Partial purification and characterization of the Saccharomyces cerevisiae transcription factor TFIIIB

B"-associated factor(s) involved in RNA polymerase III preinitiation complex formation and start-site selection

The TFIIIB transcription factor is the central component of the RNA polymerase III transcriptional machinery. In yeast, this factor is composed of three essential polypeptides TBP, TFIIIB70 and TFIIIB90, that are sufficient as recombinant proteins, together with TFIIIC, to promote accurate transcription in vitro. Here we show that a partially purified fraction, named B", that contains the TFIIIB90 subunit, displays properties distinct from recombinant TFIIIB90. This fraction contains at least a component that interacts with DNA*TFIIIC complexes, either alone or in combination with TFIIIB90, and increases the resistance of the complexes to heparin treatment. In addition, primer extension and single round transcriptions experiment reveal a different start-site selection pattern directed by B" or rTFIIIB90. In mixing experiments, we show that an activity in B", distinct from TFIIIB90, can promote transcription initiation at the +1 site without affecting the rate of preinitiation complex formation. Our data suggest the existence of at least one new component that participates in preinitiation complex formation and influences start-site selection by RNA polymerase III.

A cryptic DNA binding domain at the COOH terminus of TFIIIB70 affects formation, stability, and function of preinitiation complexes

TFIIIC-dependent assembly of yeast TFIIIB on class III genes unmasks a high avidity of TFIIIB for DNA. TFIIIB contains TATA-binding protein (TBP), TFIIIB90/B", and TFIIIB70/Brf1, which is homologous to TFIIB. Using limited proteolysis, we have found that the COOH terminus of TFIIIB70 (residues 510-596) forms a protease-resistant domain that binds DNA tightly as seen by Southwestern, DNase I footprinting, and gel shift assays. Consistent with a role for this DNA binding activity, preinitiation complexes were formed less efficiently with truncated TFIIIB70 lacking the COOH-terminal domain and displayed an increased sensitivity to heparin. B' (TFIIIB70 + TBP).TFIIIC.DNA complexes were also particularly unstable. In addition, TFIIIB.TFIIIC.DNA complexes containing truncated TFIIIB70 were impaired in promoting transcription initiation.

Cloning and characterization of an essential Saccharomyces cerevisiae gene, TAF40, which encodes yTAFII40, an RNA polymerase II-specific TATA-binding protein-associated factor

In this report we describe the cloning and initial characterization of TAF40, a gene that encodes a yeast TATA-binding protein-associated factor (yTAF) of Mr = approximately 40,000. This gene has many similarities to other yTAFs described thus far in that it is present at a single copy per haploid genome, it is essential for viability, and the deduced protein sequence of yTAF40 exhibits similarity to previously described human and Drosophila TAFIIs. Immunological studies confirm that yTAF40 protein is a subunit of a large multiprotein TATA-binding protein-TAF complex that contains a subset of the total number of the yTAFs present in yeast cell extracts. Transcription reactions performed using yeast whole cell extracts reveal that of the three nuclear RNA polymerases only RNA polymerase II function is abrogated when yTAF40 and associated proteins are immunodepleted from solution, indicating that the functionality of the multiprotein complex containing yTAF40 is RNA polymerase II-specific. By these criteria yTAF40 appears to encode a bona fide RNA polymerase II-specific TAF, and thus the protein that it encodes has been termed yTAFII40.

Isolation and characterization of TAF25, an essential yeast gene that encodes an RNA polymerase II-specific TATA-binding protein-associated factor

We describe the cloning and analysis of TAF25, a previously uncharacterized yeast gene that encodes a yeast TATA-binding protein-associated factor or yTAF of Mr = 25,000. The gene encoding yTAF25 is a single copy essential gene, and the protein sequence deduced from TAF25 exhibits sequence similarity to a metazoan hTAFII. The results from immunological studies confirm that yTAF25 is a subunit of a large multiprotein TATA-binding protein-yeast TATA-binding protein-associated factor complex that contains a subset of the total number of the yTAFs present in yeast cell extracts. Both genetic and biochemical analyses demonstrate that yTAF25 can interact directly with itself. Transcriptional data show that the activity of the multiprotein complex containing yTAF25 is RNA polymerase II-specific, thus indicating that TAF25 encodes a bona fide yeast RNA polymerase II TAF. Hence the protein encoded by TAF25 has been termed yTAFII25.

Induction of Drosophila RNA polymerase III gene expression by the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) is mediated by transcription factor IIIB

We have previously found that the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) induces specific transcription of tRNA and 5S RNA genes in Drosophila Schneider S-2 cells (M. Garber, S. Panchanathan, R. F. Fan, and D. L. Johnson, J. Biol. Chem. 266:20598-20601, 1991). Having derived cellular extracts from TPA-treated cells, that are capable of reproducing this stimulation in vitro, we have examined the mechanism for this regulatory event. Using conditions that limit reinitiation and produce single rounds of transcription from active gene complexes, we find that the number of functional transcription complexes is increased in extracts prepared from TPA-induced cells. We have analyzed the activities of the transcription factors TFIIIB and TFIIIC derived from extracts prepared from TPA-induced and noninduced cells. Examination of the relative activities of TFIIIC showed that both its ability to reconstitute transcription with TFIIIB and RNA polymerase III and its ability to stably bind to the DNA template are unchanged. However, the activity of TFIIIB derived from the TPA-induced cells is substantially increased compared with that derived from the noninduced cells. The differences in TFIIIB activity account for the differences in the overall transcriptional activities observed in the unfractionated extracts. Western blot analysis of the TATA-binding protein subunit of TFIIIB revealed that there is an increase in the amount of this polypeptide present in the induced cell extracts and TFIIIB fraction. Together, these results indicate that the TPA response in Drosophila cells stimulates specific transcription of RNA polymerase III genes by increasing the activity of the limiting transcription component, TFIIIB, and thereby increasing the number of functional transcription complexes.

Gene expression: surprises from the class III side

Those genes which are transcribed by RNA polymerase III continue to give surprising results with respect to their cis-acting elements and transacting factors. As a result, a broader view of class III promoters has emerged and the internal promoters are not universal in classical polymerase III genes. The involvement of TFIID, TFIIA, a factor homologous to TFIIB and an RNA factor in class III gene transcription has further changed our thinking in regards to the mechanisms of transcription.

RNA polymerase III. Genes, factors and transcriptional specificity

Recent studies on RNA polymerase III (pol III) gene transcription have provided a new awareness of the molecular complexity of this process. Fortunately, while the number of transcription components has been increasing, fundamental similarities have emerged regarding the function of eukaryotic promoter elements and the factors that bind them to form preinitiation complexes. Among these, the ability of transcription factor IIIB (TFIIIB) and pol III to transcribe the Saccharomyces cerevisiae U6 gene suggests that the concept of a minimal pol II promoter comprising a TATA box and an initiator region has a parallel in the pol III system. Furthermore, for each of the three classes of eukaryotic RNA polymerase, the assembly of transcription preinitiation complexes and, to some extent, the nature of these complexes appears to be more similar than was previously anticipated. This work highlights the novel functions and transcriptional properties of newly identified pol III genes, discusses the diversity of pol III promoter structures and presents the notion that the exclusive use of extragenic promoters by some pol III genes (so-called type-3 genes) may have evolved since the divergence of yeast and higher eukaryotes. Additionally, recent progress is reviewed on the identification and cloning of subunits for TFIIIC and TFIIIB. Particular emphasis is given to two components of TFIIIB, the TATA-binding protein and a protein with TFIIB homology (PCF4), since the properties of these molecules suggest a model whereby the polymerase specificity of transcription complexes is determined.

Mechanism of TATA-binding protein recruitment to a TATA-less class III promoter

The TATA-binding protein (TBP) is required for transcription by RNA polymerase III (pol III), even though many pol III templates, such as the adenovirus VA1 gene, lack a consensus TATA box. We show that TBP alone does not form a stable, productive interaction with VA1 DNA. However, it can be incorporated into an initiation complex if the other class III basal factors, TFIIIB and TFIIIC, are also present. TFIIIB can associate with the evolutionarily conserved C-terminal domain of TBP in the absence of DNA or TFIIIC, suggesting that TFIIIB exists in solution as a complex with TBP. The stable association of TBP with an essential component of the pol III transcription apparatus may account for the ability of TATA-less class III genes to recruit TBP.

PCF4 encodes an RNA polymerase III transcription factor with homology to TFIIB

A dominant mutation in the PCF4 gene of S. cerevisiae was isolated as a suppressor of a tRNA gene A block promoter mutation. In vitro studies indicate that PCF4 is a stoichiometrically-required RNA polymerase III (pol III) transcription initiation factor. We show that the PCF4-1 mutation increases the number of transcriptionally competent preinitiation complexes by affecting a limiting activity in yeast cell extracts that is squelched by excess TFIIIC. The PCF4 gene encodes a TFIIB homolog whose size, biochemical, and genetic properties are consistent with those of the 70 kd subunit of TFIIIB. The TFIIB homology of PCF4 suggests a means for determining the polymerase specificity of a gene.

A suppressor of TBP mutations encodes an RNA polymerase III transcription factor with homology to TFIIB

The TDS4 gene of S. cerevisiae was isolated as an allele-specific high copy suppressor of mutations within the basic region of the TATA-binding protein (TBP). The gene is essential for viability and encodes a 596 aa protein. The first 300 aa of the TDS4 protein exhibit significant sequence similarity to the RNA polymerase II transcription factor TFIIB. However, TDS4 is required for RNA polymerase III transcription in vivo and in vitro. Antibodies specific for TDS4 or TBP react with the TFIIIB complex, indicating that both proteins are components of the RNA polymerase III initiation complex. These findings suggest that the RNA polymerase II and III initiation mechanisms are extremely similar, and they explain how the TATA-binding protein can function in both systems.

New twists in class III transcription

Recent work emphasizes the similarity between polymerase II and III in the mechanisms of transcription. Highlights of the past year include the alignment of individual polypeptides within class III transcription complexes and the demonstration that class III transcription machinery includes TFIID and an RNA component.

Inhibition of Aspergillus fumigatus elastase with monoclonal antibodies produced by using denatured elastase as an immunogen

In preparing monoclonal antibodies to the elastase from Aspergillus fumigatus, we found that the enzyme was weakly immunogenic in BALB/c mice. Antiserum titers were only 1:1,000 to 1:5,000, and hybridomas secreted nonspecific immunoglobulin M (IgM). Denaturing the elastase in 0.5% sodium dodecyl sulfate at 80 degrees C for 10 min prior to injection increased titers of antiserum against the nondenatured (native) enzyme 10-fold. Of eight hybridomas selected following immunization with the denatured enzyme, seven produced IgG reactive with the native enzyme and one produced nonspecific IgM. The nondenatured immunogen tested again yielded mainly IgM producers. Immunoblots and enzyme-linked immunosorbent assay showed that the IgG monoclonal antibodies were reactive with both the denatured and nondenatured fungal elastases; none cross-reacted with human neutrophil elastase, porcine pancreatic elastase, or Pseudomonas elastase. Elastase-specific polyclonal antibody produced in mice inhibited elastase activity beginning at a molar ratio (antibody to elastase) of 4:1, and activity was completely inhibited at 14.5:1. Some individual monoclonal antibodies partially inhibited elastase, but certain pairs, at a molar ratio of each antibody to elastase of 5.4:1, acted synergistically to inhibit the activity completely.

Participation of the TATA factor in transcription of the yeast U6 gene by RNA polymerase C

Fractionation of transcription extracts has led to the identification of multiple transcription factors specific for each form of nuclear RNA polymerase. Accurate transcription in vitro of the yeast U6 RNA gene by RNA polymerase C requires at least two factors. One of them was physically and functionally indistinguishable from transcription factor IID (TFIID or BTF1), a pivotal component of polymerase B transcription complexes, which binds to the TATA element. Purified yeast TFIID (yIID) or bacterial extracts that contained recombinant yIID were equally competent to direct specific transcription of the U6 gene by RNA polymerase C. The results suggest the formation of a hybrid transcription machinery, which may imply an evolutionary relation between class B and class C transcription factors.

Physical and immunological characterization of human transcription factor IIIA

Human transcription factor IIIA (htFIIIA), specifically required for transcription of the gene for 5S ribosomal RNA has been characterized with respect to some of its physical, immunological and functional properties. TFIIIA from HeLa cells, which selectively binds 5S RNA, is a monomer of approximately 35 kDa with a Stokes' radius of approximately 2.65 nm and a sedimentation coefficient of approximately 2.8 S. These values indicate that the human protein is of rather globular shape and hence diverges not only in molecular mass but also in most of the molecular properties from its highly asymmetric counterpart in Xenopus laevis oocytes. By raising specific polyclonal antibodies against hTFIIIA it was shown in Western immunoblots that there was no cross-reaction between anti-hTFIIIA antibodies and the amphibian protein. Conversely, monoclonal antibodies against three domains of X. laevis TFIIIA antibodies and the amphibian protein. Conversely, monoclonal antibodies against three domains of X. laevis TFIIIA did not cross-react with the human transcription factor. The polyclonal antisera raised against hTFIIIA specifically neutralized binding of the human transcription factor to 5S DNA and abolished in vitro transcription of 5S RNA but these antibodies were unable to inhibit 5S RNA synthesis in cellular extracts from Xenopus, Drosophila or yeast cells. Finally, the species variation of TFIIIA could be substantiated by electrophoretic mobility shift assays revealing preferential binding of hTFIIIA to the homologous 5S RNA gene.

Unraveling the complexities of transcription by RNA polymerase III

The biosynthesis of proteins and nucleic acids in eukaryotes requires the participation of numerous small RNAs, many of which are products of RNA polymerase III transcription. How cells are able to coordinate the synthesis of these RNAs during growth and replication has been the subject of recent exciting and thought-provoking studies. We review the progress in this area, and focus upon shared properties between transcription systems having different functions.

Sarkosyl defines three intermediate steps in transcription initiation by RNA polymerase III: application to stimulation of transcription by E1A

We used Sarkosyl to analyze steps along the pathway of transcription initiation by RNA polymerase III. Sarkosyl (0.015%) inhibited transcription when present prior to incubation of RNA polymerase III, TFIIIB, and TFIIIC with the VAI gene, whereas it had no detectable effect on initiation or reinitiation of transcription when added subsequently. The formation of the corresponding 0.015% Sarkosyl-resistant complex required the presence of TFIIIC, TFIIIB, and RNA polymerase III but not nucleoside triphosphates. The addition of 0.05% Sarkosyl after this early step selectively inhibited a later step in the preinitiation pathway, allowing a single round of transcription after nucleoside triphosphate addition but blocking subsequent rounds of initiation. This step occurred prior to initiation because nucleoside triphosphates were not required for the formation of the corresponding 0.05% Sarkosyl-resistant complex. These observations provided a means to distinguish effects of regulatory factors on different steps in promoter activation and function. Using 0.05% Sarkosyl to limit reinitiation, we determined that the E1A-mediated stimulation of transcription by RNA polymerase III resulted from an increase in the number of active transcription complexes.

S. cerevisiae TFIIIB is the transcription initiation factor proper of RNA polymerase III, while TFIIIA and TFIIIC are assembly factors

The S. cerevisiae RNA polymerase III (pol III) transcription factor TFIIIB binds to DNA upstream of the transcription start site of the SUP4 tRNA(Tyr) gene in a TFIIIC-dependent reaction and to the major 5S rRNA gene in a reaction requiring TFIIIC and TFIIIA. It is shown here that TFIIIB alone correctly positions pol III for repeated cycles of transcription on both genes, with the same efficiency as fully assembled transcription complexes. Thus, TFIIIB is the sole transcription initiation factor of S. cerevisiae pol III; TFIIIC and TFIIIA are assembly factors for TFIIIB. The TFIIIB-dependent binding of pol III to the SUP4 tRNA and 5S rRNA genes has been analyzed in binary (protein and DNA only) and precisely arrested ternary (protein, DNA, and RNA) transcription complexes. Pol III unwinds at least 14 bp of DNA at the SUP4 transcription start in a temperature-dependent process. The unwound DNA segment moves downstream with nascent RNA as a transcription bubble of approximately the same size.

Indium selectively increases the cytochrome P-450 dependent O-dealkylation of coumarin derivatives in male mice

Indium pretreatment of rats and mice has been reported to decrease the concentration of cytochrome P-450, thereby reducing the activity of some cytochrome P-450 dependent enzymatic reactions. The present study reveals that pretreatment of C57Bl/6JHan mice of both sexes with one s.c. dose of 120 mg of In2(SO4)3.5 H2O per kg of body weight decreases the concentration of cytochrome P-450 to about 65% of control levels. Neither cytochrome b5 nor NADPH-cytochrome P-450 reductase is affected. Hepatic microsomal ethoxyresorufin O-deethylase activity declines to about 75% of control values. In contrast, with coumarin substrates, a sex dependence in the direction of change is observed: in female mice indium decreases the activity to about 75%, whereas in males it enhances the activity to 140%. Moreover, with 7-(methoxy-14C)coumarin as substrate, indium-pretreated male mice exhale about 180% and females about 65% of 14CO2 compared to the corresponding controls. A close correlation between the in vivo and in vitro effects of indium on the metabolism of the coumarin derivatives is suggested. After isolation and purification of cytochrome P-450, SDS-PAGE indicates in indium-pretreated male mice an intensification of a 48.5 kDa protein band which is decreased in females. Immunological studies using antibodies raised against control female cytochrome P-450 show cross reactivity among all microsomes used in these experiments. High percentages of inhibition occur in microsomes with high molecular activity towards coumarin derivatives. The in vitro kinetics of antibody-inhibited O-deethylation of 7-ethoxycoumarin seems to obey a non- or partial-competitive type of inhibition. Indium pretreatment of mice produces sex-dependent effects on the metabolism of coumarin derivatives.

The transcriptional efficiency of clustered tRNA genes is affected by their position within the cluster

The transcription of a mouse genomic segment containing four tRNA genes, coding for a tRNA(Ala), a tRNA(Ile), a tRNA(Pro) and a tRNA(Lys), has been studied in a HeLa cell extract, demonstrating that differences among their transcriptional efficiencies are evident using as templates either the natural cluster or an equimolecular mixture of the four isolated genes. Nevertheless, the structure of the cluster influences the transcriptional efficiency of the clustered genes. In fact, a cis-acting inhibitory sequence has been located at about 400 bp downstream of the tRNA(Pro) coding sequence. Moreover rearrangements of the reciprocal position of the various tRNA genes within the cluster results in significant changes in the transcriptional rates of the individual transcriptional units.

Partial purification of plant transcription factors. II. An in vitro transcription system is inefficient

Crude wheat germ nuclear extracts contain many inhibitors of transcription which need to be removed before an active system can be developed. Using ion exchange column chromatography to resolve RNA polymerase II transcription components we can identify at least four fractions required for transcription by their ability to interact with, or substitute for, particular HeLa fractions. Inhibitors can be removed by a second or third chromatographic process applied to each fraction. Two plant fractions can each effectively replace the corresponding fraction in a HeLa transcription system, and the wheat fractions can work together and replace two HeLa fractions. These plant factors chromatograph identically to HeLa factors on ion exchange columns. The third fraction does not fully substitute for the corresponding HeLa fraction, but can complement this HeLa fraction when both are added at half-optimal levels. An in vitro plant system consisting of four plant chromatographic fractions will selectively transcribe a gene, but only at very low efficiency. The apparent block to greater efficiency is in elongation of the RNA past the 20-30n size.

Partial purification of plant transcription factors. I. Initiation

Crude plant cell protein extracts prepared from wheat germ are inactive for in vitro transcription by RNA polymerase II. These extracts do, however, have correct initiation of transcription by RNA polymerase II. Initiation is monitored by measuring the formation of transcription complexes in vitro. A nuclear extract produces more initiation events than a whole cell extract or a cytosol extract. Some factors necessary for initiation can be separated from other proteins, including inhibitors, by ion exchange column chromatography. One specific fraction is sufficient for the formation of transcription complexes and several other fractions may be stimulatory or accessory factors.