Faculty Bibliography

TFIID is a multiprotein complex consisting of the TATA box binding protein and multiple tightly associated proteins (TAFIIs) that are required for transcription by selected activators. We previously reported cloning and partial characterization of human TAFII130 (hTAFII130). The central domain of hTAFII130 contains four glutamine-rich regions, designated Q1 to Q4, that are involved in interactions with the transcriptional activator Sp1. Mutational analysis has revealed specific regions within the glutamine-rich (Q1 to Q4) central region of hTAFII130 that are required for interaction with distinct activation domains. We tested amino- and carboxyl-terminal deletions of hTAFII130 for interaction with Sp1 activation domains A and B (Sp1A and Sp1B) and the N-terminal activation domain of CREB (CREB-N) by using the yeast two-hybrid system. Our results indicate that Sp1B interacts almost exclusively with the Q1 region of hTAFII130. In contrast, Sp1A makes multiple contacts with Q1 to Q4 of hTAFII130, while CREB-N interacts primarily with the Q1-Q2 hTAFII130 subdomain. Consistent with these interaction studies, overexpression of the Q1-to-Q4 region in HeLa cells inhibits Sp1- but not VP16-mediated transcriptional activation. These findings indicate that the Q1-to-Q4 region of hTAFII130 is required for Sp1-mediated transcriptional enhancement in mammalian cells and that different activation domains target distinct subdomains of hTAFII130

The human cytomegalovirus (HCMV) major immediate-early (IE) proteins IEP86 (IE2(579aa)) and IEP72 (IE1(491aa)) can transcriptionally activate a variety of simple promoters containing a TATA element and one upstream transcription factor binding site. In our previous studies, transcriptional activation was shown to correlate with IEP86 binding to both the TATA-box binding protein (TBP) and the transcription factor bound upstream. IEP72 often synergistically affects the activation by IEP86, although it has not previously been shown to directly interact in vitro with IEP86, TBP, or transcription factors (e.g., Sp1 and Tef-1) bound by IEP86. We report biochemical and genetic evidence suggesting that the major IE proteins may perform a function similar to that of the TBP-associated factors (TAFs) which make up TFIID. Consistent with this model, we found that the major IE proteins interact with a number of TAFs. In vitro, IEP86 bound with drosophila TAF(II)110 (dTAF(II)110) and human TAF(II)130 (hTAF(II)130), while IEP72 bound dTAF(II)40, dTAF(II)110, and hTAF(II)130. Regions on major IE proteins which mediate binding have been defined. In addition, our data indicate that both IEP72 and IEP86 can bind simultaneously to hTAF(II)130, suggesting that this TAF may provide bridging interactions between the two proteins for transcriptional activation and synergy. In agreement, a transcriptional activation mutant of IEP72 is unable to participate in bridging. Confirmation that these in vitro interactions were relevant was provided by data showing that both IEP72 and IEP86 copurify with TFIID and coimmunoprecipitate with purified TFIID derived from infected cell nuclei. To further support a TAF-like function of the IE proteins, we have found that the IE proteins expressed from the intact major IE gene, and to a lesser extent IEP86 alone, can rescue the temperature-sensitive (ts) transcriptional defect in TAF(II)250 in the BHK-21 cell line ts13. Analyses of mutations in the major IE region show that IEP86 is essential for rescue and that IEP72 augments its effect, and that mutations which affect TAF interactions are debilitated in rescue. Our data, showing that the IE proteins can bind with TFIID and rescue a ts transcriptional defect in TAF(II)250, support the model that the IE proteins perform a TAF-like function as components of TFIID.

We have used the interaction between the erythroid-specific enhancer in hypersensitivity site 2 of the human beta-globin locus control region and the globin gene promoters as a paradigm to examine the mechanisms governing promoter/enhancer interactions in this locus. We have demonstrated that enhancer-dependent activation of the globin promoters is dependent on the presence of both a TATA box in the proximal promoter and the binding site for the erythroid-specific heteromeric transcription factor NF-E2 in the enhancer. Mutational analysis of the transcriptionally active component of NF-E2, p45NF-E2, localizes the critical region for this function to a proline-rich transcriptional activation domain in the NH2-terminal 80 amino acids of the protein. In contrast to the wild-type protein, expression of p45 NF-E2 lacking this activation domain in an NF-E2 null cell line fails to support enhancer-dependent transcription in transient assays. More significantly, the mutated protein also fails to reactivate expression of the endogenous beta- or alpha-globin loci in this cell line. Protein-protein interaction studies reveal that this domain of p45 NF-E2 binds specifically to a component of the transcription initiation complex, TATA binding protein associated factor TAFII130. These findings suggest one potential mechanism for direct recruitment of distal regulatory regions of the globin loci to the individual promoters.

The transcription factor TFIID is a multisubunit complex that is required for promoter recognition and accurate initiation of transcription by RNA polymerase II. To dissect the molecular architecture and the biochemical properties of TFIID, a small-scale density gradient sedimentation method is employed to separate related complexes through differences in their sedimentation properties. A small amount of starting material is sufficient to obtain readily assayable amounts of separated proteins after centrifugation for 8 to 12 h in a benchtop ultracentrifuge. Gradient fractions are analyzed by immunoblotting for the presence of specific components of TFIID. Sucrose gradient sedimentation is performed to separate a mixture of multiprotein complexes from a crude nuclear extract immunoprecipitation of the proteins present in each fraction with an anti-TBP antibody reveals multiple TBP-containing complexes of different sizes. Density gradient sedimentation permits separation of specific components in a complex mixture and preserves activity, allowing functional assays

Transcription factor TFIID is a multiprotein complex composed of the TATA box-binding protein (TBP) and multiple TBP-associated factors (TAFs). TFIID plays an essential role in mediating transcriptional activation by gene-specific activators. Numerous transcriptional activators have been characterized from mammalian cells; however, molecular analysis of the components of mammalian TFIID has been incomplete. Here we describe isolation of cDNAs encoding two TAF subunits of the human transcription factor TFIID. The first cDNA is predicted to encode the C-terminal 947 residues of the 130-kDa human TAF subunit, hTAFII130. The second cDNA encodes the C-terminal 801 residues of the 100-kDa subunit, hTAFII100. Recombinant TAFs expressed in human cells by transient transfections are capable of associating with the endogenous TAFs and TBP to form a TFIID complex in vivo. Protein binding experiments demonstrate that hTAFII130, like its Drosophila homolog dTAFII110, interacts with the glutamine-rich activation domains of the human transcription factor Sp1. Furthermore, hTAFII130 shows reduced binding to the Sp1 mutants with impaired ability to activate transcription, suggesting a role for hTAFII130 as a direct coactivator target for Sp1

Regulation of transcription initiation by RNA polymerase II requires TFIID, a multisubunit complex composed of the TATA binding protein (TBP) and at least seven tightly associated factors (TAFs). Some TAFs act as direct targets or coactivators for promoter-specific activators while others serve as interfaces for TAF-TAF interactions. Here, we report the molecular cloning, expression and characterization of Drosophila dTAFII60 and its human homolog, hTAFII70. Recombinant TAFII60/70 binds weakly to TBP and tightly to the largest subunit of TFIID, TAFII250. In the presence of TAFII60/70, TBP and TAFII250, a stable ternary complex is formed. Both the human and Drosophila proteins directly interact with another TFIID subunit, dTAFII40. Our findings reveal that Drosophila TAFII60 and human TAFII70 share a high degree of structural similarity and that their interactions with other subunits of TFIID are conserved

We have previously described a series of mutations in the 3' terminus of the pol gene of Moloney murine leukemia virus which adversely affect the establishment of an integrated provirus (Roth, M. J., Schwartzberg, P., Tanese, N., and Goff, S. P., J. Virol. 64, 4709-4717, 1990). While most of the mutations were unconditionally lethal for virus replication, we now demonstrate that one mutation, in6161-12, a 12-base pair linker insertion into the 3' end of the pol gene, causes a temperature-sensitive phenotype. This mutant virus is temperature-sensitive for IN protein function as well as viral replication.

We have previously shown that the TATA-binding protein (TBP) and multiple TBP-associated factors (TAFs) are required for regulated transcriptional initiation by RNA polymerase II. Here we report the biochemical properties of the RNA polymerase I promoter selectivity factor, SL1, and its relationship to TBP. Column chromatography and glycerol gradient sedimentation indicate that a subpopulation of TBP copurifies with SL1 activity. Antibodies directed against TBP efficiently deplete SL1 transcriptional activity, which can be restored with the SL1 fraction but not purified TBP. Thus, TBP is necessary but not sufficient to complement SL1 activity. Analysis of purified SL1 reveals a complex containing TBP and three distinct TAFs. Purified TAFs reconstituted with recombinant TBP complement SL1 activity, and this demonstrates that TBP plus novel associated factors are integral components of SL1. These findings suggest that TBP may be a universal transcription factor and that the TBP-TAF arrangement provides a unifying mechanism for promoter recognition in animal cells