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. 1982 Aug;2(8):890–896. doi: 10.1128/mcb.2.8.890

Two structurally and functionally different forms of the transforming protein of PRC II avian sarcoma virus.

B Adkins, T Hunter
PMCID: PMC369876  PMID: 6290871

Abstract

The primary translation product of the PRC II avian sarcoma virus genome is a protein of 105,000 daltons (P105), and we have previously shown that approximately 50% of the P105 molecules are converted to molecules of 110,000 daltons (P110) by posttranslational modification. Fractionation of PRC II-infected cells showed that P105 was contained primarily in a nonionic detergent-soluble compartment, whereas P110 partitioned almost exclusively with a nonionic detergent-insoluble or crude cytoskeletal fraction. The tyrosine-specific protein kinase activity previously observed in immunoprecipitates which presumably contained both P110 and P105 was found predominantly in the P110-containing immunoprecipitates made from the cytoskeletal fraction and was essentially absent from the P105-containing immunoprecipitates prepared from the soluble fraction. Individual analysis of 32P-labeled P110 and P105 prepared by this fractionation technique revealed that P110 contained more phosphotyrosine per mole of protein than did P105. Examination of the tryptic peptide maps of 32P-labeled P110 and P105 suggested that the additional phosphotyrosine in P110 resulted from phosphorylation at discrete sites within the protein. From these experiments, we conclude that PRC II-infected cells contain two discrete forms, P105 and P110, of the transforming protein and that each of these proteins exhibits distinct structural and functional characteristics.

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Selected References

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