Structural and functional interactions of transcription factor (TF) IIA with TFIIE and TFIIF in transcription initiation by RNA polymerase II

A topological model for transcription initiation by RNA polymerase II (RNAPII) has recently been proposed. This model stipulates that wrapping of the promoter DNA around RNAPII and the general initiation factors TBP, TFIIB, TFIIE, TFIIF and TFIIH induces a torsional strain in the DNA double helix that facilitates strand separation and open complex formation. In this report, we show that TFIIA, a factor previously shown to both stimulate basal transcription and have co-activator functions, is located near the cross-point of the DNA loop where it can interact with TBP, TFIIE56, TFIIE34, and the RNAPII-associated protein (RAP) 74. In addition, we demonstrate that TFIIA can stimulate basal transcription by stimulating the functions of both TFIIE34 and RAP74 during the initiation step of the transcription reaction. These results provide novel insights into mechanisms of TFIIA function.

The RAP74 subunit of human transcription factor IIF has similar roles in initiation and elongation

Transcription factor IIF (TFIIF) is a protein allosteric effector for RNA polymerase II during the initiation and elongation phases of the transcription cycle. In initiation, TFIIF induces promoter DNA to wrap almost a full turn around RNA polymerase II in a complex that includes the general transcription factors TATA-binding protein, TFIIB, and TFIIE. During elongation, TFIIF also supports a more active conformation of RNA polymerase II. This conformational model for elongation is supported by three lines of experimental evidence. First, a region within the RNA polymerase II-associating protein 74 (RAP74) subunit of TFIIF (amino acids T154 to M177), a region that is critical for isomerization of the preinitiation complex, is also critical for elongation stimulation. Amino acid substitutions within this region are shown to have very similar effects on initiation and elongation, and mutagenic analysis indicates that L155, W164, N172, I176, and M177 are the most important residues in this region for transcription. Second, TFIIF is shown to have a higher affinity for rapidly elongating RNA polymerase II than for the stalled elongation complex, indicating that RNA polymerase II alternates between active and inactive states during elongation and that TFIIF stimulates elongation by supporting the active conformational state of RNA polymerase II. The deleterious I176A substitution in the critical region of RAP74 decreases the affinity of TFIIF for the active form of the elongation complex. Third, TFIIF is shown by Arrhenius analysis to stimulate elongation by populating an activated state of RNA polymerase II.

A region within the RAP74 subunit of human transcription factor IIF is critical for initiation but dispensable for complex assembly

Human transcription factor IIF (TFIIF) is an alpha(2)beta(2) heterotetramer of RNA polymerase II-associating 74 (RAP74) and RAP30 subunits. Mutagenic analysis shows that the N-terminal region of RAP74 between L155 (leucine at codon 155) and M177 is important for initiation. Mutants in this region have reduced activity in transcription, but none are inactive. Single amino acid substitutions at hydrophobic residues L155, W164, I176, and M177 have similar activity to RAP74(1-158), from which all but three amino acids of this region are deleted. Residual activity can be explained because each of these mutants forms a complex with RAP30 and recruits RNA polymerase II into the preinitiation complex. Mutants are defective for formation of the first phosphodiester bond from the adenovirus major late promoter but do not appear to have an additional significant defect in promoter escape. Negative DNA supercoiling partially compensates for the defects of TFIIF mutants in initiation, indicating that TFIIF may help to untwist the DNA helix for initiation.

DNA bending and wrapping around RNA polymerase: a "revolutionary" model describing transcriptional mechanisms

A model is proposed in which bending and wrapping of DNA around RNA polymerase causes untwisting of the DNA helix at the RNA polymerase catalytic center to stimulate strand separation prior to initiation. During elongation, DNA bending through the RNA polymerase active site is proposed to lower the energetic barrier to the advance of the transcription bubble. Recent experiments with mammalian RNA polymerase II along with accumulating evidence from studies of Escherichia coli RNA polymerase indicate the importance of DNA bending and wrapping in transcriptional mechanisms. The DNA-wrapping model describes specific roles for general RNA polymerase II transcription factors (TATA-binding protein [TBP], TFIIB, TFIIF, TFIIE, and TFIIH), provides a plausible explanation for preinitiation complex isomerization, suggests mechanisms underlying the synergy between transcriptional activators, and suggests an unforseen role for TBP-associating factors in transcription.

Functions of the N- and C-terminal domains of human RAP74 in transcriptional initiation, elongation, and recycling of RNA polymerase II

Transcription factor IIF (TFIIF) cooperates with RNA polymerase II (pol II) during multiple stages of the transcription cycle including preinitiation complex assembly, initiation, elongation, and possibly termination and recycling. Human TFIIF appears to be an alpha2beta2 heterotetramer of RNA polymerase II-associating protein 74- and 30-kDa subunits (RAP74 and RAP30). From inspection of its 517-amino-acid (aa) sequence, the RAP74 subunit appears to comprise separate N- and C-terminal domains connected by a flexible loop. In this study, we present functional data that strongly support this model for RAP74 architecture and further show that the N- and C-terminal domains and the central loop of RAP74 have distinct roles during separate phases of the transcription cycle. The N-terminal domain of RAP74 (minimally aa 1 to 172) is sufficient to deliver pol II into a complex formed on the adenovirus major late promoter with the TATA-binding protein, TFIIB, and RAP30. A more complete N-terminal domain fragment (aa 1 to 217) strongly stimulates both accurate initiation and elongation by pol II. The region of RAP74 between aa 172 and 205 and a subregion between aa 170 and 178 are critical for both accurate initiation and elongation, and mutations in these regions have similar effects on initiation and elongation. Based on these observations, RAP74 appears to have similar functions in initiation and elongation. The central region and the C-terminal domain of RAP74 do not contribute strongly to single-round accurate initiation or elongation stimulation but do stimulate multiple-round transcription in an extract system.

RAP74 induces promoter contacts by RNA polymerase II upstream and downstream of a DNA bend centered on the TATA box

RAP74, the large subunit of transcription factor IIF, associates with a preinitiation complex containing RNA polymerase II (pol II) and other general initiation factors. We have mapped the location of RAP74 in close proximity to promoter DNA at similar distances both upstream and downstream of a DNA bend centered on the TATA box. Binding of RAP74 induces a conformational change that affects the position of pol II relative to that of the DNA. This reorganization of the preinitiation complex minimally requires the N-terminal region of RAP74 containing both its RAP30-binding domain and another region necessary for accurate transcription in vitro. We propose a role for RAP74 in controlling the topological organization of the pol II preinitiation complex.

Cdc73p and Paf1p are found in a novel RNA polymerase II-containing complex distinct from the Srbp-containing holoenzyme

The products of the yeast CDC73 and PAF1 genes were originally identified as RNA polymerase II-associated proteins. Paf1p is a nuclear protein important for cell growth and transcriptional regulation of a subset of yeast genes. In this study we demonstrate that the product of CDC73 is a nuclear protein that interacts directly with purified RNA polymerase II in vitro. Deletion of CDC73 confers a temperature-sensitive phenotype. Combination of the cdc73 mutation with the more severe paf1 mutation does not result in an enhanced phenotype, indicating that the two proteins may function in the same cellular processes. To determine the relationship between Cdc73p and Paf1p and the recently described holoenzyme form of RNA polymerase II, we created yeast strains containing glutathione S-transferase (GST)-tagged forms of CDC73, PAF1, and TFG2 functionally replacing the chromosomal copies of the genes. Isolation of GST-tagged Cdc73p and Paf1p complexes has revealed a unique form of RNA polymerase II that contains both Cdc73p and Paf1p but lacks the Srbps found in the holoenzyme. The Cdc73p-Paf1p-RNA polymerase II-containing complex also includes Gal11p, and the general initiation factors TFIIB and TFIIF, but lacks TBP, TFIIH, and transcription elongation factor TFIIS as well as the Srbps. The Srbp-containing holoenzyme does not include either Paf1p or Cdc73p, demonstrating that these two forms of RNA polymerase II are distinct. In confirmation of the hypothesis that the two forms coexist in yeast cells, we found that a TFIIF-containing complex isolated via the GST-tagged Tfg2p construct contains both (i) the Srbps and (ii) Cdc73p and Paf1p. The Srbps and Cdc73p-Paf1p therefore appear to define two complexes with partially redundant, essential functions in the yeast cell. Using the technique of differential display, we have identified several genes whose transcripts require Cdc73p and/or Paf1p for normal levels of expression. Our analysis suggests that there are multiple RNA polymerase II-containing complexes involved in the expression of different classes of protein-coding genes.

A novel collection of accessory factors associated with yeast RNA polymerase II

A relatively simple subset of general transcription factors is sufficient for transcript initiation by RNA polymerase II. However, a recently identified "holoenzyme" contains additional accessory proteins required for mediating signals from some activators (Y-J. Kim et al., 1994, Cell 77, 599-608; A. Koleske and R. Young, 1994, Nature 368, 466-469). By immobilizing RNA polymerase II and associated proteins (RAPs) from a transcriptionally active yeast extract, we have identified a novel collection of proteins distinct from those found in the holoenzyme. The eluted RAP fraction did not contain the holoenzyme components Srb2,4,5 + 6p, Gal11p, or Sug1p, but did include the known transcription factors TFIIB and TFIIS and the three subunits of yeast TFIIF (Ssu71p/Tfg1p, Tfg2p, and Anc1p/Tfg3p). Also isolated as RAPs are two proteins (Cdc73p and Paf1p) with interesting connections to gene expression. Mutations in CDC73 and PAF1 affect cell growth and the abundance of transcripts from a subset of yeast genes (X. Shi et al., Mol. Cell. Biol., 1996 16, 669-676). The RAP fraction may therefore define one or more functional forms of RNA polymerase II distinct from the activator-mediating holoenzyme.

RNA polymerase II-associated protein (RAP) 74 binds transcription factor (TF) IIB and blocks TFIIB-RAP30 binding

A set of deletion mutants of human RNA polymerase II-associated protein (RAP) 30, the small subunit of transcription factor IIF (TFIIF; RAP30/74), was constructed to map functional domains. Mutants were tested for accurate transcriptional activity, RAP74 binding, and TFIIB binding. Transcription assays indicate the importance of both N- and C-terminal sequences for RAP30 function. RAP74 binds to the N-terminal region of RAP30 between amino acids 1 and 98. TFIIB binds to an overlapping region of RAP30, localized to amino acids 1-176 (amino acids 27-152 comprise a minimal binding region). The C-terminal region of RAP74 (amino acids 358-517) binds directly and independently to TFIIB. Interestingly, RAP74 blocks TFIIB-RAP30 binding, both by binding TFIIB and by binding RAP30. When the TFIIF complex is intact, therefore, TFIIB-TFIIF contact is maintained through RAP74. If the TFIIB-RAP30 interaction is physiologically important, the TFIIF complex must dissociate within some transcription complexes.

Paf1p, an RNA polymerase II-associated factor in Saccharomyces cerevisiae, may have both positive and negative roles in transcription

Regulated transcription initiation requires, in addition to RNA polymerase II and the general transcription factors, accessory factors termed mediators or adapters. We have used affinity chromatography to identify a collection of factors that associate with Saccharomyces cerevisiae RNA polymerase II (P. A. Wade, W. Werel, R. C. Fentzke, N. E. Thompson, J. F. Leykam, R. R. Burgess, J. A. Jaehning, and Z. F. Burton, submitted for publication). Here we report identification and characterization of a gene encoding one of these factors, PAF1 (for RNA polymerase-associated factor 1). PAF1 encodes a novel, highly charged protein of 445 amino acids. Disruption of PAF1 in S. cerevisiae leads to pleiotropic phenotypic traits, including slow growth, temperature sensitivity, and abnormal cell morphology. Consistent with a possible role in transcription, Paf1p is localized to the nucleus. By comparing the abundances of many yeast transcripts in isogenic wild-type and paf1 mutant strains, we have identified genes whose expression is affected by PAF1. In particular, disruption of PAF1 decreases the induction of the galactose-regulated genes three- to fivefold. In contrast, the transcript level of MAK16, an essential gene involved in cell cycle regulation, is greatly increased in the paf1 mutant strain. Paf1p may therefore be required for both positive and negative regulation of subsets of yeast genes. Like Paf1p, the GAL11 gene product is found associated with RNA polymerase II and is required for regulated expression of many yeast genes including those controlled by galactose. We have found that a gal11 paf1 double mutant has a much more severe growth defect than either of the single mutants, indicating that these two proteins may function in parallel pathways to communicate signals from regulatory factors to RNA polymerase II.

Functional domains of human RAP74 including a masked polymerase binding domain

RAP74, the large subunit of human transcription factor IIF (TFIIF), has been analyzed by deletion mutagenesis and in vitro assays to map functional domains. Tight binding to the RAP30 subunit involves amino acids between positions 1-172. Amino acids 1-205 are minimally sufficient to stimulate accurate transcription from the adenovirus major late promoter in an extract system, although C-terminal sequences contribute to activity. A partially masked RNA polymerase II binding domain has been mapped to the C-terminal region of the protein (amino acids 363-444). Sequences near the N terminus and within the central portion of RAP74 affect accessibility of this domain. Extending this domain to 363-486 creates a peptide that binds polymerase and DNA and inhibits transcription initiation in vitro from non-promoter DNA sites. This larger C-terminal domain may modify polymerase interaction with template during initiation and/or elongation of RNA chains.

The activity of COOH-terminal domain phosphatase is regulated by a docking site on RNA polymerase II and by the general transcription factors IIF and IIB

Each cycle of transcription appears to be associated with the reversible phosphorylation of the repetitive COOH-terminal domain (CTD) of the largest RNA polymerase (RNAP) II subunit. The dephosphorylation of RNAP II by CTD phosphatase, therefore, plays an important role in the transcription cycle. The following studies characterize the activity of HeLa cell CTD phosphatase with a special emphasis on the regulation of CTD phosphatase activity. Results presented here suggest that RNAP II contains a docking site for CTD phosphatase that is essential in the dephosphorylation reaction and is distinct from the CTD. This is supported by the observations that (a) phosphorylated recombinant CTD is not a substrate for CTD phosphatase, (b) RNAP IIB, which lacks the CTD, and RNAP IIA are competitive inhibitors of CTD phosphatase and (c) CTD phosphatase can form a stable complex with RNAP II. To test the possibility that the general transcription factors may be involved in the regulation of CTD phosphatase, CTD phosphatase activity was examined in the presence of recombinant or highly purified general transcription factors. TFIIF stimulates CTD phosphatase activity 5-fold. The RAP74 subunit of TFIIF alone contained the stimulatory activity and the minimal region sufficient for stimulation corresponds to COOH-terminal residues 358-517. TFIIB inhibits the stimulatory activity of TFIIF but has no effect on CTD phosphatase activity in the absence of TFIIF. The potential importance of the docking site on RNAP II and the effect of TFIIF and TFIIB in regulating the dephosphorylation of RNAP II at specific times in the transcription cycle are discussed.

Importance of codon preference for production of human RAP74 and reconstitution of the RAP30/74 complex

RAP30 and RAP74 are subunits of RAP30/74 (TFIIF, beta gamma), a general initiation and elongation factor for transcription by RNA polymerase II. Methods were previously published for production of human RAP30 and RAP74 in bacterial cells, using a bacteriophage T7 promoter expression system. The vectors described for production of RAP74 were not very efficient and produced significant quantities of RAP74 amino terminal fragments. To improve these vectors, a segment of the human RAP74 cDNA was recoded using a preferred set of codons for translation in Escherichia coli. Recoding dramatically improved protein production and suppressed production of amino-terminal fragments. Improved vectors are reported that produce RAP74 with an LEHHHHHH carboxy-terminal extension (RAP74-H6), for purification on a Ni(2+)-affinity column, and also with the native carboxy terminus (RAP74). Methods for purification of RAP74-H6 and RAP74 are reported. Using these improved vectors, approximately 30 mg of soluble and active RAP74-H6 or RAP74 can be produced and purified from 1 liter of E. coli culture, representing a 10-fold improvement in protein production. Methods have also been developed for reconstitution of native RAP30/74 complex using recombinant proteins. This complex has indistinguishable activity from human RAP30/74 for accurate transcription in vitro.

Functional analysis of Drosophila factor 5 (TFIIF), a general transcription factor

Factor 5 is a Drosophila RNA polymerase II initiation factor that also affects the elongation phase of transcription. We have used a cDNA encoding the large subunit of factor 5 (F5a) to produce recombinant F5a (rF5a). Antibodies directed against peptides deduced from the sequence of the F5a cDNA recognized rF5a and the large subunit of factor 5 purified from Kc cells. A chimeric human/fly factor composed of the small subunit of human TFIIF (RAP30) and rF5a stimulated elongation by Drosophila RNA polymerase II when assayed using a dC-tailed template. In addition, the chimeric human/fly factor functioned during initiation in either the Drosophila or human system. Therefore, the structure of the large subunit of TFIIF is sufficiently conserved from human to fly to allow functional interaction with both the small subunit of TFIIF and RNA polymerase II from either species. Analysis of deletion mutants of F5a indicated that almost all of the protein was required for initiation while only the NH2-terminal region was required for stimulating transcriptional elongation. A comparison of our results with those obtained with RAP74 suggest that the carboxyl terminal region of the protein may be involved in interactions with RNA polymerase II or other factors during initiation.

RAP30/74 (transcription factor IIF) is required for promoter escape by RNA polymerase II

RNA polymerase II-associating proteins (RAP30 and RAP74) are subunits of the transcription factor called variously RAP30/74, TFIIF, beta gamma, and FC. This factor is required for accurate transcription by RNA polymerase II, in addition to other basal transcription factors. Using recombinant human RAP30 and RAP74, the functions of these subunits have been tested separately during the initiation and elongation phases of transcription. RAP30 is required to form a Sarkosyl-resistant complex at 0.25% Sarkosyl, so RAP30 is required for initiation. RAP74, however, stimulates transcription when added after Sarkosyl, indicating that RAP74 is dispensable for initiation. The same result is obtained using a pulse-chase protocol in which accurately initiated RNA is labeled during a short pulse, followed by a chase with excess unlabeled nucleoside triphosphates. RAP30 is required in order to label the transcript during the pulse, but RAP74 is not. RAP74 must be added during the chase, however, in order to obtain a short runoff transcript. The following conclusions can be drawn from these experiments: 1) RAP30 is an initiation factor; 2) RAP74 is not required for ATP hydrolysis in initiation, which precedes phosphodiester bond formation; 3) RAP74 is not required for template strand separation; 4) RAP74 is not required to initiate phosphodiester bond formation; and 5) RAP74 is required for very early elongation.

Production of human RAP30 and RAP74 in bacterial cells

RAP30 and RAP74 are subunits of RAP30/74 (TFIIF), a general initiation and elongation factor for transcription by RNA polymerase II. Complementary DNA (cDNA) clones have previously been reported encoding human RAP30 and RAP74. Here we report expression of these cDNAs using a T7 RNA polymerase system in Escherichia coli. Production of human RAP30 was very efficient using the expression vector pET11d. RAP30 accumulated within inclusion bodies and was solubilized using guanidine hydrochloride. After removal of the denaturant, RAP30 was soluble and active in accurate transcription. Approximately 44 mg of highly purified and soluble RAP30 was obtained from a 1-liter culture of cells. Production of RAP74 was more problematic, because a mixture of full length RAP74 and RAP74 fragments was produced in E. coli. Most RAP74 fragments were shortened by deletion of the COOH-terminus of the protein and probably resulted from premature translation termination. RAP74 was most successfully produced using a pET23d construct, in which the RAP74 peptide was fused to a short polyhistidine stretch at its COOH-terminus. Addition of the polyhistidine sequence allowed purification using a Ni2+ affinity resin. Full length RAP74 carrying this polyhistidine extension was purified in a single step by Ni2+ affinity chromatography in 4 M urea; the yield of RAP74 was approximately 3 mg from a 1-liter culture of cells. RAP74 derivatized with a polyhistidine stretch at its NH2-terminus, on the other hand, remained contaminated with RAP74 fragments after Ni2+ affinity chromatography.(ABSTRACT TRUNCATED AT 250 WORDS)

A cDNA encoding RAP74, a general initiation factor for transcription by RNA polymerase II

RAP30/74 (also known as TFIIF, beta gamma and FC is one of several general factors required for initiation by RNA polymerase II. The small RAP30 subunit of RAP30/74 binds directly to polymerase and appears structurally and functionally homologous to bacterial sigma factors in their RNA polymerase-binding region. RAP30/74 or recombinant RAP30 suppresses nonspecific binding of RNA polymerase II to DNA and is required for RNA polymerase II to assemble stably into a preinitiation complex containing promoter DNA and the general factors TFIID, TFIIA and TFIIB; both RAP30 and RAP74 are physical components of the preinitiation complex. A complementary DNA encoding human RAP30 has been isolated, and here we report the isolation of a cDNA encoding human RAP74. RAP30 and RAP74 produced in Escherichia coli can be used in place of natural human RAP30/74 to direct accurate transcription initiation by RNA polymerase II in vitro.

The small subunit of transcription factor IIF recruits RNA polymerase II into the preinitiation complex

We found that transcription factor IIF mediates the association of RNA polymerase II with promoter sequences containing transcription factors IID, IIB, and IIA (DAB complex). The resulting DNA-protein complex contained RNA polymerase II and the two subunits of transcription factor IIF (RAP 30 and RAP 74). Cloned human RAP 30 was sufficient for the recruitment of RNA polymerase II to the DAB complex. This ability of RAP 30 to recruit RNA polymerase to a promoter is also a characteristic of sigma factors in prokaryotes.

Structure and associated DNA-helicase activity of a general transcription initiation factor that binds to RNA polymerase II

RAP30/74 is a heteromeric general transcription initiation factor which binds to RNA polymerase II. Here we report that preparations of RAP30/74 contain an ATP-dependent DNA helicase whose probable function is to melt the DNA at transcriptional start sites. The sequence of the RAP30 subunit of RAP30/74 indicates that RAP30 may be distantly related to bacterial sigma factors.

RAP30/74: a general initiation factor that binds to RNA polymerase II

We have previously shown by affinity chromatography that RAP30 and RAP74 are the mammalian proteins that have the highest affinity for RNA polymerase II. Here we show that RAP30 binds to RAP74 and that the RAP30-RAP74 complex (RAP30/74) is required for accurate initiation by RNA polymerase II. RAP30/74 is required for accurate transcription from the following promoters: the adenovirus major late promoter, the long terminal repeat of human immunodeficiency virus, P2 of the human c-myc gene, the mouse beta maj-globin promoter (all of which have TATA boxes), and the mouse dihydrofolate reductase promoter (which lacks a TATA box). RAP30/74 is not required for initiation by RNA polymerase III at the adenovirus virus-associated RNA promoters. Therefore, RAP30/74 is a general initiation factor that binds to RNA polymerase II.

Proteins that bind to RNA polymerase II are required for accurate initiation of transcription at the adenovirus 2 major late promoter

Extracts prepared from HeLa cell nuclei are inactivated for accurate transcription from the adenovirus 2 major late promoter (Ad2 MLP) by repeated passage over a column containing immobilized calf thymus RNA polymerase II. The capacity for accurate transcription is restored to these extracts by a fraction that is eluted from the RNA polymerase II column with 0.5 M KC1. This fraction contains RNA polymerase II-associating proteins (RAPs). RAPs are not required for the formation of a stable, promoter-associated pre-initiation complex. However, at least one RAP is required for the formation of the first phosphodiester bond at the Ad2 MLP, both when initiation depends only on the TATAAA box, and when initiation is stimulated by the upstream sequence of the promoter. Initiation occurs approximately 1 min after the addition of RAPs to initiation complexes formed in the absence of RAPs. Therefore, the RAP(s) that is an RNA polymerase II initiation factor functions late in the initiation pathway to convert a stable preinitiation complex to an initiation-competent complex.

Stringent response in Escherichia coli induces expression of heat shock proteins

The rpoD gene (encoding the 70,000 Mr sigma subunit of Escherichia coli RNA polymerase) is the most distal gene in an operon that contains three genes. The promoter-proximal gene is rpsU (encoding ribosomal protein S21) and the middle gene is dnaG (encoding DNA primase). During the stringent response, caused by a deficiency in an aminoacyl-tRNA, expression of rpsU is decreased, while expression of rpoD is not. This disco-ordinate regulation is due to increased transcription from a minor promoter upstream from rpoD, in the dnaG gene. Transcription from this promoter is also increased during the heat shock response. Expression of other heat shock proteins was found to increase during the stringent response. Thus, the stringent response in E. coli induces expression of heat shock proteins. The requirements for this stringent induction of the heat shock proteins differ from those for temperature induction during the heat shock response.

Nucleotide sequence of the rpsU-dnaG-rpoD operon from Salmonella typhimurium and a comparison of this sequence with the homologous operon of Escherichia coli

In Escherichia coli the genes encoding ribosomal protein S21 (rpsU), DNA primase (dnaG), and the 70-kDal sigma subunit of RNA polymerase (rpoD) are contained in a single operon. These gene products are involved in the initiation of translation, DNA replication, and transcription, respectively. We have examined the homologous region in the closely related bacterium Salmonella typhimurium and have found that the same three genes are similarly organized. We have sequenced the DNA for this operon in S. typhimurium and have compared the (nt) nucleotide and amino acid (aa) sequences with E. coli. In the coding regions, the sequence conservation varies from extremely high for rpsU to moderate for dnaG with respect to both nt and aa sequence. In the noncoding regions, sequences thought to be important for the regulation of transcription are conserved, while other sequences are not conserved. aa differences in DNA primase and sigma are not randomly distributed and suggest regions that may be important for protein structure or function.

Transcription from a heat-inducible promoter causes heat shock regulation of the sigma subunit of E. coli RNA polymerase

The rpoD gene encoding the sigma subunit of E. coli RNA polymerase is cotranscribed with rpsU and dnaG, encoding ribosomal protein S21 and DNA primase, respectively. After temperature upshift, a heat shock promoter (Phs) located within dnaG is transiently induced, causing increased transcription of rpoD. The extent of induction is sufficient to account for the heat shock response of sigma synthesis. The initiation site of this promoter was located about 360 bp upstream of rpoD by promoter cloning and S1 nuclease mapping. Plasmid deletions generated with Bal 31 nuclease show that the DNA sequence CTGCCACCC in the -44 to -36 region of this promoter is necessary for its heat shock activity. Heat induction of transcription from Phs is under the control of HtpR, a positive regulator of the heat shock response.

The operon that encodes the sigma subunit of RNA polymerase also encodes ribosomal protein S21 and DNA primase in E. coli K12

The sigma subunit of E. coli RNA polymerase is encoded by the rpoD gene. Within the sequence upstream from rpoD, we have identified the structural genes rpsU and dnaG, which encode the 30S ribosomal protein S21 and DNA primase, respectively. The three genes are in the order rpsU, dnaG rpoD, and are all encoded by the same DNA strand. Analysis of in vivo transcripts from this region shows that these genes are all within the same operon. By correlating the 5' and 3' ends of in vivo transcripts with our DNA sequence, we have identified several regulatory features of the operon. These features include tandem promoters upstream from rpsU, a terminator between rpsU and dnaG, an RNA processing site separating dnaG and rpoD, and the operon terminator just downstream from rpoD. Immediately upstream of the operon promoters is an active promoter for an unidentified gene. We discuss the regulatory significance of the operon features and the biological significance of an operon encoding proteins essential for translation, replication and transcription.