with MERS-CoV had been reported to the World Health Organization (WHO), including at least 490 deaths, corresponding to a CFR as high as 35.45% (9). Recent MERS clusters in South Korea are thought to be the largest outbreak outside the Middle East countries (10). As of 25 July 2015, 186 laboratory-confirmed cases of MERS-CoV infection have been confirmed (including 36 deaths) in South Korea (9). A South Korean man who was a relative of some of the laboratory-confirmed cases traveled to Guangdong Province (10) and was diagnosed as the first imported MERS-CoV case in China by molecular detection of MERS-CoV (1112). The rapid spread of disease in South Korea raised concerns that the imported virus had evolved to become more transmissible. Here, we report a comprehensive phylogenetic analysis of the complete MERS-CoV genome sequence of the first Chinese imported case of MERS (ChinaGD01), and the results indicate its probable origin and show evidence of genetic recombination.

Link to comment
Share on other sites
niman Grand Master

niman

Posted
  • Author
Posted

RESULTS

Patient and sample history.The current outbreak in South Korea and China was initiated when a 68-year-old Korean man flew back to Seoul on 4 May 2015 after a visit to four Middle East countries (Bahrain, United Arab Emirates, Saudi Arabia, and Qatar). On 26 May 2015, a 44-year-old South Korean man presented with fever to a hospital in Guangdong. He was in close contact with the index patient in South Korea on 16 May 2015 (Fig. 1), as well as a suspected second-generation patient. The timeline of the travel history, potential virus exposure, onset of disease, and diagnosis of the first imported MERS-CoV case in China are presented in Fig. 1.

FIG 1 
View larger version:
FIG 1 

Timeline of the travel history, potential virus exposure, onset of disease, and diagnosis of the first imported MERS-CoV case in China. UAE, United Arab Emirates; KSA, Kingdom of Saudi Arabia.

 

Characterization of genome.With informed consent and the approval of the ethical committee of the National Institute of Viral Disease Control and Prevention, China Center for Disease Control and Prevention (CDC), nasopharyngeal swabs were collected and used for RNA extraction, followed by reverse transcription PCR and genome sequencing. Through both Sanger and Ion Torrent sequencing, the full-length virus genome (30,144 bp) of ChinaGD01 was obtained and deposited in GenBank (accession no. KT006149). Over 2,000,000 paired-end reads were quality trimmed and processed to remove human genome sequences. Nonhuman reads were assembled into contigs by CLC Genomic Workbench and aligned against representative sequences of MERS-CoV. No nucleotide insertions or deletions were observed in the genome.

The genome sequence of this virus, referred to as ChinaGD01, had high levels of nucleotide identity (99.33% to 99.79%) to previously published MERS-CoV genomes (Fig. 2), with 99.31% to 99.78% sequence identity in the open reading frame 1a and -b (ORF1ab) gene segment and 98.91% to 99.60% identity in the S gene. The E, M, and N genes had 98.93% to 100% identity with previously described MERS-CoV strains. In total, ChinaGD01 possessed 11 nonsynonymous nucleotide substitutions (Table 1), which occurred in the ORF1ab (n = 8), ORF3 (n = 1), ORF4b (n = 1), and M (n = 1) genes, respectively (Table 1). Although there were five nucleotide substitutions in the S gene, no amino acid change was discovered. Of note, in comparison with previously published MERS-CoV genomes, the ChinaGD01 genome shows 11 unique amino acid substitutions, and 8 of them were shared with the newly released South Korean strains and the latest strains prevalent in Saudi Arabia (Table 1).

FIG 2 
View larger version:
FIG 2 

Phylogenetic relationships based on complete genomes (A), ORF1ab genes (B), and S genes (C) of MERS-CoV strains. China’s first imported MERS-CoV strain (GenBank accession no. KT006149.2), South Korea’s first MERS-CoV strain (GenBank accession no.KT029139), and the latest MERS-CoV strains prevalent in the Middle East (GenBank accession no. KT026453 to KT026456) are indicated in red. The MERS-CoV strains derived from camels are indicated in blue. All of the complete genomes were analyzed by nucleotide sequence alignment using the maximum-likelihood method implemented in the RAxML. Numbers at the nodes indicate bootstrap support for each node (percentage of 1,000 bootstrap replicates). Scale bars indicate the expected number of nucleotide substitutions per site.

 
View this table:
TABLE 1 

Comparison of sites of variation between gene sequences of ChinaGD01, the first South Korean strain, the latest Saudi Arabia strains, and other MERS-CoV strainsa

 

Phylogenetic analysis.To further investigate the genetic relationship between ChinaGD01 and other MERS-CoV strains whose genomes are available, we performed phylogenetic analyses using the complete genome, the ORF1ab gene, and the S gene. From the whole-genome phylogeny, all available MERS-CoV strains can be clustered into two clades, the earlier clade A and the more recent clade B (Fig. 2A). ChinaGD01 fell into group 3 of clade B (Fig. 2A). Within group 3, ChinaGD01 and the South Korean and Saudi Arabian strains from 2015 were closely clustered and formed a long branch, separate from others of group 3. The nearest strain to this branch was Hafr-Al-Batin-1-2013 (GenBank accession no.KF600628), isolated in August 2013. Phylogenetic analysis of the ORF1ab gene indicated a similar topology in which ChinaGD01 and the recent MERS-CoV strains identified in South Korea were closely adjacent to Hafr-Al-Batin-1-2013 in group 3 (Fig. 2B). However, the phylogeny of the S gene differed in that the new viruses fell into group 5 and were closely related to viruses from both humans and dromedaries (Fig. 2C). These findings are consistent with recombination, a phenomenon not uncommon in coronaviruses.

Genetic recombination analysis.To examine whether genetic recombination has occurred in ChinaGD01, we performed bootscanning analyses. We compared ChinaGD01 with representative viruses from group 3 (Hafr-Al-Batin-1-2013; GenBank accession no. KF600628), group 5 (KSA-CAMEL-378; GenBank accession no. KJ713296), and group 1 (Abu Dhabi_UAE_9_2013; GenBank accession no.KP209312) as controls. As shown in Fig. 3A, ChinaGD01 was more similar to the group 3 strain from position 1 to 15,000 and more similar to the group 5 strain from approximately position 18,000 to 24,000. We then compared the single-nucleotide polymorphisms (SNPs) of ChinaGD01 with consensus sequences of group 3 and group 5 (Fig. 3B; see also Fig. S1 and S2 in the supplemental material). There were 78 SNPs discovered along the ChinaGD01 genome (Fig. 3B). Whereas before position 17,206, ChinaGD01’s SNP pattern is nearly identical to that of the group 3 viruses, its SNP pattern is more similar to that of group 5 viruses between positions 17,311 and 23,804. The consistency in the results of bootscanning and SNP analyses supports the hypothesis that the gene segment from approximately position 17,300 to 24,000, representing portions of the ORF1ab and S genes, reflects a recombination event (Fig. 3B).

FIG 3 
View larger version:
FIG 3 

Recombination analyses of complete MERS-CoV genomes. (A) Bootscanning analysis of MERS-CoV genome. The ChinaGD01 strain was used as a query sequence and compared with one strain from group 3 (GenBank accession no.KF600628.1), one from group 5 (GenBank accession no.KJ713296.1), and one from group 1 (GenBank accession no.KP209312.1). (B) Single-nucleotide differences between the ChinaGD01 sequence and consensus sequences of group 3 and group 5. Group 3 cons, consensus sequences of group 3 strains; group 5 cons, consensus sequences of group 5 strains; South Korea, first MERS-CoV strain (GenBank accession no. KT029139) in South Korea; KSA-2015, latest strains prevalent in Saudi Arabia (GenBank accession no. KT026453 to KT026456), Bisha-1/2012, an earlier strain used as a control.

 

Phylogenetic analysis was further performed using BEAST with the complete genome, the nonrecombinant region (positions 1 to 17,300), and the potential recombinant region (positions 17,301 to 24,000), respectively (Fig. 4). The phylogenies revealed by the BEAST trees were consistent with those from the maximum-likelihood trees. In the trees constructed using the complete genome and the nonrecombinant region, ChinaGD01 fell within group 3; however, trees constructed using the recombinant region clustered with the group 5 sequences.

FIG 4 
View larger version:
FIG 4 

Time-resolved phylogenetic analyses of complete genomes (A), nonrecombination regions (B), and recombination regions (C) of MERS-CoV strains using BEAST. The nonrecombination region is approximately bp 1 to 17,300, and the recombination region is approximately bp 17,301 to 24,000. ChinaGD01 (GenBank accession no. KT006149), South Korea’s first MERS-CoV strain (GenBank accession no. KT029139), and the latest strains prevalent in Saudi Arabia (GenBank accession no. KT026453 toKT026456) are indicated in red.

 

To date the recombination event, we estimated the time to most recent common ancestor for the novel MERS-CoV from 2015. Although there was a slight difference among results from different models, the time to most recent common ancestor of the 2015 cluster was estimated to be between 0.5 and 0.7 years before the identification of the imported case in the latter months of 2014 (Table 2). Given the observation of similar recombination events in the newly released South Korean strains and the latest strains prevalent in Saudi Arabia, the travel histories of patients, and potential opportunities for virus exposure, we surmise that the recombination likely occurred in the Arabian Peninsula.

View this table:
TABLE 2 

Estimated times in years to most recent common ancestor of the 2015 cluster

Link to comment
Share on other sites
niman Grand Master

niman

Posted
  • Author
Posted

DISCUSSION

Over the past 3 years, MERS-CoV infections have continued to increase, posing a serious threat to global public health. Previous studies have revealed that MERS-CoV infections are likely due to repeated introductions of MERS-CoV from dromedary camels to humans (1315), resulting in only limited human-to-human transmission (16). However, the large number of second- and third-generation cases in South Korea raised concerns that MERS-CoV may have evolved to become more adapted to human-to-human transmission.

Our results indicate that at the whole-genome level, ChinaGD01 is >99% similar to the previously identified MERS-CoV strains. Phylogenetic analysis based on the whole-genome sequence revealed that it belongs to group 3 of clade B MERS-CoV strains and forms a separate small branch with viruses from South Korea and Saudi Arabia from 2015. Different phylogenies were observed in the trees constructed using the full-length genome and the S gene, indicating the possibility of a recombination event. Further evidence of a recombination event was obtained through bootscanning and SNP analyses. BEAST analysis revealed that it might have occurred recently, in the second half of 2014, in the Middle East.

Genetic recombination has been well established in severe acute respiratory syndrome coronavirus (SARS-CoV) (1718); however, there is only one report of genetic recombination in MERS-CoV (19). Dudas and Rambaut point to frequent recombination in MERS-CoV and partition the genome into two parts in which nucleotides 1 to 23,722 and nucleotides 23,723 to 30,126 have independent molecular clock rates. Based on the latest genome sequences from South Korea and the Kingdom of Saudi Arabia, our research indicated that a novel type of genetic recombination has occurred in the MERS-CoV strains prevalent in South Korea. We note that six MERS-CoV isolates from 2015 (ChinaGD01, the first MERS-CoV strain from South Korea, and the four latest strains from Saudi Arabia) had high levels of nucleotide identity (99.90% to 99.96%) and showed the same recombination signal in our analyses. We speculate that they arose from a common recombination event. However, more studies are needed to understand the relationship between genetic recombination of MERS-CoV, the biological properties it conveys, and its relevance to the recent high rate of transmission.

Link to comment
Share on other sites
niman Grand Master

niman

Posted
  • Author
Posted

MATERIALS AND METHODS

Full-length genomic sequencing.Nasopharyngeal swabs from the South Korean patient diagnosed with MERS-CoV infection were collected and used for viral RNA extraction with the QIAamp viral RNA minikit. Forty-four sets of specific primer pairs were designed and used to amplify the complete genome, followed by Sanger sequencing; meanwhile, the extracted viral RNA was also used for next-generation sequencing with the Ion Torrent PGM after random amplification.

Phylogenetic analysis.We downloaded all (n = 92) available full-length genome sequences of MERS-CoV from GenBank and used RAxML (20) for phylogenetic analyses of the complete genome, the ORF1ab gene, and the S gene, respectively. One thousand bootstrap replicates were run. Furthermore, the Bayesian Markov chain Monte Carlo method, implemented in BEAST (21), was used to estimate the time to the most recent common ancestor. Twelve different model combinations were applied. For all the analyses, we used the general time-reversible nucleotide substitution model with gamma-distributed rate heterogeneity. Bayesian Markov chain Monte Carlo analysis was run for 50 million steps. Trees and parameters were sampled every 5,000 steps, with the first 10% removed as burn-in.

Genetic recombinant analysis.Similarity plots and bootscanning analysis were generated by SimPlot (22); a sliding window of 200 nucleotides was used, moving in 20-nucleotide steps. Single-nucleotide-difference analysis was used to confirm the recombination event.

Nucleotide sequence accession number.The full-length virus genome (30,144 bp) of ChinaGD01 was deposited in GenBank under accession no. KT006149.

Previous SectionNext Section

SUPPLEMENTAL MATERIAL

  • FIGURE S1 

    Substitutions in the ORF1ab genes from all available MERS-CoV genomes. Different groups are separated by lines; only positions with substitutions are shown. Different types of substitutions are indicated using different colors, as follows: blue for synonymous, claret red for nonsynonymous, and green for untranslated region. Download Figure S1, PDF file, 0.5 MB.

     

     

  • FIGURE S2 

    Substitutions in the indicated genes from all available MERS-CoV genomes. Different groups are separated by lines; only positions with substitutions are shown. Different types of substitutions are indicated using different colors, as follows: blue for synonymous, claret red for nonsynonymous, and green for untranslated region. Download Figure S2, PDF file, 0.4 MB.

     

     

Previous SectionNext Section

ACKNOWLEDGMENTS

This work was supported by funds from the Ministry of Science and Technology of China (2011CB504704), the National Health and Family Planning Commission of China (grants 2014ZX10004-001 and 2013ZX10004601), and National Natural Science Foundation of China (NSFC; grants 81100062 and 81321063). G.F.G. is a leading principal investigator of the NSFC Innovative Research Group (81321063).

We thank the clinical staff in Huizhou Central Hospital in Guangdong Province for providing the information and nasopharyngeal swab samples from this imported case.

Link to comment
Share on other sites
niman Grand Master

niman

Posted
  • Author
Posted

REFERENCES

  1. 1.
     
    1. Zumla A
    2. Hui DS
    3. Perlman S
    3 June 2015Middle East respiratory syndromeLancet. 10.1016/S0140-6736(15)60454-8.
     
    CrossRef
  2. 2.
     
    1. Guery B
    2. Poissy J
    3. el Mansouf L
    4. Séjourné C
    5. Ettahar N
    6. Lemaire X,
    7. Vuotto F
    8. Goffard A
    9. Behillil S
    10. Enouf V
    11. Caro V
    12. Mailles A
    13. Che D,
    14. Manuguerra JC
    15. Mathieu D
    16. Fontanet A
    17. van der Werf SMERS-CoV Study Group
    2013Clinical features and viral diagnosis of two cases of infection with Middle East respiratory syndrome coronavirus: a report of nosocomial transmissionLancet 381:22652272. 10.1016/S0140-6736(13)60982-4.
    CrossRefMedline
  3. 3.
     
    1. De Groot RJ
    2. Baker SC
    3. Baric RS
    4. Brown CS
    5. Drosten C
    6. Enjuanes L,
    7. Fouchier RA
    8. Galiano M
    9. Gorbalenya AE
    10. Memish ZA
    11. Perlman S
    12. Poon LL,
    13. Snijder EJ
    14. Stephens GM
    15. Woo PC
    16. Zaki AM
    17. Zambon M
    18. Ziebuhr J
    2013.Middle East respiratory syndrome coronavirus (MERS-CoV): announcement of the Coronavirus Study GroupJ Virol 87:77907792. 10.1128/JVI.01244-13.
    FREE Full Text
  4. 4.
     
    1. Zaki AM
    2. Van Boheemen S
    3. Bestebroer TM
    4. Osterhaus AD
    5. Fouchier RA
    .2012Isolation of a novel coronavirus from a man with pneumonia in Saudi ArabiaN Engl J Med 367:18141820. 10.1056/NEJMoa1211721.
     
    CrossRefMedline
  5. 5.
     
    1. Memish ZA
    2. Mishra N
    3. Olival KJ
    4. Fagbo SF
    5. Kapoor V
    6. Epstein JH,
    7. AlHakeem R
    8. Durosinloun A
    9. Al Asmari M
    10. Islam A
    11. Kapoor A
    12. Briese T,
    13. Daszak P
    14. Al Rabeeah AA
    15. Lipkin WI
    2013Middle East respiratory syndrome coronavirus in bats, Saudi ArabiaEmerg Infect Dis 19:18191823.10.3201/eid1911.131172.
     
    CrossRefMedline
  6. 6.
     
    1. Alagaili AN
    2. Briese T
    3. Mishra N
    4. Kapoor V
    5. Sameroff SC
    6. de Wit E,
    7. Munster VJ
    8. Hensley LE
    9. Zalmout IS
    10. Kapoor A
    11. Epstein JH
    12. Karesh WB,
    13. Daszak P
    14. Mohammed OB
    15. Lipkin WI
    2014Middle East respiratory syndrome coronavirus infection in dromedary camels in Saudi ArabiamBio 5(2):e00884-00814. 10.1128/mBio.00884-14.
     
    Abstract/FREE Full Text
  7. 7.
     
    1. Cotten M
    2. Watson SJ
    3. Zumla AI
    4. Makhdoom HQ
    5. Palser AL
    6. Ong SH,
    7. Al Rabeeah AA
    8. Alhakeem RF
    9. Assiri A
    10. Al-Tawfiq JA
    11. Albarrak A
    12. Barry M,
    13. Shibl A
    14. Alrabiah FA
    15. Hajjar S
    16. Balkhy HH
    17. Flemban H
    18. Rambaut A,
    19. Kellam P
    20. Memish ZA
    2014Spread, circulation, and evolution of the Middle East respiratory syndrome coronavirusmBio 5(1):e01062-13.10.1128/mBio.01062-13.
     
    Abstract/FREE Full Text
  8. 8.
     
    1. Haagmans BL
    2. Al Dhahiry SH
    3. Reusken CB
    4. Raj VS
    5. Galiano M,
    6. Myers R
    7. Godeke G-J
    8. Jonges M
    9. Farag E
    10. Diab A
    11. Ghobashy H
    12. Alhajri F,
    13. Al-Thani M
    14. Al-Marri SA
    15. Al Romaihi HE
    16. Al Khal A
    17. Bermingham A,
    18. Osterhaus AD
    19. AlHajri MM
    20. Koopmans MP
    2014Middle East respiratory syndrome coronavirus in dromedary camels: an outbreak investigationLancet Infect Dis 14:140145. 10.1016/S1473-3099(13)70690-X.
     
    CrossRefMedline
  9. 9.
     
    1. World Health Organization
    2015Novel coronavirus infection—update.http://www.who.int/csr/don/20-June-2015-mers-saudi-arabia/en/.
     
  10. 10.
     
    1. Hui DS
    2. Perlman S
    3. Zumla A
    2015Spread of MERS to South Korea and ChinaLancet Respir Med 3:509510. 10.1016/S2213-2600(15)00238-6.
    CrossRef
  11. 11.
     
    1. Assiri A
    2. Al-Tawfiq JA
    3. Al-Rabeeah AA
    4. Al-Rabiah FA
    5. Al-Hajjar S,
    6. Al-Barrak A
    7. Flemban H
    8. Al-Nassir WN
    9. Balkhy HH
    10. Al-Hakeem RF,
    11. Makhdoom HQ
    12. Zumla AI
    13. Memish ZA
    2013Epidemiological, demographic, and clinical characteristics of 47 cases of Middle East respiratory syndrome coronavirus disease from Saudi Arabia: a descriptive studyLancet Infect Dis13:752761. 10.1016/S1473-3099(13)70204-4.
     
    CrossRefMedline
  12. 12.
     
    1. Corman V
    2. Eckerle I
    3. Bleicker T
    4. Zaki A
    5. Landt O,
    6. Eschbach-Bludau M
    7. Van Boheemen S
    8. Gopal R
    9. Ballhause M,
    10. Bestebroer TM
    11. Muth TD
    12. Müller MA
    13. Drexler JF
    14. Zambon M,
    15. Osterhaus AD
    16. Fouchier RM
    17. Drosten C
    2012Detection of a novel human coronavirus by real-time reverse-transcription polymerase chain reactionEuro Surveillance 17(39):pii=20285.http://www.eurosurveillance.org/ViewArticle.aspx?ArticleId=20285.
     
  13. 13.
     
    1. Banik G
    2. Khandaker G
    3. Rashid H
    2015Middle East respiratory syndrome coronavirus “MERS-CoV”: current knowledge gapsPaediatr Respir Rev16:197202. 10.1016/j.prrv.2015.04.002.
     
    CrossRefMedline
  14. 14.
     
    1. Zumla A
    2. Perlman S
    3. McNabb SJ
    4. Shaikh A
    5. Heymann DL,
    6. McCloskey B
    7. Hui DS
    2015Middle East respiratory syndrome in the shadow of EbolaLancet Respir Med 3:100102. 10.1016/S2213-2600(14)70316-9.
    CrossRefMedline
  15. 15.
     
    1. Hemida MG
    2. Al-Naeem A
    3. Perera RA
    4. Chin AW
    5. Poon LL
    6. Peiris M
    .2015Lack of Middle East respiratory syndrome coronavirus transmission from infected camelsEmerg Infect Dis 21:699701. 10.3201/eid2104.141949.
    CrossRef
  16. 16.
     
    1. Edelstein M
    2. Heymann DL
    2015What needs to be done to control the spread of Middle East respiratory syndrome coronavirus? Future Virol10:497505. 10.2217/fvl.15.20.
     
    CrossRef
  17. 17.
     
    1. Yount B
    2. Roberts RS
    3. Lindesmith L
    4. Baric RS
    2006Rewiring the severe acute respiratory syndrome coronavirus (SARS-CoV) transcription circuit: engineering a recombination-resistant genomeProc Natl Acad Sci U S A103:1254612551. 10.1073/pnas.0605438103.
     
    Abstract/FREE Full Text
  18. 18.
     
    1. Gorbalenya AE
    2. Snijder EJ
    3. Spaan WJ
    2004Severe acute respiratory syndrome coronavirus phylogeny: toward consensusJ Virol 78:78637866.10.1128/JVI.78.15.7863-7866.2004.
     
    FREE Full Text
  19. 19.
     
    1. Dudas G
    2. Rambaut A
    2015MERS-CoV recombination: implications about the reservoir and potential for adaptationbioRxiv 10.1101/020834.
    Abstract/FREE Full Text
  20. 20.
     
    1. Stamatakis A
    2014RAxML version 8: a tool for phylogenetic analysis and post-analysis of large phylogeniesBioinformatics 30:13121313.10.1093/bioinformatics/btu033.
     
    Abstract/FREE Full Text
  21. 21.
     
    1. Drummond AJ
    2. Suchard MA
    3. Xie D
    4. Rambaut A
    2012Bayesian phylogenetics with BEAUti and the BEAST 1.7Mol Biol Evol 29:19691973.10.1093/molbev/mss075.
     
    Abstract/FREE Full Text
  22. 22.
     
    1. Lole KS
    2. Bollinger RC
    3. Paranjape RS
    4. Gadkari D
    5. Kulkarni SS,
    6. Novak NG
    7. Ingersoll R
    8. Sheppard HW
    9. Ray SC
    1999Full-length human immunodeficiency virus type 1 genomes from subtype C-infected seroconverters in India, with evidence of intersubtype recombinationJ Virol 73:152160.
    Abstract/FREE Full Text
Link to comment
Share on other sites

Please sign in to comment

You will be able to leave a comment after signing in



Sign In Now
 Share
Go to topic listing

  • Recently Browsing   0 members

    • No registered users viewing this page.
×
×
  • Create New...