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. 1993 Jul 1;90(13):6032–6036. doi: 10.1073/pnas.90.13.6032

Molecular and biological changes in the cold-adapted "master strain" A/AA/6/60 (H2N2) influenza virus.

M L Herlocher 1, H F Maassab 1, R G Webster 1
PMCID: PMC46861  PMID: 8327480

Abstract

The live cold-adapted (ca) A/AA/6/60 influenza vaccine is being commercially developed for worldwide use in children and is being used as a model for other live vaccines. Although it has been proven safe and immunogenic, the molecular basis of cold adaptation has never been determined. To identify sequence changes responsible for cold adaptation, we have compared the sequence of the master ca vaccine strain to its progenitor wild-type virus, wt A/AA/6/60 E2 (wt2). Only 4 nt differences encoding 2 aa differences were found in three gene segments. Computer-predicted RNA folds project different secondary structures between the ca and wt2 molecules based on the two silent differences between them. Genes coding for the acidic polymerase, matrix, and nonstructural proteins are identical between the two viruses. The few differences found in the ca A/AA/6/60 virus after its long stepwise passage at 25 degrees C in primary chicken kidney cells suggest that cold adaptation resulted in greater genetic stability for the highly variable RNA genome.

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Selected References

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