Direct Sequencing of SARS-Coronavirus S and N Genes from Clinical Specimens Shows Limited Variation | Zendy

Suxiang Tong | Zendy; Jairam R. Lingappa | Zendy; Qi Chen | Zendy; Bo Shu | Zendy; Ashley LaMonte | Zendy; Byron T. Cook | Zendy; Charryse Birge | Zendy; Shur-Wern Wang Chern | Zendy; Xin Liu | Zendy; Renee L. Galloway | Zendy; Mai Le Thi Quynh | Zendy; Fu Ng Wai | Zendy; PanChyr Yang | Zendy; Jagdish Butany | Zendy; James A. Comer | Zendy; Stephan S. Monroe | Zendy; Suzanne Beard | Zendy; Thomas G. Ksiazek | Zendy; Dean D. Erdman | Zendy; Paul A. Rota | Zendy; Mark A. Pallansch | Zendy; Larry J. Anderson | Zendy

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Direct Sequencing of SARS-Coronavirus S and N Genes from Clinical Specimens Shows Limited Variation

Author(s) -

Suxiang Tong,

Jairam R. Lingappa,

Qi Chen,

Bo Shu,

Ashley LaMonte,

Byron T. Cook,

Charryse Birge,

Shur-Wern Wang Chern,

Xin Liu,

Renee L. Galloway,

Mai Le Thi Quynh,

Fu Ng Wai,

PanChyr Yang,

Jagdish Butany,

James A. Comer,

Stephan S. Monroe,

Suzanne Beard,

Thomas G. Ksiazek,

Dean D. Erdman,

Paul A. Rota,

Mark A. Pallansch,

Larry J. Anderson

Publication year - 2004

Publication title -

the journal of infectious diseases

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 2.69

H-Index - 252

eISSN - 1537-6613

pISSN - 0022-1899

DOI - 10.1086/422849

Subject(s) - gene , biology , virology , virus , covid-19 , coronavirus , genome , genetic variation , dna sequencing , transmission (telecommunications) , genetics , disease , medicine , infectious disease (medical specialty) , pathology , electrical engineering , engineering

Severe acute respiratory syndrome-associated coronavirus (SARS-CoV) emerged, in November 2002, as a novel agent causing severe respiratory illness. To study sequence variation in the SARS-CoV genome, we determined the nucleic acid sequence of the S and N genes directly from clinical specimens from 10 patients--1 specimen with no matched SARS-CoV isolate, from 2 patients; multiple specimens from 3 patients; and matched clinical-specimen/cell-culture-isolate pairs from 6 patients. We identified 3 nucleotide substitutions that were most likely due to natural variation and 2 substitutions that arose after cell-culture passage of the virus. These data demonstrate the overall stability of the S and N genes of SARS-CoV over 3 months during which a minimum of 4 generations for transmission events occurred. These findings are a part of the expanding investigation of the evolution of how this virus adapts to a new host.

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