Repression of TFIIH transcriptional activity and TFIIH-associated cdk7 kinase activity at mitosis.

Nuclear transcription is repressed when eukaryotic cells enter mitosis. Mitotic repression of transcription of various cellular and viral gene promoters by RNA polymerase II can be reproduced in vitro either with extracts prepared from cells arrested at mitosis with the microtubule polymerization inhibitor nocodazole or with nuclear extracts prepared from asynchronous cells and the mitotic protein kinase cdc2/cyclin B. Purified cdc2/cyclin B kinase is also sufficient to inhibit transcription in reconstituted transcription reactions with biochemically purified and recombinant basal transcription factors and RNA polymerase II. The cyclin-dependent kinase inhibitor p21Waf1/Cip1/Sdi1 can reverse the effect of cdc2/cyclin B kinase, indicating that repression of transcription is due to protein phosphorylation. Transcription rescue and inhibition experiments with each of the basal factors and the polymerase suggest that multiple components of the transcription machinery are inactivated by cdc2/cyclin B kinase. For an activated promoter, targets of repression are TFIID and TFIIH, while for a basal promoter, TFIIH is the major target for mitotic inactivation of transcription. Protein labeling experiments indicate that the p62 and p36 subunits of TFIIH are in vitro substrates for mitotic phosphorylation. Using the carboxy-terminal domain of the large subunit of RNA polymerase II as a test substrate for phosphorylation, the TFIIH-associated kinase, cdk7/cyclin H, is inhibited concomitant with inhibition of transcription activity. Our results suggest that there exist multiple phosphorylation targets for the global shutdown of transcription at mitosis.

Repression of RNA polymerase II and III transcription during M phase of the cell cycle.

Nuclear transcription is repressed when eukaryotic cells enter mitosis. Using Xenopus egg extracts shifted to the mitotic state with recombinant cyclin B1 protein, we have been able to reproduce mitotic repression of transcription in vitro. Active RNA polymerase III transcription is observed in interphase extracts in the absence of added cyclin, but is strongly repressed by the induction of cdc2/cyclin B (maturation/mitosis promoting factor, MPF) kinase activity in the mitotic extract. Studies with protein kinase inhibitors show that protein phosphorylation is required for repression. Add-back experiments indicate that repression of class III gene transcription is due to inactivation of the transcription factor TFIIIB. TFIIIB is composed of the TATA-box binding protein (TBP) and TBP-associated factors of 75 and 92 kDa. In the present study, we show that TBP and a polypeptide of 92 kDa are substrates of the mitotic kinase in highly purified TF- IIIB fractions. We also show that a phosphatase present in the Xenopus egg extract can reactivate transcription after repression by the mitotic kinases. This result suggests a mechanism for reactivation of transcription after exit from mitosis into the G1 phase of the cell cycle. As for pol III genes, purified cdc2/cyclin B kinase is sufficient to inhibit transcription by RNA polymerase II in a reconstituted transcription system containing the basal transcription factors and polymerase.

TATA-box DNA binding activity and subunit composition for RNA polymerase III transcription factor IIIB from Xenopus laevis.

The RNA polymerase III transcription initiation factor TFIIIB contains the TATA-box-binding protein (TBP) and polymerase III-specific TBP-associated factors (TAFs). Previous studies have shown that DNA oligonucleotides containing the consensus TATA-box sequence inhibit polymerase III transcription, implying that the DNA binding domain of TBP is exposed in TFIIIB. We have investigated the TATA-box DNA binding activity of Xenopus TFIIIB, using transcription inhibition assays and a gel mobility shift assay. Gel shift competition assays with mutant and nonspecific DNAs demonstrate the specificity of the TFIIIB-TATA box DNA complex. The apparent dissociation constant for this protein-DNA interaction is approximately 0.4 nM, similar to the affinity of yeast TBP for the same sequence. TFIIIB transcriptional activity and TATA-box binding activity cofractionate during a series of four ion-exchange chromatographic steps, and reconstituted transcription reactions demonstrate that the TATA-box DNA-protein complex contains TFIIIB TAF activity. Polypeptides with apparent molecular masses of 75 and 92 kDa are associated with TBP in this complex. These polypeptides were renatured after elution from sodium dodecyl sulfate-gels and tested individually and in combination for TFIIIB TAF activity. Recombinant TBP along with protein fractions containing the 75- and 92-kDa polypeptides were sufficient to reconstitute TFIIIB transcriptional activity and DNA binding activity, suggesting that Xenopus TFIIIB is composed of TBP along with these polypeptides.

Interaction of the RNA binding fingers of Xenopus transcription factor IIIA with specific regions of 5 S ribosomal RNA.

Zinc fingers 4 to 7 of Xenopus transcription factor IIIA (TFIIIA) represent the minimal polypeptide necessary for high-affinity binding to 5 S RNA. Mutations covering the entire 5 S RNA structure have been compared for their effects on the binding affinity of full-length TFIIIA and a polypeptide consisting of fingers 4 to 7 of TFIIIA (zf4-7). In addition, ribonuclease footprinting was used to compare the binding sites of TFIIIA and zf4-7 on 5 S RNA. The consistency between the data obtained from these two approaches provided a clear indication that zinc fingers 4 to 7 of TFIIIA bind to a central core region on the 5 S RNA molecule consisting of loop B/helix II/loop A/helix V/region E. This information was used to design a truncated 75-nucleotide-long RNA molecule that retains high affinity for zf4-7. Therefore, we conclude that the specific interaction of TFIIIA with 5 S RNA can be represented by a complex formed between a four zinc finger polypeptide and a truncated 5 S RNA molecule.