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. 1976 Nov;20(2):465–477. doi: 10.1128/jvi.20.2.465-477.1976

Genome expression and mRNA maturation at late stages of productive adenovirus type 2 infection.

W S Wold, M Green, K H Brackmann, M A Cartas, C Devine
PMCID: PMC355014  PMID: 978800

Abstract

RNA from adenovirus 2-infected KB cells was annealed in liquid with RNA in vast excess to viral heavy (l) and light (r) 32P-labeled DNA strands. Hybridization kinetics were analyzed by computer to estimate the number of viral RNA abundance classes, their relative concentrations, and the fraction of each DNA strand from which they originated. Early whole cell RNA extracted 5 h postinfection annealed rapidly to 10 to 15% of l and r strands and then slowly to final values of 60 and 40% of l and r strands. By 9 h postinfection the expression of late genes was apparent and whole cell RNA annealed to 20 and 75% of l and r strands. Whole cell RNA extracted between 12 and 36 h postinfection annealed to 7 to 15% and 75 to 90% of l and r strands. Late nuclear RNA hybridized to 10 and 90% of l and r strands, and late polyribosomal RNA hybridized to 20 and 75% of l and r strands. Based upon kinetic analyses, we estimate that mRNA synthesized exclusively during late stages arises from about 6 to 8% and 45 to 49% of l and r strands. This assumes that the early class I mRNA (in low concentration late) originates from 8 to 10% and 6 to 10% of l and r strands and that early class II mRNA (in high concentration late) is derived from 2% and 8 to 13% of l and r strands. Mixing experiments indicated that early mRNA is a subset of RNA extracted from polyribosomes late after infection and that late nuclear RNA contains sequences complementary to early l strand class I nRNA. RNA-RNA hybrids were isolated from late mRNA containing sequences from 60% of l and r strands, but it is not known when these were synthesized, and therefore whether complementary RNA transcripts are synthesized late after infection, as they are known to be synthesized early. These results demonstrate that portions of the genome are transcribed into RNA sequences that remain confined to the nucleus and are not exported to polyribosomes as mRNA.

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Selected References

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