Mammalian RNA Polymerase Research Articles

Src homology 2 domain as a specificity determinant in the c-Abl-mediated tyrosine phosphorylation of the RNA polymerase II carboxyl-terminal repeated domain.

The Src-homology (SH) 2 domain, found in a variety of proteins, has a binding site for phosphotyrosine-containing peptides. In adaptor proteins such as Grb2, the SH2 domain plays an important role in the assembly of signal transducer complexes. Many nonreceptor tyrosine kinases--e.g., Abl and Src--also contain SH2 domains. Without a functional SH2 domain, these tyrosine kinases retain catalytic activity but lose their biological function. This result suggests that the SH2 domain may be involved in the selection of biologically relevant substrates. We have previously shown that the carboxyl-terminal repeated domain (CTD) of the mammalian RNA polymerase II is a substrate for the Abl but not the Src tyrosine kinase. This specificity is conferred in part by the SH2 domain. The Abl SH2 domain binds the tyrosine-phosphorylated [Tyr(P)] CTD and is required for the processive and stoichiometric phosphorylation of the 52 tyrosines in the CTD. Mutation of the Abl SH2 or exchanging it with that of Src, which does not bind the Tyr(P)-CTD, abolished processivity and reduced the CTD kinase activity without any effect on autophosphorylation or the phosphorylation of nonspecific substrates. These results demonstrate that the SH2 domain of the Abl tyrosine kinase plays an active role in catalysis and suggests that SH2 domain and the tyrosine kinase domain may act in concert to confer substrate specificity.

RNA Chain Elongation and Termination by Mammalian RNA Polymerase III: Analysis of tRNA Gene Transcription by Imposing a Reversible Factor-mediated Block to Elongation using a Sequence-specific DNA Binding Protein

We have used a sequence-specific DNA binding protein to examine transcription elongation and termination by mammalian RNA polymerase III (polIII). The Escherichia coli lac repressor protein, bound to its cognate operator site positioned between the 3′ end of the coding region and the termination site of a human tRNA gene, conditionally blocked transcription elongation by polIII in vitro in HeLa cell nuclear extracts. Arrest of elongation by polIII dramatically reduced overall levels of transcription and directed the synthesis of shortened transcripts, consistent with a block to polIII elongation at the boundary of the repressor/DNA complex. Removal of template-bound repressor with the allosteric inducer isopropylthio-β- d-galactoside (IPTG) allowed extension of nascent transcripts and restored transcriptional activity. Moreover, a subset of transcription complexes were shown to be capable of transcribing through the repressor obstacle lac repressor positioned just downstream of the natural termination site effected the premature termination of transcription but otherwise had no affect on the overall level of transcription. Our findings demonstrate that elongation and termination by mammalian polIII can be modulated in vitro by a heterologous sequence-specific DNA binding protein. Moreover, the ability to selectivity arrest elongation by polIII at defined positions within the tRNA gene transcription unit has permitted the identification of discrete functional properties of paused mammalian polIII ternary complexes.

Regulation of the human general transcription initiation factor TFIIF by phosphorylation.

The transcription initiation factor, TFIIF, is essential not only for the initiation of transcription but also for efficient elongation of mRNA synthesis by mammalian RNA polymerase II and is extensively phosphorylated in vivo. The possible regulation of TFIIF activity by protein phosphorylation was investigated by comparing the biochemical properties of alkaline phosphatase-treated HeLa TFIIF with those of native or bacterially expressed factor. Alkaline phosphatase treatment decreased the size of the large subunit (RAP74) of TFIIF to that of the recombinant protein but did not change the size of the small subunit (RAP30). Both the transcription initiation and elongation stimulating activities of the alkaline phosphatase-treated TFIIF decreased to 15-20% of the native form under conditions in which the amount of TFIIF was rate-limiting for transcription. Furthermore, phosphatase-treated TFIIF assembled the DBPolF complex and bound to RNA polymerase II less efficiently than the native protein. When hybrid TFIIFs were reconstituted using native or recombinant subunits, a native form of RAP74 stimulated both transcription and DBPolF complex formation activity regardless of whether native or recombinant RAP30 was used. We propose that TFIIF activity is regulated by protein phosphorylation, particularly of the RAP74 subunit. The functional role of RAP74 in assembling the preinitiation complex and modulating TFIIF activity is discussed.

DNA sequence requirements for transcriptional initiator activity in mammalian cells

A transcriptional initiator (Inr) for mammalian RNA polymerase II can be defined as a DNA sequence element that overlaps a transcription start site and is sufficient for (i) determining the start site location in a promoter that lacks a TATA box and (ii) enhancing the strength of a promoter that contains a TATA box. We have prepared synthetic promoters containing random nucleotides downstream of Sp1 binding sites to determine the range of DNA sequences that convey Inr activity. Numerous sequences behaved as functional Inrs in an in vitro transcription assay, but the Inr activities varied dramatically. An examination of the functional elements revealed loose but consistent sequence requirements, with the approximate consensus sequence Py Py A+1 N T/A Py Py. Most importantly, almost every functional Inr that has been described fits into the consensus sequence that we have defined. Although several proteins have been reported to bind to specific Inrs, manipulation of those elements failed to correlate protein binding with Inr activity. The simplest model to explain these results is that all or most Inrs are recognized by a universal binding protein, similar to the functional recognition of all TATA sequences by the same TATA-binding protein. The previously reported proteins that bind near specific Inr elements may augment the strength of an Inr or may impart transcriptional regulation through an Inr.

DNA sequence requirements for transcriptional initiator activity in mammalian cells.

A transcriptional initiator (Inr) for mammalian RNA polymerase II can be defined as a DNA sequence element that overlaps a transcription start site and is sufficient for (i) determining the start site location in a promoter that lacks a TATA box and (ii) enhancing the strength of a promoter that contains a TATA box. We have prepared synthetic promoters containing random nucleotides downstream of Sp1 binding sites to determine the range of DNA sequences that convey Inr activity. Numerous sequences behaved as functional Inrs in an in vitro transcription assay, but the Inr activities varied dramatically. An examination of the functional elements revealed loose but consistent sequence requirements, with the approximate consensus sequence Py Py A+1 N T/A Py Py. Most importantly, almost every functional Inr that has been described fits into the consensus sequence that we have defined. Although several proteins have been reported to bind to specific Inrs, manipulation of those elements failed to correlate protein binding with Inr activity. The simplest model to explain these results is that all or most Inrs are recognized by a universal binding protein, similar to the functional recognition of all TATA sequences by the same TATA-binding protein. The previously reported proteins that bind near specific Inr elements may augment the strength of an Inr or may impart transcriptional regulation through an Inr.

RNA polymerase II transcription factor SIII. II. Functional properties and role in RNA chain elongation.

A novel transcription factor that stimulates synthesis of accurately initiated transcripts by mammalian RNA polymerase II has been identified and purified to apparent homogeneity from rat liver extracts (Bradsher, J. N., Jackson, K. W., Conaway, R. C., Conaway, J. W. (1993) J. Biol. Chem. 268, 25587-25593). This factor, which we designate SIII, has a native molecular mass of approximately 140 kDa and is composed of three polypeptides of 110, 18, and 15 kDa. In this report, we demonstrate that SIII stimulates promoter-specific transcription by increasing the overall rate of RNA chain elongation by RNA polymerase II. Results of pulse-chase experiments indicate that SIII does not need to be present during preinitiation complex formation or transcription initiation in order to stimulate promoter-specific transcription. In addition, SIII is able to stimulate the rate of RNA chain elongation by RNA polymerase II during transcription of double stranded oligo(dC)-tailed templates. Taken together, these findings indicate that the factor exerts its activity directly on the elongation complex.

Synthesis of reinitiated transcripts by mammalian RNA polymerase II is controlled by elongation factor SII.

Previous studies have revealed that the in vitro synthesis of reinitiated transcripts by RNA polymerase II requires an additional activity, designated reinitiation transcription factor (RTF), which is distinct from all of the general class II initiation factors. While further characterizing this activity, it was found that RTF displays properties indistinguishable from those of the RNA polymerase II elongation factor SII. In addition, Western blot analysis using SII-specific antibodies revealed that human SII is a major component in purified RTF preparations. The functional equivalence of the two proteins was established using recombinant SII, which proved fully capable of substituting for RTF in the reinitiation assay. In these reconstituted reactions, transcription complexes resulting from reinitiation events required SII to proceed through a 400 bp G-free cassette, while complexes resulting from the first round of initiations were SII-independent. Reinitiations can take place in the absence of SII; however, addition of the elongation factor is essential for full extension of the reinitiated transcripts. These results suggest that events taking place at the promoter (e.g. first-round initiations versus reinitiations) can create marked differences in the properties of RNA polymerase II elongation complexes.

RNA polymerase II is a glycoprotein. Modification of the COOH-terminal domain by O-GlcNAc

The largest subunit of mammalian RNA polymerase II (RNAP II) contains at its carboxyl terminus an unusual domain consisting of 52 tandem repeats of the consensus sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser. This domain, designated the COOH-terminal domain (CTD), is essential for viability and is extensively phosphorylated during the transition from preinitiation complex assembly to elongation (1). Indeed, phosphorylation of the CTD may play an important regulatory role in this transition. We show here that the CTD is also modified by a novel form of protein glycosylation, O-GlcNAc. This modification has been found on numerous transcription factors and other nuclear and cytosolic proteins (2). Glycopeptides obtained by proteolytic digestion of the CTD were purified by reverse-phase high performance liquid chromatography and sequenced. Results from such experiments suggest that glycosylation occurs at multiple sites throughout the CTD, similar to the phosphorylation of this domain. The carbohydrate, however, is not detectable on the phosphorylated form of the enzyme. This observation is consistent with the idea that phosphorylation and glycosylation are mutually exclusive modifications. The CTD of RNAP II, therefore, appears to exist in three distinct conformational states: unmodified, phosphorylated, and glycosylated. The differential modification of the CTD may play an important role in the regulated expression of genes transcribed by RNA polymerase II.

Contacts between mammalian RNA polymerase II and the template DNA in a ternary elongation complex.

Elongation complexes of RNA polymerase II, RNA-DNA-enzyme ternary complexes, are intermediates in the synthesis of all eukaryotic mRNAs and are potential regulatory targets for factors controlling RNA chain elongation and termination. Analysis of such complexes can provide information concerning the structure of the catalytic core of the RNA polymerase and its interactions with the DNA template and RNA transcript. Knowledge of the structure of such complexes is essential in understanding the catalytic and regulatory properties of RNA polymerase. We have prepared and isolated complexes of purified RNA polymerase II halted at defined positions along a DNA template, and we have used deoxyribonuclease I (DNAse I) to map the interactions of the polymerase with the DNA template. DNAse I footprints of three specific ternary complexes reveal that the enzyme-template interactions of individual elongation complexes are not identical. The size of the protected region is distinct for each complex and varies from 48 to 55 bp between different complexes. Additionally, the positioning of the protected region relative to the active site varies in different complexes. Our results suggest that RNA polymerase II is a dynamic molecule and undergoes continual conformational transitions during elongation. These transitions are likely to be important in the processes of transcript elongation and termination and their regulation.

Factor-stimulated RNA polymerase II transcribes at physiological elongation rates on naked DNA but very poorly on chromatin templates.

We used an in vitro assay system based on HeLa cell core transcription components to examine transcript elongation by RNA polymerase II on either naked DNA or chromatin templates as a function of the three known elongation factors, IIS, TFIIF, and TFIIX. We demonstrate for the first time that mammalian RNA polymerase II can achieve physiological elongation rates on naked DNA templates in vitro. The addition of TFIIF alone gave this rate, although IIS was required to minimize the block to elongation at intrinsic termination sites. However, IIS and TFIIF provided only a slight increase in the very poor elongation efficiency of RNA polymerase II on chromatin templates. The addition of TFIIX to reactions containing IIS and TFIIF reduced the elongation rate on naked DNA templates but slightly increased the elongation efficiency on chromatin. The ability of elongation factors either separately or in combination to stimulate transcription on naked DNA and chromatin templates was also examined.

Recombinant TBP, transcription factor IIB, and RAP30 are sufficient for promoter recognition by mammalian RNA polymerase II.

Initiation of transcription by RNA polymerase II is a complex, multistep process which requires several accessory factors in addition to the polymerase itself. A critical event in transcription initiation is the specific association of RNA polymerase II with promoter DNA. In this report we show that three eukaryotic polypeptides, produced in Escherichia coli and purified to near homogeneity, constitute a minimal set of general transcription factors both necessary and sufficient for specific and stable promoter binding by RNA polymerase II. These polypeptides are the yeast TATA box binding protein TBP, the human general initiation factor TFIIB, and human RAP30, the small subunit of RAP30/74 (or transcription factor IIF). Formation of the polymerase-containing complex required only the TATA box, and not the initiator element (Inr), of the adenovirus major late promoter which was used in these experiments.

The interaction of RNA polymerase II with the adenovirus-2 major late promoter is precluded by phosphorylation of the C-terminal domain of subunit IIa.

Mammalian RNA polymerase II contains at the C terminus of its largest subunit an unusual domain consisting of 52 tandem repeats of the consensus sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser. The phosphorylation of this domain is thought to play an important role in the transition of RNA polymerase II from a preinitiation complex to an elongating complex. The unphosphorylated form of RNA polymerase II is designated IIA, whereas the phosphorylated form is designated IIO. In an effort to determine the consequence of C-terminal domain phosphorylation on complex formation, 32P-labeled RNA polymerases IIA and IIO were prepared and examined for their ability to form a stable preinitiation complex on the adenovirus-2 major late promoter in the presence of a reconstituted HeLa cell transcription extract. Preinitiation complexes were formed in the absence of ATP and purified from free RNA polymerase II by chromatography on Sepharose CL-4B. The state of phosphorylation of the largest subunit was monitored by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and the transcriptional activity was determined by assaying specific transcript formation upon the addition of nucleotides and a competing DNA template. RNA polymerase IIA was recovered in transcriptionally active complexes in reactions in which the input enzyme was RNA polymerase IIA. In reactions with RNA polymerase IIO as the input enzyme, no IIO was recovered in excluded fractions that normally contain preinitiation complex. In reactions with equimolar amounts of RNA polymerases IIO and IIA, purified preinitiation complexes contained almost exclusively RNA polymerase HA. These results support the idea that RNA polymerase II containing an unphosphorylated C-terminal domain preferentially associates with the adenovirus-2 major late promoter. The state of phosphorylation of the C-terminal domain can, therefore, directly influence preinitiation complex formation. We also report here the presence of an activity in HeLa cell extracts that catalyzes dephosphorylation of the C-terminal domain, thereby converting RNA polymerase IIO to IIA. This C-terminal domain phosphatase is specific in that it does not catalyze the dephosphorylation of a serine residue phosphorylated by casein kinase II. The presence of a C-terminal domain phosphatase in in vitro transcription reactions containing RNA polymerase IIO results in the formation of RNA polymerase IIA. This RNA polymerase IIA associates preferentially with preinitiation complexes.

DNA wrapping and bending by a mitochondrial high mobility group-like transcriptional activator protein.

Mitochondrial transcription factor 1 (mtTF1) is the only accessory protein known to be required for accurate and efficient promoter recognition by mammalian mitochondrial RNA polymerase. It activates transcription by binding immediately upstream of transcriptional start sites and shows an inherent flexibility in primary DNA sequence requirement. By application of a purification strategy designed for human and mouse mtTF1, a protein resembling mtTF1 was recently isolated from yeast mitochondria; its size (19 kDa), DNA-binding properties, and amino acid composition suggest identity to HM, a previously described abundant protein of yeast mitochondria. Both human and yeast proteins show a general ability to wrap or condense and unwind DNA in vitro and bend DNA at specific sequences. Recent determinations of the amino acid sequences of the human and yeast proteins reveal that both contain domains homologous to the nuclear high mobility group (HMG) proteins which have been implicated in diverse functions such as chromatin compaction and transcription stimulation. The ability to unwind and bend DNA may be fundamental to the documented roles of the mammalian protein in mitochondrial DNA transcription and replication priming and suggests a similar function for the yeast protein in yeast mitochondria.

Factors involved in specific transcription by mammalian RNA polymerase II. Identification and characterization of factor IIH.

Two new factors required for transcription of class II genes have been identified. These factors, TFIIH and TFIIJ, were required together with the previously described general factors (TFIIA, TFIIB, TFIID, TFIIE, and TFIIF) and RNA polymerase II for transcription of different class II genes. TFIIH was extensively purified, and the activity appeared to coelute with polypeptides of 33 and 95 kDa. The role of TFIIH and TFIIJ in preinitiation complex assembly was analyzed using mobility shift assays. It was found that TFIIH and TFIIJ association with the preinitiation complex was ordered and required the previous assembly of a preinitiation complex intermediate containing factors IID, IIB, IIF, IIE, and RNA polymerase II. A model for the ordered assembly of the general factors and RNA polymerase II is presented.

Polymerase II promoter activation: closed complex formation and ATP-driven start site opening.

Studies on bacterial RNA polymerases have divided the initiation pathway into three steps, namely (i) promoter binding to form the closed complex; (ii) DNA melting to form an open complex, and (iii) messenger RNA initiation. Potassium permanganate was used to detect DNA melting by mammalian RNA polymerase II in vitro. Closed complexes formed in a rate-limiting step that was stimulated by the activator GAL4-VP16. Adenosine triphosphate was then hydrolyzed to rapidly melt the DNA within the closed complex to form an open complex. Addition of nucleoside triphosphates resulted in the melted bubble moving away from the start site, completing initiation.

Factors Involved in Specific Transcription by Mammalian RNA Polymerase II: Purification and Analysis of Transcription Factor ILA and Identification of Transcription Factor IIJ

The previously described transcription factor IIA (TFIIA) protein fraction was separated into two factors that affect transcription, TFIIA and TFIIJ. TFIIA was found to have a stimulatory effect, and TFIIJ was found to be required for transcription. The requirement of TFIIJ was observed when bacterially produced purified human or yeast (Saccharomyces cerevisiae) TATA-binding protein (TBP) was used in lieu of the endogenous HeLa cell TFIID complex, suggesting that TFIIJ may be part of the TFIID complex. The stimulatory activity of TFIIA was found also to be dependent on the source of the TBP. Transcription reactions reconstituted with TFIID were stimulated by TFIIA; however, when human or yeast TBP was used instead of TFIID, TFIIA had no effect. TFIIA was found to interact with the TBP and was extensively purified by the use of affinity chromatography on columns containing immobilized recombinant yeast TBP. TFIIA is a heterotrimer composed of polypeptides of 34, 19, and 14 kDa. These three polypeptides were required to isolate, by using the gel mobility shift assay, a stable complex between TBP and the TATA box sequence.

Factors involved in specific transcription by mammalian RNA polymerase II: purification and analysis of transcription factor IIA and identification of transcription factor IIJ.

The previously described transcription factor IIA (TFIIA) protein fraction was separated into two factors that affect transcription, TFIIA and TFIIJ. TFIIA was found to have a stimulatory effect, and TFIIJ was found to be required for transcription. The requirement of TFIIJ was observed when bacterially produced purified human or yeast (Saccharomyces cerevisiae) TATA-binding protein (TBP) was used in lieu of the endogenous HeLa cell TFIID complex, suggesting that TFIIJ may be part of the TFIID complex. The stimulatory activity of TFIIA was found also to be dependent on the source of the TBP. Transcription reactions reconstituted with TFIID were stimulated by TFIIA; however, when human or yeast TBP was used instead of TFIID, TFIIA had no effect. TFIIA was found to interact with the TBP and was extensively purified by the use of affinity chromatography on columns containing immobilized recombinant yeast TBP. TFIIA is a heterotrimer composed of polypeptides of 34, 19, and 14 kDa. These three polypeptides were required to isolate, by using the gel mobility shift assay, a stable complex between TBP and the TATA box sequence.

Psychotrine and its O-methyl ether are selective inhibitors of human immunodeficiency virus-1 reverse transcriptase.

Psychotrine dihydrogen oxalate and O-methylpsychotrine sulfate heptahydrate (MP), the salts of isoquinoline alkaloids from ipecac, were found to be potent inhibitors of the DNA polymerase activity of human immunodeficiency virus-1 reverse transcriptase (HIV-1 RT). We currently report the results of additional studies designed to characterize the mechanism of inhibition facilitated by MP. The inhibition was noncompetitive with respect to TTP and uncompetitive with respect to poly(rA) and oligo(dT)12-18 (4:1) at low template-primer concentrations but competitive at high concentrations (greater than 200 microM). Identical non-Michaelis-type kinetics were observed when activated DNA was used as the template. The biphasic nature of the double-reciprocal plots and Hill coefficients of less than 1 indicate that MP functions as an allosteric inhibitor of the enzyme which appears to possess multiple active sites that interact in a cooperative (negative) fashion in the presence of the inhibitor. MP was selective for the recombinant HIV-1 RT (p66) utilizing poly(rA) and oligo(dT)12-18 (4:1) as template-primer. Greater inhibition was observed with this template primer as compared with other natural and synthetic template-primers tested. MP had significantly less effect on avian myeloblastosis virus RT as well as mammalian or bacterial DNA and RNA polymerases. Other members of the ipecac class of alkaloids, e.g. emetine hydrochloride, were inactive against all of these enzymes, including HIV-1 RT. Conversely, MP did not inhibit in vitro protein synthesis, a property manifested by all the other ipecac alkaloids tested. Studies conducted with structural analogs revealed that the imine functionality at positions 1' and 2' of MP is the key structural requirement for HIV-1 RT inhibitory activity. Therefore, MP appears to possess unique structural properties that enable interaction with HIV-1 RT in a manner that can be differentiated from other polymerases. Use of these alkaloids for the definition of this viral enzyme-specific topology may lead to the development of therapeutically useful chemotherapeutic agents.

Cooperative interaction of an initiator-binding transcription initiation factor and the helix–loop–helix activator USF

Transcription initiation by mammalian RNA polymerase II is effected by multiple common factors interacting through minimal promoter elements and regulated by gene-specific factors interacting with distal control elements. Minimal promoter elements that can function independently or together, depending on the specific promoter, include the upstream TATA box and a pyrimidine-rich initiator (Inr) overlapping the transcription start site. The binding of TFIID to the TATA element promotes the assembly of other factors into a preinitiation complex but factors which function at the Inr have not been defined. We show here that a novel factor (TFII-I) binds specifically to Inr elements, supports basal transcription from the adenovirus major late promoter and is immunologically related to the helix-loop-helix activator USF. We further show that TFII-I also binds to the upstream high-affinity USF site (E box), that USF also binds to the Inr, and that TFII-I and USF interact cooperatively at both Inr and E box sites. Thus, TFII-I represents a novel type of transcription initiation factor whose interactions at multiple promoter elements may aid novel communication mechanisms between upstream regulatory factors and the general transcriptional machinery.

Footprinting analysis of mammalian RNA polymerase II along its transcript: an alternative view of transcription elongation.

Ternary complexes of RNA polymerase II, bearing the nascent RNA transcript, are intermediates in the synthesis of all eukaryotic mRNAs and are implicated as regulatory targets of factors that control RNA chain elongation and termination. Information as to the structure of such complexes is essential in understanding the catalytic and regulatory properties of the RNA polymerase. We have prepared complexes of purified RNA polymerase II halted at defined positions along a DNA template and used RNase footprinting to map interactions of the polymerase with the nascent RNA. Unexpectedly, the transcript is sensitive to cleavage by RNases A and T1 at positions as close as 3 nucleotides from the 3'-terminal growing point. Ternary complexes in which the transcript has been cleaved to give a short fragment can retain that fragment and remain active and able to continue elongation. Since DNA.RNA hybrid structures are completely resistant to cleavage under our reaction conditions, the results suggest that any DNA.RNA hybrid intermediate can extend for no more than 3 base pairs, in dramatic contrast to recent models for transcription elongation. At lower RNase concentrations, the transcript is protected from cleavage out to about 24 nucleotides from the 3' terminus. We interpret this partial protection as due to the presence of an RNA binding site on the polymerase that binds the nascent transcript during elongation, a model proposed earlier by several workers in preference to the hybrid model. The properties of this RNA binding site are likely to play a central role in the process of transcription elongation and termination and in their regulation.