Specificity of sigma-dependent binding of RNA polymerase to DNA

A two-subunit bacterial sigma-factor activates transcription in Bacillus subtilis

The sigma-like factor YvrI and coregulator YvrHa activate transcription from a small set of conserved promoters in Bacillus subtilis. We report here that these two proteins independently contribute sigma-region 2 and sigma-region 4 functions to a holoenzyme-promoter DNA complex. YvrI binds RNA polymerase (RNAP) through a region 4 interaction with the beta-subunit flap domain and mediates specific promoter recognition but cannot initiate DNA melting at the -10 promoter element. Conversely, YvrHa possesses sequence similarity to a conserved core-binding motif in sigma-region 2 and binds to the N-terminal coiled-coil element in the RNAP beta'-subunit previously implicated in interaction with region 2 of sigma-factors. YvrHa plays an essential role in stabilizing the open complex and interacts specifically with the N-terminus of YvrI. Based on these results, we propose that YvrHa is situated in the transcription complex proximal to the -10 element of the promoter, whereas YvrI is responsible for -35 region recognition. This system presents an unusual example of a two-subunit bacterial sigma-factor.

Native deoxyribonucleic acid transcription by yeast RNA polymerase--P37 complex

The specific activity of yeast RNA polymerases A or B, when complexed with P37 cofactor, compares favorably with that of E. coli RNA polymerase. The stimulation is observed only with double-stranded DNA but does not result from DNase action. The Km for nucleotide substrates and the optimal conditions of transcription are not modified. P37 stimulates RNA synthesis by ternary transcription complexes in the presence of poly(rI) which prevents reinitiations. The RNA chain length, estimated by 5' end labeling or sedimentation, is increased in the presence of P37. On the other hand, the trinucleotide synthesis, which reflects the chain initiation reaction, is not affected. Therefore, the cofactor appears to act at the elongation step of RNA synthesis.

The interaction of RNA polymerase and DNA. Effects on the helix-coil transition and light scattering

To characterize the interactions of RNA polymerase with DNA, we have investigated the thermal transition of poly[d(A-T] bound to RNA polymerase from Escherichia coli and the aggregation properties of the enzyme with DNA. The melting curve of the DNA-enzyme complex demonstrates a sharply lowered melting temperature for part of the DNA, whereas for another fraction the double helix is stabilized. This indicates that the DNA-binding site of RNA polymerase serves two functions: (1) to disrupt the double helix at one point, and (2) to maintain the duplex form at other points. The aggregation of DNA and RNA polymerase has been monitored by turbidity measurements, and conditions have been delineated under which aggregation is minimized. Holoenzyme added to double-stranded DNA or single-stranded DNA has little or no tendency to aggregate under most conditions. Core enzyme, on the other hand, aggregate extensively with double-stranded DNA, the only under conditions of low salt (10 mM KCl), without Mg2+, or at high salt (300 mM KCl), with or without Mg2+, can this aggregation be eliminated. Core enzyme also does not aggregate in the presence of single-stranded DNA. These aggregation properties are interpreted as evidence for more than one DNA-binding site on RNA polymerase.

Transcription of adenovirus 2 DNA by human RNA polymerase II in vitro

The interaction of Adenovirus 2 DNA and human placental RNA polymerase II in vitro satisfies criteria that suggest that at least some fraction of our purified polymerase preparations corresponds to prokaryotic holoenzyme and is able to initiate transcription at "true" promoters: (1) The purified enzyme forms highly stable complexes at specific sites on Ad 2 DNA; Kass = 1--2 X 10(12) M-1. (2) Transcription of Ad 2 DNA from pre-formed complexes with human RNA polymerase II is resistant to poly I. (3) Many of the stable-binding sites correspond to Ad 2 promoters known to be active in vivo. We also present evidence consistent with a two-state (I and RS) model (Chamberlin et al. 1976; Travers 1974) for the interaction of human RNA polymerase II with Ad 2 DNA. These experiments, which are similar to those described previously in studies of wheat germ RNA polymerase II (Seidman et al. 1979), indicate that the mechanisms of transcription inhibition and promoter site selection in eukaryotic and prokaryotic systems may be very similar.

Inactivation of E. coli RNA polymerase by polyriboinosinic acid: heterogeneity of RS complexes

Polyriboinosinic acid (poly I) inhibits initiation of transcription by binary complexes formed between Adenovirus 2 DNA and E. coli RNA polymerase holoenzyme. In the presence of poly I, just as in the presence of rifampicin, initiation of transcription exhibits a sigmoidal dependence on the temperature at which the binary complexes are formed. This indicates that I (closed) complexes between Ad 2 DNA and RNA polymerase are rapidly inactivated by poly I, but that RS (open) complexes are relatively resistant. However, even among the RS complexes, at least two classes can be distinguished on the basis of the degree to which they are resistant to poly I: RS-1 complexes are somewhat sensitive to poly I (half-time of inactivation approximately 10 min) while RS-2 complexes are almost completely resistant to the inhibitor (half-time of inactivation approximately 10 h). For both types of RS complex, the degree of sensitivity to poly I is ionic strength-dependent.

Form II DNA-dependent RNA polymerase from Drosophila melanogaster: general in vitro catalytic properties and template interactions

Several in vitro properties of partially purified form II RNA polymerase from Drosophila melanogaster embryo nuclei are described. The enzyme preparation is free from contaminating RNase, protein kinase, and polyphosphate kinase activities and can be used to study the incorporation of gamma-32P-labeled nucleoside triphosphates. The enzyme exhibits a biphasic heat inactivation pattern which is probably related to differential lability of its two subforms. However, a considerable protection against heat inactivation is provided by the nucleoside triphosphates present in the in vitro reaction system such that the enzyme catalyzes RNA synthesis in a nearly linear mode for over 2 hr at 30 C. Two initiation inhibitors, rifamycin AF/013 was found unsuitable for critical studies because of the high concentrations necessary for total inhibition (200 micrograms/ml) and particularly because of the obligate use of solvents which secondarily have a destabilizing effect on native DNA. Poly[I] was found to effectively block initiation at very low concentrations (1 microgram/ml). The enzyme rapidly forms poly[I]-resistant preinitiation complexes on both double- and single-stranded DNA. These complexes decay with a half-life of 2.5--3 min. RNA synthesis from poly[I]-resistant complexes amounts to 10% of the total potential synthesis on both double- and single-stranded DNA. Enzyme-DNA saturation experiments indicate that the form II enzyme discriminates two types of sites on Drosophila DNA, tight binding and weak binding, from which RNA synthesis proceeds slowly and rapidly, respectively. The tight-binding sites appear to be analogous to those sites with which the enzyme is able to form poly[I]-resistant complexes.

Enumeration of drosophila form II DNA-dependent RNA polymerase initiation sites on Drosophila DNA

The in vitro incorporation of gamma-32P-labeled nucleoside triphosphates into RNA by Drosophila melanogaster form II RNA polymerase from template sites which afford protection from the initiation inhibitor, polyriboinosinic acid (poly [I]), is used as a method for enumerating a specific class of transcription initiation sites on D. melanogaster DNA. Such sites number about 4000 per haploid genome for D. melanogaster. This value is in good agreement with the number of functional genetic units in the D. melanogaster genome as determined by classical cytogenetics.

Transcription of bacteriophage T4 DNA in vitro: selective initiation with dinucleotides

The transcription products of phage T4 DNA in vitro are separated on polyacrylamide gels. The influence of salt, polymerase, triphosphate concentration and glucosylation on the RNA synthesis are shown. Individual transcripts are initiated selectively with dinucleotides and a single triphosphate. This technique allows the prediction of the initiation sequences of several T4 transcripts.

Capacity of ribosomal RNA promoters of E. coli to bind RNA polymerase

The rate of in vitro transcription of the rRNA genes of E. coli is more than 20 fold higher than the averaged transcription rate of other genome segments of the same size. This "preferential transcription" of rRNA genes reflects a high efficiency of their promoters in chain initiation. We show that the high initiation rate at rRNA promoters results from a high rate of RNA polymerase binding to these promoters as measured by the formation of heparin-resistant RNA polymerase-DNA complexes. The results indicate that the preferential binding of RNA polymerase to rRNA promoters is mainly due to their large binding capacity rather than to a high rate constant of polymerase binding to a single binding site. The polymerase binding capcity of rRNA promoters was estimated from the number of rRNA chains initiated by heparin-resistant complexes under conditions of template saturation and from the number of rRNA transcription units participating in the binding reaction. At least 30 RNA polymerase molecules were found to be protected from heparin per rRNA transcription unit. The rest of the genome (99.4%; possibly sufficient to encode 4000 nonribosomal RNA species) protects under these conditions 2000 enzyme molecules. These results suggest that a high multiplicity of RNA polymerase binding may be responsible for the high efficiency of rRNA promoters. The validity of this hypothesis is discussed.

Recognition properties of the beta subunit of Escherichia coli ribonucleic acid polymerase

Changes in the phage protein patterns obtained by gel electrophoresis of extracts from phage S13 and phiX174 infection of rifampin-resistant hosts suggest that the beta subunit of ribonucleic acid polymerase of Escherichia coli has a function in the recognition of promoter or terminator sites or both. The altered protein patterns also provide information on the location of some ribonucleic acid polymerase recognition signals in S13 deoxyribonucleic acid. There is a promoter site before gene A, which lies either in gene H or between H and A. There is evidence for a promotor between genes C and D or in gene C. There is either a terminator or a promoter somewhere between the end of gene D and the beginning of gene F.

Multiple modes of ribosomal RNA transcription in vitro

The rate of rRNA synthesis from E. coli DNA in vitro can exhibit an unusual temperature dependence. Instead of the typical sigmoid curve, at least five to six pronounced peaks of rRNA synthesis are detectable over a 30degrees range in temperature. rRNA synthesis from performed initiation complexes exhibits a similar pattern and shows that the number of polymerases able to initiate rRNA synthesis increases with each successive peak. These results are interpreted in terms of a model which proposes that the rRNA cistrons are served by multiple promoter sites (subpromoters) whose activation energies form a graded series. Thus the number of polymerases initiating rRNA synthesis could be controlled by regulating the number of active subpromoters.

Influence of DNA acidification on DNA premelting and template properties

Acidification of a T7 DNA sample was found to be partly irreversible as ultraviolet difference spectra measured at various sub-melting temperatures were different from those observed for a 'normal' DNA sample. This implies some subtle conformational change which is not reversed by return to neutral pH. In the same conditions, only poly(purine)-poly(pyrimidine) polymers behaved in a different manner, during premelting, according to whether they were previously acidified or not. The properties of acidified and reneutralized T7 DNA were also investigated for Escherichia coli RNA polymerase binding and transcription. An inhibition of RNA synthesis and chain initiation was observed. The results suggest that the binding of the enzyme is affected. RNA synthesized is specific but there is a decrease in the number and in the stability of the RNA-polymerase-DNA complexes.

I.n vitro transcription of adenovirus 2 DNA. I. Characterization of promoters for E. coli RNA polymerase

E coli RNA polymerase holoenzyme is able to recognize transcription initiation sites on Adenovirus 2 DNA that are functionally indistinguishable from promoters for the enzyme on phage DNAs. The complexes formed between the polymerase and the DNA at these sites can exist in two states-either as I (initiation) complexes, from which rapid RNA chain initiation is not possible, or as RS (rapid starting) "rifampicin resistant" complexes, from which rapid RNA chain initiation can occur. When transcription is limited to that initiated from stable, rifmapicin-resistant pre-initiation complexes, initiation is strictly dependent on the presence of sigma factor; in addition, the frequency of initiation exhibits sigmoidal dependence on the temperature at which pre-initiation complexes are allowed to form, with a transition temperature of 26-28 degrees C. The average half-time for initiation of RNA chains from sites on Ad 2 DNA is shown to be comparable to half-times for initiation of RNA chains from promoters on T7 and lambda DNAs. At saturating levels of enzyme, the half-times are 0.6, 0.9, and 1.6 sec for lambda b2, Ad 2 and T7 DNAs, respectively. The existence of efficient, phage-like promoters for E coli RNA polymerase on Ad 2 DNA suggests to us that such promoters may be closely related functionally and spatially to promoters for mammalian RNA polymerases.

In vitro transcription of adenovirus 2 DNA. II. Quantification and localization of promoters for E. coli RNA polymerase

We estimate that E. coli RNA polymerase is able to form stable, rifampicin-resistant, pre-intiation complexes with Adenovirus 2 DNA at three to six binding sites. The number of RNA chains initiated from such complexes has been determined form the incorporation of gamma-32P-ATP and -GTP at two rifampicin concentrations (7 mug/ml and 24 mug/ml) and after pre-incubation at either 25 or 37 degrees C. The total number of RNA chains initiated ranges from 2.6 per Ad 2 DNA molecule at a rifampicin concentration of 24 mug/ml and pre-incubation temperature of 25 degrees C, to 5.4 per Ad 2 DNA molecule at a rifampicin concentration of 7 mug/ml and pre-incubation temperature of 37 degrees C. Efficient initiation with GTP occurs only after pre-incubation at 37 degrees C whereas initiation with ATP is equally as efficient at either pre-incubation temperature. Promoters for initiation with ATP have been localized to the leftmost 58% of the Ad 2 DNA molecule, defined by the EcoR.RI restriction endonuclease fragment A; promoters for initiation with GTP are located on the remaining 42% of the Ad2 DNA molecule. It is likely that on Adenovirus 2 DNA each RNA chain is initiated from a unique binding site which constitutes a seperate promoter for E. coli RNA polymerase.

Interaction of RNA polymerase from Escherichia coli with DNA. Analysis of T7 DNA early-promoter sites

A method was devised for directing RNA polymerase on a single promoter site on T7 DNA. Initiation complexes were formed on each of the three main promoter sites using one dinucleotide plus one nucleoside triphosphate. The ternary initiation complexes are resistant to rifampicin action, to inhibition by (rI)n at 0 degrees C and are stable at high salt concentrations. A minimum of a trinucleotide is required to form a stable ternary complex. To determine which promoter site was selected by RNA polymerase during initiation, the (rI)n-resistant RNA was digested by RNAse III to generate three characteristic initiator RNA fragments, resolved by gel electrophoresis. The three major promoter sites could be selected individually by using different primer and substrate combinations ApC plus ATP selected promoter A3, CpG plus CTP selected A2 and CpC plus ATP specified preferentially A1. A number of primer-substrate combinations specified each site at low salt concentration but the substrate requirement became very stringent at high salt concentration, suggesting that the postulated local opening of the promoter site could be more or less extensive, depending on the ionic strength. The minimum opening observed at high salt concentration corresponded to the insertion of a leader trinucleotide sequence. The promoter region melted by RNA polymerase at low salt concentration was (G plus C)-rich and corresponded to about 9 to 11 base pairs. Sequences of the melting recognition regions were tentatively inferred from the results.

RNA polymerase binding sites isolated from T4DNA: analysis of oligopyrimidine sequences constituting preinitiation and initiation complexes

Oligopyrimidines which contain 5'-hydroxymethylcytosine instead of cytosine were separated by thin layer chromatography. Using this method, the oligopyrimidine pattern of RNA polymerase binding sites, isolated from T4DNA, was evaluated quantitatively. The analysis shows that 1. the RNA polymerase binding sites on T4 DNA obtained under low salt conditions in absence of triphosphates, are A-T-rich as compared with total T4 DNA. 2. The A-T base pairs stand mainly in alternating position. On the average these sequences comprise more than half of the chain length of each binding site, which contains about 8 G-5'-HMC pairs. 3. The sites of binding and the sites of initiation do not show an identical base composition. 4. A mixture of at least 8 different binding istes is isolated under the conditions employed. This figure is in agreement with the number of distinct transcripts synthesized in nitro by E. coli RNA polymerase from T4 DNA. The overall length of these transcripts corresponds to approximately 9% of the T4 genome.

Comparative effect of heparin on RNA synthesis of isolated rat-liver nucleoli and purified RNA polymerase A

The polyanion heparin has been employed to study the interaction of rat liver DNA-dependent RNA polymerase A and its template under various conditions. Heparin very efficiently inhibits polymerase molecules, which are not bound to DNA or are associated with the template in a loose, i.e. non-specific fashion. Purified nucleoli, isloated from rat liver nuclei, contain RNA polymerase A in abundant quantities of which only a portion is bound in a transcriptional complex. Excess enzyme, which is contained in the nucleolus in a quasi free form, can be transferred to an exogenously added template and can be completely inhibited by the prior addition of heparin. The enzyme contained in a transcriptional complex, however, initiated in vivo and completing these RNA chains in vitro, is fully resistant to heparin. In contrast to these results it has been found that RNA polymerase A extracted from nuclei and purified by various chromatographic steps does not form heparin-resistant complexes, even after the enzyme has been bound to the DNA template. Moreover it has been found that purified RNA polymerase A transcribes truly native DNA extremely poorly, indicating that the enzyme is highly deficient in the act of initiation on duplex DNA. It is therefore questionable whether the interaction of the purified enzyme and isolated DNA represents binding to true initiation complexes as is observed in the intact nucleolus.