Analysis of the evolution and variation of the human influenza A virus nucleoprotein gene from 1933 to 1990.

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J Virol. 1993 May; 67(5): 2723-2729

Analysis of the evolution and variation of the human influenza A virus nucleoprotein gene from 1933 to 1990.

L L Shu, W J Bean and R G Webster

Department of Virology and Molecular Biology, St. Jude Children's Research Hospital, Memphis, Tennessee 38101.

ABSTRACT

This study examined the evolution and variation of the humaninfluenza virus nucleoprotein gene from the earliest isolatesto the present. Phylogenetic reconstruction of the most parsimoniousevolutionary path connecting 49 nucleoprotein sequences yieldeda single lineage. The average calculated rate of mutation was3.6 nucleotide substitutions per year (2.3 x 10(-3) substitutionsper site per year). Thirty-two percent of these mutations resultedin amino acid substitutions, and the remainder were silent mutations.Analysis of virus isolates from China and elsewhere showed nosignificant differences in their rate of evolution, geneticdiversity, or mean survival time. The nearly constant rate ofchange was maintained through the two antigenic shifts, andthere were no obvious changes in the number or types of mutationsassociated with the changes in the surface proteins. A detailedcomparison of the changes that have occurred on the main evolutionarypath with those that have occurred on the side branches of thephylogenetic tree was made. This showed that while 35% of themutations on the side branches resulted in amino acid changes,only 21% of those on the main path affected the protein sequence.These results suggest that although the rate of change of thehuman influenza virus nucleoprotein is much higher than thatpreviously described for avian influenza viruses, there aremeasurable constraints on the evolution of the surviving viruslineage. Comparison of the nucleoproteins of virus isolatesadapted to chicken embryos with the nucleoproteins of thosegrown only in MDCK cells revealed no consistent differencesbetween the virus pairs. Thus, although the nucleoprotein isknown to be critical for host specificity, its adaptation togrowth in eggs apparently involves no immediate selective pressures,such as are found with hemagglutinin.

J Virol. 1993 May; 67(5): 2723-2729

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