Abstract
We mapped the location of the E3A RNA 3' end site in the E3 transcription unit of adenovirus 2. The procedure used was nuclease-gel analysis with 32P-labeled RNA probes. The poly(A) addition sites were microheterogeneous and were located approximately 17 to 29 nucleotides downstream from an ATTAAA sequence. To identify the sequences that make up the E3A RNA 3' end signal, we constructed five viable virus mutants with deletions in or near the E3A RNA 3' end site. The mutants were analyzed for E3A RNA 3' end formation in vivo. No effect was observed from a 47-base-pair (bp) deletion (dl716) or a 72-bp deletion (dl714) located 22 and 19 nucleotides, respectively, upstream of the ATTAAA. In contrast, E3A RNA 3' end formation was abolished by a 554-bp deletion (dl708) that removes both the ATTAAA and the poly(A) addition sites, a 124-bp deletion (dl713) that removes the ATTAAA but leaves the poly(A) addition sites, and a 65-bp deletion (dl719) that leaves the ATTAAA but removes the poly(A) addition sites. These results indicate that the ATTAAA, as well as downstream sequences, including the poly(A) addition sites, are required for E3A RNA 3' end formation.
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Selected References
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