Faculty Bibliography

The mechanisms of transcriptional activation directed by sequence-specific regulators is central to understanding gene regulation. Here, we report the isolation of coactivators responsible for mediating transcriptional activation by Gal4-Pro, a hybrid regulator containing the proline-rich activation domain of human CTF/NFI. Chromatographic studies indicate that endogenous human TFIID consists of a multisubunit complex containing the TATA-binding protein (TBP), coactivators, and other associated factors. A fraction containing the coactivator activity was separated from the endogenous TBP after disrupting the tightly associated complex with urea. The urea-purified TBP was active for basal level transcription but no longer could support activation by Gal4-Pro. However, when the two separated components were added together, activated levels of transcription were restored in the presence of Gal4-Pro. Immunoaffinity purification of the TFIID complex identifies several polypeptides specifically associated with the endogenous TBP, some or all of which function as coactivators when reconstituted with Gal4-Pro. The isolated coactivators also mediate activation by a chimeric glutamine-rich activator derived from Sp1 but not the Gal4-VP16 activator, suggesting distinct factor requirements for different types of transcriptional regulators.

The reverse transcriptase enzymes of retroviruses are multifunctional proteins containing both DNA polymerase activity and a nuclease activity, termed RNase H, specific for RNA in RNA-DNA hybrid form. To determine the role of RNase H activity in retroviral replication, we constructed a series of mutant genomes of Moloney murine leukemia virus that encoded reverse transcriptase enzymes that were specifically altered to retain polymerase function but lack RNase H activity. The mutant genomes were all replication defective. Analysis of in vitro reverse transcription reactions carried out by mutant virions showed that minus-strand strong-stop DNA was formed but did not efficiently translocate to the 3' end of the genome; rather, the DNA was stably retained in RNA-DNA hybrid form. Plus-strand strong-stop DNA was not detected. These results suggest that RNase H normally promotes strong-stop translocation, perhaps by exposing single-stranded DNA sequences for base pairing. Four new DNA species were also detected among the reaction products. Analysis of these DNAs suggested that they were minus-strand DNAs formed from VL30 RNAs encoded by the mouse genome. We suggest that reverse transcriptase can initiate DNA synthesis at any one of four alternate tRNA primer-binding sites near the 5' ends of VL30 RNAs.