Alfred S. Ponticelli

The N-terminal Region of Yeast TFIIB Contains Two Adjacent Functional Domains Involved in Stable RNA Polymerase II Binding and Transcription Start Site Selection

The general transcription factor IIB (TFIIB) is required for accurate and efficient transcription of protein-coding genes by RNA polymerase II (RNAPII). To define functional domains in the highly conserved N-terminal region of TFIIB, we have analyzed 14 site-directed substitution mutants of yeast TFIIB for their ability to support cell viability, transcription in vitro, accurate start site selection in vitro and in vivo, and to form stable complexes with purified RNAPII in vitro. Mutations impairing the formation of stable TFIIB·RNAPII complexes mapped to the zinc ribbon fold, whereas mutations conferring downstream shifts in transcription start site selection were identified at multiple positions within a highly conserved homology block adjacent and C-terminal to the zinc ribbon. These results demonstrate that the N-terminal region of yeast TFIIB contains two separable and adjacent functional domains involved in stable RNAPII binding and transcription start site selection, suggesting that downstream shifts in transcription start site selection do not result from impairment of stable TFIIB·RNAPII binding. We discuss models for yeast start site selection in which TFIIB may affect the ability of preinitiation complexes to interact with downstream DNA or to affect start site recognition by a scanning polymerase.

Functional differences between yeast and human TFIID are localized to the highly conserved region

TFIID, the general transcription factor that binds TATA promoter elements, is highly conserved throughout the eukaryotic kingdom. TFIIDs from different organisms contain C-terminal core domains that are at least 80% identical and display similar biochemical properties. Despite these similarities, yeast cells containing human TFIID instead of the endogenous yeast protein grow extremely poorly. Surprisingly, this functional distinction reflects differences in the core domains, not the divergent N-terminal regions. The N-terminal region is unimportant for the essential function(s) of yeast TFIID because expression of the core domain permits efficient cell growth. Analysis of yeast-human hybrid TFIIDs indicates that several regions within the conserved core account for the phenotypic difference, with some regions being more important than others. This species specificity might reflect differences in DNA-binding properties and/or interactions with activator proteins or other components of the RNA polymerase II transcription machinery.

Unphosphorylated SR-like protein Npl3 stimulates RNA polymerase II elongation.

The production of a functional mRNA is regulated at every step of transcription. An area not well-understood is the transition of RNA polymerase II from elongation to termination. The S. cerevisiae SR-like protein Npl3 functions to negatively regulate transcription termination by antagonizing the binding of polyA/termination proteins to the mRNA. In this study, Npl3 is shown to interact with the CTD and have a direct stimulatory effect on the elongation activity of the polymerase. The interaction is inhibited by phosphorylation of Npl3. In addition, Casein Kinase 2 was found to be required for the phosphorylation of Npl3 and affect its ability to compete against Rna15 (Cleavage Factor I) for binding to polyA signals. Our results suggest that phosphorylation of Npl3 promotes its dissociation from the mRNA/RNAP II, and contributes to the association of the polyA/termination factor Rna15. This work defines a novel role for Npl3 in elongation and its regulation by phosphorylation.

In vivo tyrosine phosphorylations of the abelson virus transforming protein are absent in its normal cellular homolog

The transforming gene product of the Abelson murine leukemia virus (A-MuLV) is a phosphoprotein encoded by combined viral and cellular sequences. Previous work has shown the existence of a serologically crossreactive normal cellular phosphoprotein called NCP150. We have utilized two-dimensional phosphopeptide mapping and phosphoamino acid analysis to compare the structures of NCP150 and wild-type and mutant forms of the A-MuLV protein labeled in vivo with 32P-orthophosphate. This analysis demonstrated clear homology between NCP150 and wild-type A-MuLV protein, but a number of phosphorylation differences were seen. Among them, two specific tyrosine phosphorylations present in all transformation-competent Abelson proteins were not observed in NCP150. No other phosphotyrosine-containing peptides were detected. In addition, transformation-defective mutants isolated from either the P120 or P160 wild-type strain lack phosphotyrosine-containing peptides. Double-infection studies with such transformation-defective and transformation-competent A-MuLV strains show that Abelson viral proteins may be substrates for their own tyrosine-specific kinase activity in vivo. These observations suggest that the phosphotyrosine kinase activity of the abl region may be controlled, and may function, differently in its viral and cellular forms.

Mutational Analysis of the D1/E1 Core Helices and the Conserved N-Terminal Region of Yeast Transcription Factor IIB (TFIIB): Identification of an N-Terminal Mutant That Stabilizes TATA-Binding Protein-TFIIB-DNA Complexes

The general transcription factor IIB (TFIIB) plays an essential role in transcription of protein-coding genes by RNA polymerase II. We have used site-directed mutagenesis to assess the role of conserved amino acids in several important regions of yeast TFIIB. These include residues in the highly conserved amino-terminal region and basic residues in the D1 and E1 core domain alpha-helices. Acidic substitutions of residues K190 (D1) and K201 (E1) resulted in growth impairments in vivo, reduced basal transcriptional activity in vitro, and an inability to form stable TFIIB-TATA-binding protein-DNA (DB) complexes. Significantly, these mutants retained the ability to respond to acidic activators in vivo and to the Gal4-VP16 activator in vitro, supporting the view that these basic residues play a role in basal transcription. In addition, 14 single-amino-acid substitutions were introduced in the conserved amino-terminal region. Three of these mutants, the L50D, R64E, and R78L mutants, displayed altered growth properties in vivo and were compromised for supporting transcription in vitro. The L50D mutant was impaired for RNA polymerase II interaction, while the R64E mutant exhibited altered transcription start site selection both in vitro and in vivo and, surprisingly, was more active than the wild type in the formation of stable DB complexes. These results support the view that the amino-terminal domain is involved in the direct interaction between yeast TFIIB and RNA polymerase II and suggest that this domain may interact with DNA and/or modulate the formation of a DB complex.

The glutamine-rich activation domains of human Sp1 do not stimulate transcription in Saccharomyces cerevisiae.

Eukaryotic transcriptional activators have been classified on the basis of the characteristics of their activation domains. Acidic activation domains, such as those in the yeast GAL4 or GNC4 proteins and the herpes simplex virus activator VP16, stimulate RNA polymerase II transcription when introduced into a variety of eukaryotic cells. This species interchangeability demonstrates that the mechanism by which acidic activation domains function is highly conserved in the eukaryotic kingdom. To determine whether such a conservation of function exists for a different class of activation domain, we have tested whether the glutamine-rich activation domains of the human transcriptional activator Sp1 function in the yeast Saccharomyces cerevisiae. We report here that the glutamine-rich domains of Sp1 do not stimulate transcription in S. cerevisiae, even when accompanied by human TATA-box binding protein (TBP) or human-yeast TATA-box binding protein hybrids. Thus, in contrast to the case for acidic activation domains, the mechanism by which glutamine-rich domains stimulate transcription is not conserved between S. cerevisiae and humans.

Analysis of Saccharomyces cerevisiae his3 transcription in vitro : biochemical support for multiple mechanisms of transcription

The promoter region of the Saccharomyces cerevisiae his3 gene contains two TATA elements, TC and TR, that direct transcription initiation to two sites designated +1 and +13. On the basis of differences between their nucleotide sequences and their responsiveness to upstream promoter elements, it has previously been proposed that TC and TR promote transcription by different molecular mechanisms. To begin a study of his3 transcription in vitro, we used S. cerevisiae nuclear extracts together with various DNA templates and transcriptional activator proteins that have been characterized in vivo. We demonstrated accurate transcription initiation in vitro at the sites used in vivo, transcriptional activation by GCN4, and activation by a GAL4 derivative on various gal-his3 hybrid promoters. In all cases, transcription stimulation was dependent on the presence of an acidic activation region in the activator protein. In addition, analysis of promoters containing a variety of TR derivatives indicated that the level of transcription in vitro was directly related to the level achieved in vivo. The results demonstrated that the in vitro system accurately reproduced all known aspects of in vivo his3 transcription that depend on the TR element. However, in striking contrast to his3 transcription in vivo, transcription in vitro yielded approximately 20 times more of the +13 transcript than the +1 transcript. This result was not due to inability of the +1 initiation site to be efficiently utilized in vitro, but rather it reflects the lack of TC function in vitro. The results support the idea that TC and TR mediate transcription from the wild-type promoter by distinct mechanisms.

Promoter-specific shifts in transcription initiation conferred by yeast TFIIB mutations are determined by the sequence in the immediate vicinity of the start sites.

ABSTRACT The general transcription factor IIB (TFIIB) is required for transcription of class II genes by RNA polymerase II. Previous studies demonstrated that mutations in the Saccharomyces cerevisiae SUA7 gene, which encodes TFIIB, can alter transcription initiation patterns in vivo. To further delineate the functional domain and residues of TFIIB involved in transcription start site utilization, a genetic selection was used to isolate S. cerevisiae TFIIB mutants exhibiting downstream shifts in transcription initiation in vivo. Both dominant and recessive mutations conferring downstream shifts were identified at multiple positions within a highly conserved homology block in the N-terminal region of the protein. The TFIIB mutations conferred downstream shifts in transcription initiation at the ADH1 and CYC1 promoters, whereas no significant shifts were observed at the HIS3 promoter. Analysis of a series of ADH1-HIS3 hybrid promoters and variant ADH1 and HIS3 promoters containing insertions, deletions, or site-directed base substitutions revealed that the feature that renders a promoter sensitive to TFIIB mutations is the sequence in the immediate vicinity of the normal start sites. We discuss these results in light of possible models for the mechanism of start site utilization by S. cerevisiae RNA polymerase II and the role played by TFIIB.

Amino acid substitutions in yeast TFIIF confer upstream shifts in transcription initiation and altered interaction with RNA polymerase II.

ABSTRACT Transcription factor IIF (TFIIF) is required for transcription of protein-encoding genes by eukaryotic RNA polymerase II. In contrast to numerous studies establishing a role for higher eukaryotic TFIIF in multiple steps of the transcription cycle, relatively little has been reported regarding the functions of TFIIF in the yeast Saccharomyces cerevisiae. In this study, site-directed mutagenesis, plasmid shuffle complementation assays, and primer extension analyses were employed to probe the functional domains of the S. cerevisiae TFIIF subunits Tfg1 and Tfg2. Analyses of 35 Tfg1 alanine substitution mutants and 19 Tfg2 substitution mutants identified 5 mutants exhibiting altered properties in vivo. Primer extension analyses revealed that the conditional growth properties exhibited by the tfg1-E346A, tfg1-W350A, and tfg2-L59K mutants were associated with pronounced upstream shifts in transcription initiation in vivo. Analyses of double mutant strains demonstrated functional interactions between the Tfg1 mutations and mutations in Tfg2, TFIIB, and RNA polymerase II. Importantly, biochemical results demonstrated an altered interaction between mutant TFIIF protein and RNA polymerase II. These results provide direct evidence for the involvement of S. cerevisiae TFIIF in the mechanism of transcription start site utilization and support the view that a TFIIF-RNA polymerase II interaction is a determinant in this process.

Functions of Saccharomyces cerevisiae TFIIF during Transcription Start Site Utilization

ABSTRACT Previous studies have shown that substitutions in the Tfg1 or Tfg2 subunits of Saccharomyces cerevisiae transcription factor IIF (TFIIF) can cause upstream shifts in start site utilization, resulting in initiation patterns that more closely resemble those of higher eukaryotes. In this study, we report the results from multiple biochemical assays analyzing the activities of wild-type yeast TFIIF and the TFIIF Tfg1 mutant containing the E346A substitution (Tfg1-E346A). We demonstrate that TFIIF stimulates formation of the first two phosphodiester bonds and dramatically stabilizes a short RNA-DNA hybrid in the RNA polymerase II (RNAPII) active center and, importantly, that the Tfg1-E346A substitution coordinately enhances early bond formation and the processivity of early elongation in vitro. These results are discussed within a proposed model for the role of yeast TFIIF in modulating conformational changes in the RNAPII active center during initiation and early elongation.