Promoter melting by T7 ribonucleic acid polymerase as detected by single-stranded endonuclease digestion

Sequential release of promoter contacts during transcription initiation to elongation transition

Bacteriophage T7 RNA polymerase undergoes major conformational changes as transcription proceeds from initiation to elongation. Using limited trypsin digestion and stopped-flow fluorescence kinetic methods, we have monitored promoter release, initial bubble collapse, and refolding of the 152-205 region (subdomain H), the latter being important for RNA channel formation. The kinetic studies show that the conformational changes are temporally coupled, commencing at the synthesis of 9 nt and completing by the synthesis of 12 nt of RNA. The temporal coupling of initial bubble collapse and RNA channel formation is proposed to facilitate proper binding of the RNA dissociated from the late initiation complexes into the RNA channel. Using promoter mutations, we have determined that promoter contacts are broken sequentially during transition from initiation to elongation. The specificity loop interactions are broken after synthesis of 8 nt or 9 nt of RNA, whereas the upstream promoter contacts persists up to synthesis of 12 nt of RNA. Both promoter contacts need to be broken for transition into elongation. The A-15C mutation resulted in efficient transition to elongation by synthesis of 9 nt of RNA, whereas the C-9A mutation resulted in early transition to elongation by synthesis of 7-8 nt of RNA. The effect of early promoter clearance in the mutant promoters was observed as reduced production of long abortive products.

Initial bubble collapse plays a key role in the transition to elongation in T7 RNA polymerase

RNA polymerases bind to specific sequences in DNA, melt open duplex DNA around the start site, and start transcription within the initially melted bubble. The initially transcribing complex is relatively unstable, releasing short abortive products. After synthesis of a minimal length of RNA (approximately 10-12 bases in the T7 system), RNA polymerases complete the transition to a processive (highly stable) elongation phase and lose the initial promoter contacts. The current study strongly supports a model for T7 RNA polymerase in which initial bubble collapse from position -4 to position +3 is responsible for initiating RNA displacement in the transition process. More specifically, collapse of the bubble from position -4 to position -1 indirectly and energetically facilitates the direct strand invasion offered by collapse at positions +1 to +3. Parallel work shows that promoter release, another key event occurring during this stage of transcription, begins after translocation to position +8 and is largely complete upon translocation to about position +12. The timing of promoter release agrees with the timing of initial bubble collapse determined by our previous fluorescence studies, suggesting that these two events are closely related.

Evidence for DNA bending at the T7 RNA polymerase promoter

Phage T7 RNA polymerase is the only DNA-dependent RNA polymerase for which we have a high-resolution structure of the promoter-bound complex. Recent studies with the more complex RNA polymerases have suggested a role for DNA wrapping in the initiation of transcription. Here, circular permutation gel retardation assays provide evidence that the polymerase does indeed bend its promoter DNA. A complementary set of experiments employing differential phasing from an array of phased A-tracts provides further evidence for both intrinsic and polymerase-induced bends in the T7 RNA polymerase promoter DNA. The bend in the complex is predicted to be about 40-60 degrees and to be centered around positions -2 to +1, at the start site for transcription, while the intrinsic bend is much smaller (about 10 degrees ). These results, viewed in the light of a recent crystal structure for the complex, suggest a mechanism by which binding leads directly to bending. Bending at the start site would then facilitate the melting necessary to initiate transcription.

Promoter specificity determinants of T7 RNA polymerase

The high specificity of T7 RNA polymerase (RNAP) for its promoter sequence is mediated, in part, by a specificity loop (residues 742-773) that projects into the DNA binding cleft (1). Previous work demonstrated a role for the amino acid residue at position 748 (N748) in this loop in discrimination of the base pairs (bp) at positions -10 and -11 (2). A comparison of the sequences of other phage RNAPs and their promoters suggested additional contacts that might be important in promoter recognition. We have found that changing the amino acid residue at position 758 in T7 RNAP results in an enzyme with altered specificity for the bp at position -8. The identification of two amino acid:base pair contacts (i.e., N748 with the bp at -10 and -11, and Q758 with the bp at -8) provides information concerning the disposition of the specificity loop relative to the upstream region of the promoter. The results suggest that substantial rearrangements of the loop (and/or the DNA) are likely to be required to allow these amino acids to interact with their cognate base pairs during promoter recognition.

Identification of a minimal binding element within the T7 RNA polymerase promoter

The T7 RNA polymerase promoter has been proposed to contain two domains: the binding region upstream of position -5 is recognized through apparently traditional duplex contacts, while the catalytic domain downstream of position -5 is bound in a melted configuration. This model is tested by following polymerase binding to a series of synthetic oligonucleotides representing truncations of the consensus promoter sequence. The increase in the fluorescence anisotropy of a rhodamine dye linked to the upstream end of the promoter provides a very sensitive measure of enzyme binding in simple thermodynamic titrations, and allows the determination of both increases and decreases in the dissociation constant. The best fit value of Kd=4.0 nM for the native promoter is in good agreement with previous fluorescence and steady state measurements. Deletion of the downstream DNA up to position -1 or to position -5 leads to a fivefold increase in binding, while further sequential single-base deletions upstream result in 20 and 500-fold decreases in binding. These results indicate that the (duplex) region of the promoter upstream of and including position -5 is both necessary and sufficient for tight binding, and represents the core binding element of the promoter. We propose a model in which part of the upstream binding energy is used by T7 RNA polymerase to melt the downstream initiation region of the promoter. We also show that the presence of magnesium is necessary for optimal binding, but not for specific enzyme-promoter complex formation, and we propose that magnesium is not required for melting of the promoter.

A mutant T7 RNA polymerase that is defective in RNA binding and blocked in the early stages of transcription

We have identified a mutation (E148A) in T7 RNA polymerase (RNAP) that results in an enzyme which aborts transcription primarily when the nascent RNA achieves a length of 5 nt. This phenomenon is observed at a consensus promoter, but is even more strongly observed at promoters that are altered in the initiation region. Although the abortive product is of a fixed length (5 nt), the positions of the base substitutions in the initiation region that enhance this effect do not appear to be fixed, and we have observed the effect with a variety of initiation-region promoter variants. The phenomenon is also observed during promoter-independent transcription when transcribing a homopolymeric template such as poly(dC). Under conditions where the active site of the RNAP cannot extend beyond the third nucleotide in the template strand and the maximum length of the RNA:DNA hybrid cannot exceed three base-pairs (i.e. when synthesizing oligoG products due to transcript slippage at a promoter that initiates with the sequence +1 GGG...) the mutant RNAP gives rise to a normal spectrum of products 2 to 14 nt in length with no evidence of a block at 5 nt. Neither promoter binding nor promoter melting appears to be involved in this phenotype, as the mutant RNAP binds normally to promoter sequences and the behavior of the enzyme is unaffected by removal of the non-template strand in the initiation region of the promoter or on a supercoiled template. Importantly, the mutant RNAP is defective in binding single strand oligomers of RNA. These results suggest that the affected region of the RNAP may form part of the RNA product binding site and may be involved in the transition from an unstable initiation complex to a stable elongation complex, perhaps by sensing the presence of a nascent RNA and/or RNA:DNA hybrid.

A shared, non-canonical DNA conformation detected at DNA/protein contact sites and bent DNA in the absence of supercoiling or cognate protein binding

A hybrid protein (H144), consisting of Lac repressor and T7 endonuclease I, binds at the lac operator and cleaves relaxed double-stranded DNA at distal but distinct sites. These sites are shown here to coincide with a bacterial promoter, a phage T7 promoter, a site for gyrase and intrinsically bent DNA. The targets do not seem to share a particular DNA sequence, and in bent DNA, cleavage occurs at the physical center rather than at the common A-tracts. These results indicate that protein contact sites and intrinsic bends assume a non-canonical conformation in the absence of supercoiling or cognate protein binding. This feature may serve as a recognition signal or facilitate protein binding to initiate transcription and recombination.

The stability of abortively cycling T7 RNA polymerase complexes depends upon template conformation

We have developed a promoter competition assay to determine whether T7 RNA polymerase dissociates from its template during abortive cycling. We find that the stability of the initiation complex (IC) depends upon the conformation of the promoter, and that the degree to which the template is unwound contributes importantly to the stability of the IC. On linear DNA or a relaxed plasmid template, the stability of the IC is very low (t1/2 < 1 min). However, on a supercoiled template, the IC has a stability that is comparable to that of a paused elongation complex (t1/2 = 14 min). At a synthetic promoter that is single stranded in the initiation region (from -5 and downstream), the polymerase forms a highly stable complex (t1/2 > 30 min) even in the absence of RNA synthesis. These findings are important to our understanding of the transition from the IC to an EC.

Crystal structure of bacteriophage T7 RNA polymerase at 3.3 A resolution

The crystal structure of T7 RNA polymerase reveals a molecule organized around a cleft that can accommodate a double-stranded DNA template. A portion (approximately 45%) of the molecule displays extensive structural homology to the polymerase domain of Klenow fragment and more limited homology to the human immunodeficiency virus HIV-1 reverse transcriptase. A comparison of the structures and sequences of these polymerases identifies structural elements that may be responsible for discriminating between ribonucleotide and deoxyribonucleotide substrates, and RNA and DNA templates. The relative locations of the catalytic site and a specific promoter recognition residue allow the orientation of the polymerase on the template to be defined.

Model for the mechanism of bacteriophage T7 RNAP transcription initiation and termination

Characterization of a mutant T7 RNA polymerase (RNAP) that is active on non-promoter templates but has lost the ability to selectively utilize the T7 promoter led to the finding that wild-type T7 RNAP initiates transcription at a high rate on non-promoter templates but that most (approximately 90%) of these initiation events lead to synthesis of dinucleotides only. The anomalously high activity of T7 RNAP on poly(dC) templates (relative to other non-promoter templates) is due to a reduction in the rate of transcription abortion after dinucleotide synthesis rather than an increase in initiation. Evidence is presented that the transition from abortive to processive transcription is associated with a conformational change in T7 RNAP. The stability of the nascent chain in a ternary complex is shown to increase with increasing chain length in the 2 to 14 base range even when the size of the complementary RNA-DNA hybrid remains constant and small (2 to 3 base-pairs). Two mutant polymerases that show increased release of transcripts during abortive transcription and a proteolytically nicked polymerase that exhibits reduced RNA binding are shown to have reduced ability to read-through a T7 RNAP hairpin U-stretch transcription terminator. Single-stranded nucleic acids are shown to bind more tightly than double-stranded nucleic acids to T7 RNAP. These observations and a large set of published studies on T7 RNAP structure and mechanism are accommodated in a relatively simple model of T7 RNAP transcription initiation and termination in which a T7 RNAP that has initiated transcription is proposed to be capable of assuming two functionally distinct conformations: an abortive conformer characterized by a loose association with the nascent RNA and an inability to translocate along the template; and a processive conformer characterized by the stable retention of the nascent RNA and the ability to process stably along the template. The equilibrium between these two conformations is shifted towards the processive form when the nascent chain binds at a site located at least partly on the T7 RNAP N-terminal domain. The interaction requires that the RNA be more than approximately nine bases and this RNAP-RNA interaction plays a primary role in retaining the RNA within the ternary complex.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of elongating T7 and SP6 RNA polymerases and their response to a roadblock generated by a site-specific DNA binding protein

As a means of generating homogeneous populations of elongation complexes with the RNA polymerases encoded by phages T7 and SP6, transcription has been carried out in vitro on templates associated with the Gln-111 mutant of EcoRI endonuclease. The Gln-111 protein, as a result of a single amino acid substitution at position 111, lacks cleavage function yet shows higher than wild-type affinity for the EcoRI recognition sequence GAATTC. On a series of linear and circular templates associated with Gln-111 protein, blockage of the phage RNA polymerase elongation complex is observed. The 3' endpoint of the major blocked-length RNA species, just 3 bp upstream from the GAATTC, reveals an extremely close approach of polymerase's leading edge to essential contacts between Gln-111 protein and its binding site. In contrast to E. coli RNA polymerase, which is blocked stably and quantitatively by Gln-111 protein (Pavco, P.A. and Steege, D. A. (1990) J. Biol. Chem. 265, 9960-9969), the phage polymerases show substantial levels of readthrough transcription beyond the protein block.

Displacement of Xenopus transcription factor IIIA from a 5S rRNA gene by a transcribing RNA polymerase

In the absence of other components of the RNA polymerase III transcription machinery, transcription factor IIIA (TFIIIA) can be displaced from both strands of its DNA-binding site (the internal control region) on the somatic-type 5S rRNA gene of Xenopus borealis during transcription elongation by bacteriophage T7 RNA polymerase, regardless of which DNA strand is transcribed. Furthermore, substantial displacement is observed after the template has been transcribed only once. Since the complete 5S rRNA transcription complex has previously been shown to remain stably bound to the gene during repeated rounds of transcription by either RNA polymerase III or bacteriophage SP6 RNA polymerase, these results indicate that a factor(s) in addition to TFIIIA is required to create a complex that will remain stably associated with the template during transcription. Thus, transcription complex stability during passage of RNA polymerase cannot be explained solely on the basis of the DNA-binding properties of TFIIIA.

Displacement of Xenopus transcription factor IIIA from a 5S rRNA gene by a transcribing RNA polymerase

In the absence of other components of the RNA polymerase III transcription machinery, transcription factor IIIA (TFIIIA) can be displaced from both strands of its DNA-binding site (the internal control region) on the somatic-type 5S rRNA gene of Xenopus borealis during transcription elongation by bacteriophage T7 RNA polymerase, regardless of which DNA strand is transcribed. Furthermore, substantial displacement is observed after the template has been transcribed only once. Since the complete 5S rRNA transcription complex has previously been shown to remain stably bound to the gene during repeated rounds of transcription by either RNA polymerase III or bacteriophage SP6 RNA polymerase, these results indicate that a factor(s) in addition to TFIIIA is required to create a complex that will remain stably associated with the template during transcription. Thus, transcription complex stability during passage of RNA polymerase cannot be explained solely on the basis of the DNA-binding properties of TFIIIA.

Processivity of T7 RNA polymerase requires the C-terminal Phe882-Ala883-COO- or "foot"

The role of the C-terminal Phe882-Ala883 residues of bacteriophage T7 RNA polymerase in specific transcription has been investigated by means of site-directed mutagenesis. A mutant enzyme that lacks the C-terminal Phe882-Ala883 residues, denoted the "foot" mutant, has been cloned and overproduced, and the effects of the deletion on promoter recognition, initiation, and elongation have been determined. Gel retardation assays and DNase I footprinting show that the foot mutant specifically recognizes and binds to T7 promoters, although this binding appears to be approximately 30-fold weaker than that of the wild-type enzyme. Transcription assays using oligonucleotide templates that contain the consensus T7 promoter show a dramatic decrease in transcriptional activity for the foot mutant. With templates whose coding region begins CCC..., the mutant synthesizes poly(G) products even in the presence of all four nucleotides. The synthesis of poly(G) products from such templates has previously been observed for the wild-type enzyme when GTP is the sole nucleotide present in the reaction and is thought to occur by a novel mechanism involving slippage of the RNA chain 3' to 5' relative to the template [Martin, C.T., Muller, D.K., & Coleman, J.E. (1988) Biochemistry 27, 3966-3974]. These data suggest that the loss in transcriptional activity by the foot mutant results from a severe decrease in processivity as well as catalytic efficiency of the enzyme. Removal of the C-terminal Phe and Ala residues from the wild-type enzyme with carboxypeptidase A generates the phenotype of the mutant precisely, proving that all of the properties of the foot mutant derive from the loss of the Phe-Ala-COOH moiety.(ABSTRACT TRUNCATED AT 250 WORDS)

Processivity of proteolytically modified forms of T7 RNA polymerase

Two proteolytically modified forms of T7 RNA polymerase have been characterized with respect to transcription initiation and processivity. One species, denoted 80K-20K, is singly cleaved within the region of the polypeptide chain between amino acids 172 and 180. The second species, denoted 80K, is generated by extensive proteolysis of the N-terminal 20K domain by trypsin. The 80K-20K form is fully active in initiation and escape from abortive cycling. It is deficient only in processivity on long DNA templates. Likewise, the 80K species shows initiation kinetics and abortive product synthesis similar to those of the native enzyme. This latter species, however, is unable to escape abortive cycling and shows no synthesis of transcripts longer than about eight bases. Studies of RNA and DNA binding to the three different forms of the enzyme by gel retention assays reveal that the native (98K), the 80K-20K, and the 80K species all form specific complexes with promoter-containing DNA. In addition, the native enzyme binds nonspecifically to double-stranded DNA, while the 80K-20K and 80K enzymes do not. The native enzyme also binds RNA. This RNA binding is reduced in the 80K-20K enzyme and is absent in the 80K species. We suggest a model for T7 RNA polymerase wherein the 20K N-terminal domain of the protein or a shared region between the N- and the C-terminal domains of the protein forms a nonspecific polynucleotide binding site.(ABSTRACT TRUNCATED AT 250 WORDS)

Bacteriophage T7 late promoters with point mutations: quantitative footprinting and in vivo expression

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Construction of bacteriophage T7 late promoters with point mutations and characterization by in vitro transcription properties

This paper describes the construction of 18 cloned bacteriophage T7 late promoters with single point mutations. In vitro transcription experiments were used to characterize the properties of these promoters. Since the mutated promoters are cloned into identical backgrounds, differences seen in the transcription assays are directly attributable to the point mutations. All of the mutated promoters are less active than wildtype, but they can be divided into two types. Type A mutations map from -4 to +1 and reduce promoter activity when the template is linearized or when 60mM NaCl is added to the reaction buffer. Type B mutations map from -9 to -7 and reduce promoter activity under all conditions tested. At several sites all three possible point mutations are available. At these sites we observed hierarchies of base pair preference, as determined by promoter activity, that may indicate that T7 RNA polymerase interacts with groups in the major groove.

Comparison of the open complexes formed by RNA polymerase at the Escherichia coli lac UV5 promoter

In transcription initiation at the lac UV5 promoter, Escherichia coli RNA polymerase forms two open complexes, called Ou and O1, which can be separated by electrophoresis on native polyacrylamide gels. We have compared the properties of these two open complexes, with the objective of rationalizing the functional difference previously reported between the two forms: the complex which is dominant at high temperature (Ou) is better able to escape abortive transcriptional cycling into productive mRNA elongation. Methylation protection and binding domain probing with exonuclease III were used to investigate differences in polymerase binding strength to particular DNA domains. Also, we examined the difference in the extent and temperature dependence of promoter unwinding in the two complexes, as probed by methylation of unpaired cytosines and cleavage by phage T7 endonuclease. We find that O1 has stronger promoter interactions in the DNA domain whose upstream edge is defined by an exonuclease III stop at -24. These -24 domain interactions, which presumably aid in promoter binding and nucleation of DNA unwinding, are inferred to be strong enough to hinder escape of the polymerase from the open complex contacts that are maintained during abortive initiation. The Ou complex has weaker binding to the -24 domain, partially compensated by better upstream interactions and a better ability to accommodate extensive DNA unwinding. It thus escapes abortive initiation more readily because of weaker critical open complex contacts that must be lost when stable initiation occurs from the corresponding stressed intermediates.

Gene 3 endonuclease of bacteriophage T7 resolves conformationally branched structures in double-stranded DNA

Gene 3 endonuclease of bacteriophage T7 has been expressed from the cloned gene, purified, and characterized as to its activity on different DNA substrates. Besides its known strong preference for cutting single-stranded DNA rather than double-stranded DNA, the enzyme has a strong preference for cutting conformationally branched structures in double-stranded DNA, either X or Y-shaped branches. Three types of branched DNA substrates were used: relaxed circular DNAs containing large cruciform structures (a model for Holliday structures, presumed intermediates in genetic recombination); X-shaped molecules having a limited potential for branch migration, made from the cloned phage and bacterial arms of the lambda attachment site; and Y-shaped molecules, made by hybridizing molecules homologous except for a 2 X 21 base-pair palindrome in one of them. Gene 3 endonuclease cuts two opposing strands at or near the branchpoint to resolve these substrates into linear molecules, and does not cut the potentially single-stranded tips of the stem-and-loop structure generated from the palindrome. The position of the cleavage points on the equivalent arm of two X-shaped molecules, constructed from wild-type and mutant lambda attachment sites, show that the enzyme can cut at several different sites within or slightly 5' of the limited region of branch migration. The various activities of gene 3 endonuclease are consistent with the known role of this enzyme in genetic recombination, in maturation and packaging of T7 DNA, and in degradation of host DNA, and suggest that the enzyme recognizes a specific structural feature in DNA. Its cleavage specificity, ready availability, and ability to act at physiological pH and ionic conditions may make gene 3 endonuclease useful as a probe for specific DNA structures or for binding of proteins that alter DNA structure.

Specific binding of monomeric bacteriophage T3 and T7 RNA polymerases to their respective cognate promoters requires the initiating ribonucleoside triphosphate (GTP)

Bacteriophage T3 and T7 RNA polymerases are monomeric proteins of Mr of about 100,000. Each polymerase has stringent specificity for its own promoters that is present only on the homologous phage DNA template. Neither enzyme recognizes the heterologous phage promoters or Escherichia coli RNA polymerase promoters. In the present study, the interaction of T3 and T7 RNA polymerases with their respective cognate promoters was studied by DNase I footprinting techniques. These studies revealed an absolute requirement for the initiating nucleotide (GTP) for each phage RNA polymerase to bind specifically to and protect its cognate promoter from DNase I digestion. In the absence of the initiating nucleotide, both enzymes randomly bind DNA with lower affinity. No other nucleotide can substitute for GTP; however, the addition of GTP + ATP, which causes the synthesis of a hexamer RNA (pppGpGpGpApGpA), makes the DNA-RNA-protein complex highly stable. Nitrocellulose filter binding studies confirmed these observations. On the basis of these results we propose that the binding of the initiating nucleotide (in this case, GTP) drives the phage RNA polymerase into an "initiation conformation" in which the random DNA-binding property of the enzyme is converted to a promoter-specific recognition, and the polymerase is primed to initiate transcription.

Interactions of the RNA polymerase of bacteriophage T7 with its promoter during binding and initiation of transcription

Promoters for T7 RNA polymerase have a highly conserved sequence of 23 continuous base pairs located at position -17 to +6 relative to the initiation site for the RNA. The complex of T7 RNA polymerase with the phage phi 10 promoter has been visualized indirectly by exploiting the ability of the polymerase to protect DNA sequences from cleavage by methidiumpropyl-EDTA X Fe(II). The DNA contacts made by T7 RNA polymerase have been mapped during binding and during the subsequent initiation of transcription. The RNA polymerase alone protects 19 bases in a region from -21 to -3. Synthesis of the trinucleotide r(GGG) expands the length of the sequence protected by the RNA polymerase and stabilizes the complex; 29 bases (-21 to +8) are protected, and the observed equilibrium association constant of the r(GGG) complex is 5 X 10(5) M-1. The formation of a hexanucleotide mRNA, r(GGGAGA), further extends the protected region; 32 bases (-21 to +11) are protected. Finally, the synthesis of a pentadecanucleotide mRNA leads to a translocation of the region protected by the protein; the sequence now protected is reduced to 24 bases (-4 to +20).

Transcription by T7 RNA polymerase is not zinc-dependent and is abolished on amidomethylation of cysteine-347

T7 RNA polymerase has been purified to homogeneity from an overproducing clone of Escherichia coli containing pAR1219. Preparations have a zinc content as low as 0.01 mol/mol of enzyme and a high specific activity, 300 000-500 000 units/mg. There are no intrinsic zinc sites. Furthermore, extrinsic Zn2+ does not function as an activator. Supplementation of the assay mix with up to 5 mM ethylenediaminetetraacetic acid has little effect on activity while added Zn2+ is strongly inhibitory at concentrations above 10 microM. This monomeric RNA polymerase is not a zinc metalloenzyme, unlike its multimeric bacterial counterparts. Titration of the urea-denatured protein with 5,5'-dithiobis(2-nitrobenzoic acid) reveals that all 12 Cys residues are present in the free sulfhydryl form, 5 of which are readily accessible to reagent in the native enzyme. More preferential labeling of the sulfhydryls can be achieved with low concentrations of [14C]iodoacetamide, where inactivation of the enzyme proceeds with incorporation of approximately 1.2 mol of [14C]iodoacetamide/mol of polymerase. Amidomethylation primarily occurs at Cys-347, with lesser reaction at Cys-723 and Cys-839. Cys-347 and Cys-723 are in segments of the primary sequence containing numerous basic residues. These same segments have previously been implicated in promoter binding, suggesting that both residues are located within or near the active site region.

Cloning, expression, and purification of gene 3 endonuclease from bacteriophage T7

The structural gene for the single-stranded endonuclease coded for by gene 3 of bacteriophage T7 has been cloned in pGW7, a derivative of the plasmid pBR322, which contains the lambda PL promoter and the gene for the temperature-sensitive lambda repressor, cI857. The complete gene 3 DNA sequence has been placed downstream of the PL promoter, and the endonuclease is overproduced by temperature induction at mid-log phase of Escherichia coli carrying the recombinant plasmid pTP2. Despite the fact that cell growth rapidly declines due to toxic effects of the excess endonuclease, significant amounts of the enzyme can be isolated in nearly homogeneous form from the induced cells. An assay of nuclease activity has been devised using gel electrophoresis of the product DNA fragments from DNA substrates. These assays show the enzyme to have an absolute requirement for Mg(II) (10 mM), a broad pH optimum near pH 7, but significant activity from pH 3 to pH 9, and a 10-100-fold preference for single-stranded DNA (ssDNA). The enzyme is readily inactivated by ethylenediaminetetraacetic acid or high salt. The differential activity in favor of ssDNA can be exploited to map small single-stranded regions in double-stranded DNAs as shown by cleavage of the melted region of an open complex of T7 RNA polymerase and its promoter.

Regulation of the Escherichia coli DNA topoisomerase I gene by DNA supercoiling

The transcriptional control region of THE E. coli DNA topoisomerase I (topA) gene has been fused to the galactokinase (galK) gene coding region in a recombinant plasmid. In vivo synthesis of the galactokinase produced from such a plasmid has been measured and found to be reduced when mutations in the genes coding for DNA gyrase subunits are introduced into the cell or when gyrase inhibitors are present. In vitro transcription-translation of the galactokinase gene product confirms that a supercoiled DNA template is required for efficient transcription from the topA gene promoter. These results indicate that the amount of DNA topoisomerase I activity in E. coli is regulated by the extent of DNA supercoiling and can contribute to the overall modulation of DNA superhelicity and the expression of other genes.

Mapping of single-stranded regions in duplex DNA at the sequence level: single-strand-specific cytosine methylation in RNA polymerase-promoter complexes

A method based on the differential rate of cytosine methylation in single- and double-stranded nucleic acids by dimethyl sulfate [Peattie, D.A. & Gilbert, W. (1980) Proc. Natl. Acad. Sci. USA 77, 4679-4682] has been developed for probing unpaired cytosines in DNA and DNA-protein complexes at the sequence level. Application of the method to the complexes between Escherichia coli RNA polymerase (EC 2.7.7.6) and three related promoters, lac UV5, trp, and a hybrid promoter tac resulting from the fusion of the two, reveals distinct differences in the way RNA polymerase unpairs DNA in these promoters. No single-stranded region is detectable in the complex with the trp promoter. For the lac UV5 promoter, the cytosines at positions -6, -4, -2, and -1 are in an unpaired region. The same cytosines in the tac promoter, which is homologous in sequence to lac UV5 in this region, are also found to be single stranded. For the pair of promoters lac UV5 and tac, the cytosine methylation reaction has also been used to demonstrate the steep temperature dependence of opening of base pairs by RNA polymerase. One striking feature is that the midpoint of this transition for the tac promoter is 3 degrees C lower than the corresponding value for lac UV5, even though the sequence of the unpaired region in the two promoters is identical.

Changes in DNA binding by purified simian RNA polymerase II under transcribing and nontranscribing conditions

The interaction of RNA polymerase II from African Green Monkey liver tissue with SV40 DNA was examined by a DNAase protection technique. In the absence of nucleoside triphosphates, simian polymerase binds to nicked, linear SV40 DNA and protects 30 bp of binary complex DNA from DNAase I digestion. With the addition of nucleoside triphosphates to initiate transcription, polymerase protects 40 bp of the ternary complex DNA from DNAase I. Thus, a conformational change in either the polymerase, the DNA, or both occurs during the transition from binary to ternary complex, and this altered conformation allows a larger protection of template DNA. Similar results were seen with Escherichia coli RNA polymerase holoenzyme on SV40 DNA.

Bacteriophage T7 late promoters: construction and in vitro transcription properties of deletion mutants

The construction of plasmids containing T7 class I promoters with deletion mutants was described. Restriction fragments, ending at the Hinf I site located at position -10 in the promoter from 14.8% of the T7 genome, were cloned into pBR322. This produced the deletion of either the left or the right part of the promoter. The in vitro transcription properties of these plasmids were determined. Control plasmids were obtained by cloning wild type class II and class III promoters into pBR322. These plasmids also were used to compare the in vitro transcription properties of the two classes of late promoters. Much of the leftward part of a T7 late promoter can be deleted without abolishing activity, but deletion of the right part eliminates promoter activity. Class II, class III, and the mutated promoters have characteristic responses to changes in ionic strength, exogenous glycerol, and temperature.

Regulation of promoter selection by the bacteriophage T7 RNA polymerase in vitro

During bacteriophage T7 infection a phage-specified RNA polymerase transcribes the late phage genes in two temporal classes (class II and class III). In this report, we show that the purified phage polymerase discriminates between the class II and class III promoters in vitro as a function of variables that alter the stability of the DNA helix. These variables include ionic strength, temperature, and the presence of denaturing agents such as dimethyl sulfoxide. In general, initiation at the class II promoters is preferentially inhibited as helix stability is increased. Conditions required for the establishment of salt-resistant transcription complexes by the T7 RNA polymerase have been determined; the establishment of stable complexes at the class II promoters requires the synthesis of a longer nascent RNA transcript than does formation of such complexes at the class III promoters. A comparison of the nucleotide sequences of several class II and class III promoters suggests certain features that may be responsible for the different responses of these promoters to helix destabilization. The conservation of structural features that are peculiar to the class II or class III promoters indicates that these features are important in regulation of T7 transcription in vivo. Experiments which bear on the physiological significance of these features are discussed.