- THIS ARTICLE
- Full Text
- Full Text (PDF)
- Alert me when this article is cited
- Alert me if a correction is posted
- SERVICES
- Similar articles in this journal
- Similar articles in PubMed
- Alert me to new issues of the journal
- Download to citation manager
- Reprints & Permissions
- CITING ARTICLES
- Citing Articles via Google Scholar
- GOOGLE SCHOLAR
- Articles by Xia, X.
- Articles by Danchin, A.
- Search for Related Content
- PUBMED
- PubMed Citation
- Articles by Xia, X.
- Articles by Danchin, A.
Genomic Changes in Nucleotide and Dinucleotide Frequencies in Pasteurella multocida Cultured Under High Temperature
Xuhua Xiaa,b, Ting Weic, Zheng Xieb, and Antoine Danchinaa Bioinformatics Laboratory, HKU-Pasteur Research Center, Hong Kong,
b Department of Microbiology, University of Hong Kong, Hong Kong
c Guangxi Antiepidemic Station, Guangxi, China
Corresponding author: Xuhua Xia, HKU-Pasteur Research Center, Dexter H.C. Man Bldg., 8 Sassoon Rd., Pokfulam, Hong Kong., xxia{at}hkusua.hku.hk (E-mail)
Communicating editor: N. TAKAHATA
14,400 generations. The GC content of the vaccine strain is significantly (P < 0.05) lower than that of the virulent strain, contrary to the popular hypothesis of covariation between the GC content and temperature. The frequencies of AA, TA, and TT dinucleotides were higher, and those of AT, GC, and CG dinucleotides were lower, in the vaccine strain than in the virulent strain. A statistic called genomic RAPD entropy is formulated to measure the randomness of the genome, and the genome of the vaccine strain is more random than that of the virulent strain. These differences between the virulent and vaccine strains are interpreted in terms of mutation and selection under increased culturing temperature. A method for estimating substitution rates is developed in the APPENDIX.