Modulation of poliovirus replicative fitness in HeLa cells by deoptimization of synonymous codon usage in the capsid region.

We replaced degenerate codons for nine amino acids within the capsid region of the Sabin type 2 oral poliovirus vaccine strain with corresponding nonpreferred synonymous codons. Codon replacements were introduced into four contiguous intervals spanning 97% of the capsid region. In the capsid region of the most highly modified virus construct, the effective number of codons used (N(C)) fell from 56.2 to 29.8, the number of CG dinucleotides rose from 97 to 302, and the G+C content increased from 48.4% to 56.4%. Replicative fitness in HeLa cells, measured by plaque areas and virus yields in single-step growth experiments, decreased in proportion to the number of replacement codons. Plaque areas decreased over an approximately 10-fold range, and virus yields decreased over an approximately 65-fold range. Perhaps unexpectedly, the synthesis and processing of viral proteins appeared to be largely unaltered by the restriction in codon usage. In contrast, total yields of viral RNA in infected cells were reduced approximately 3-fold and specific infectivities of purified virions (measured by particle/PFU ratios) decreased approximately 18-fold in the most highly modified virus. The replicative fitness of both codon replacement viruses and unmodified viruses increased with the passage number in HeLa cells. After 25 serial passages (approximately 50 replication cycles), most codon replacements were retained, and the relative fitness of the modified viruses remained well below that of the unmodified virus. The increased replicative fitness of high-passage modified virus was associated with the elimination of several CG dinucleotides. Potential applications for the systematic modulation of poliovirus replicative fitness by deoptimization of codon usage are discussed.

Sequence variability of the integrase protein from a diverse collection of HIV type 1 isolates representing several subtypes.

HIV-1 recombinants between viruses from different subtypes appear to be surprisingly common in several regions of the world. To detect such intersubtype recombinants that contain mosaic genomes, we have analyzed sequences from the integrase (IN)-coding region of the polymerase (pol) gene from 23 viruses of known envelope (env) subtype from South America and Africa. As defined by env sequences, these viral genomes included nine subtype A, four subtype B, three subtype C, and four subtype D viruses from group M, and three viruses from group O HIV-1. Mosaic genomes were common, with 7 mosaic genomes among the 20 group M isolates analyzed. Two of these isolates had mosaic IN-coding regions that were distinct, but that had recombination breakpoints at the same location, in the highly conserved polypurine track. Mosaic genomes were particularly common in the viruses from Kenya (five of nine), consistent with our previous prediction that there was a high frequency of intersubtype recombinants circulating in this country. The IN amino acid sequence was highly conserved among the several represented subtypes, including group O. Group M IN sequences shared 94% or greater amino acid sequence identity within a subtype and 91% or greater identity between subtypes. The most divergent M and O variant amino acid sequences differed by only 19%, and the known functional domains were conserved among all of the isolates. The high degree of genetic homogeneity among the virus isolates representing several subtypes indicates that a single drug targeted against IN might be effective for all HIV-1 infections.