©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Promoter Selectivity of Escherichia coli RNA Polymerase E and E Holoenzymes
EFFECT OF DNA SUPERCOILING (*)

(Received for publication, July 5, 1995; and in revised form, October 18, 1995)

Shuichi Kusano (1) (2) Quinquan Ding (1)(§) Nobuyuki Fujita (1) Akira Ishihama (1)(¶)

From the  (1)Department of Molecular Genetics, National Institute of Genetics, and the (2)School of Life Science, Graduate University of Advanced Studies, Mishima, Shizuoka 411, Japan

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

The functional specificity was compared between two factors, (the major at exponentially growing phase) and (the essential at stationary growth phase), of Escherichia coli RNA polymerase. The core enzyme binding affinity of was less than half the level of as measured by gel filtration column chromatography or by titrating the concentration of required for the maximum transcription in the presence of a fixed amount of core enzyme. In addition, the holoenzyme concentration required for the maximum transcription of a fixed amount of templates was higher for E than E. The transcription by E was, however, enhanced with the use of templates with low superhelical density, in good agreement with the decrease in DNA superhelicity in the stationary growth phase. We thus propose that the selective transcription of stationary-specific genes by E holoenzyme requires either a specific reaction condition(s) or a specific factor(s) such as template DNA with low superhelical density.


INTRODUCTION

In Escherichia coli, the total number of RNA polymerase core enzyme is fixed at a level characteristic of the rate of cell growth, which ranges from 1,000 to 3,000 molecules per genome equivalent of DNA(1, 2) . On the other hand, the total number of genes on the E. coli genome is estimated to be about 4,000, which is in good agreement with the number estimated from the DNA sequence (up to now, more than 60% has been sequenced). These considerations raise a possibility that competition must take place between promoters for binding a small number of RNA polymerase molecules. Among about 4,000 genes on the E. coli genome, about 1,000 genes are expressed at various levels in exponentially growing cells under laboratory culture conditions, i.e. at 37 °C and with aeration(2, 3) . The rest of the genes are considered to be expressed under various stress conditions that E. coli meets in nature (4, 5, 6, 7) . For instance, a set of stress-response genes is expressed when cells stop growing at stationary phase(6, 7) . Transcription of at least some of these stationary phase-specific genes is catalyzed by RNA polymerase holoenzyme containing (the rpoS gene product)(8, 9, 10, 11) . In addition, the modification of core enzyme is considered to be involved in stationary-specific transcription regulation(12, 13) .

Promoters from the stationary-specific genes, however, do not have a single consensus sequence(10, 11, 14, 15) . The lack of a consensus could indicate the involvement of a regulatory cascade, in which some genes are directly transcribed by E but others are under the control of these gene products. However, we found that the osmo-regulated genes, osmB and osmY, are transcribed preferentially by E only in the presence of high concentrations of potassium glutamate (or acetate) (16) . This finding raises a possibility that each stationary-specific promoter carries a specific sequence that is recognized by E under a specific reaction condition and suggests that the promoter sequences recognized by E differ between gene groups with different requirements. Our effort has since been focused to identify specific conditions or factors required for transcription of each stationary-specific gene by E holoenzyme. Along this line, we analyzed in this study the effect of DNA superhelicity on the promoter recognition by E holoenzyme. DNA superhelicity is known to change depending on the cell growth conditions. For instance, nutrient downshift and stationary growth phase cause a decrease in the DNA superhelical density(17, 18) , while high osmolarity leads to an increase in the superhelicity(19, 20) .

In this report, we describe the comparison of two factors, and , in the following activities: (i) the core binding activity, (ii) the promoter recognition activity, and (iii) the effect of DNA conformation on the promoter recognition patterns. The results show that the selectivity for stationary phase-specific promoters by E increases concomitantly with the decrease in DNA superhelicity and that the effects of decreased DNA superhelicity and high potassium glutamate concentrations are additive in enhancing the selectivity for E.


MATERIALS AND METHODS

Promoters and Templates

The truncated lacUV5 template, 205 bp (^1)EcoRI-EcoRI fragment, was prepared as described previously(21) , while the 156-bp HindIII-EcoRI katE and 796-bp PstI-EcoRI fic fragments were prepared as described by Ding et al.(16) and Tanaka et al.(10) , respectively. The BamHI-KpnI fragment of 287 bp in length carrying alaS promoter was prepared as described by Nomura et al.(22) . These truncated DNA templates produced in vitro transcripts of 63, 69, 53, 257, and 169 nucleotides in length, respectively.

Plasmids pBSOY containing osmY promoter and pBSLU containing lacUV5 promoter were constructed as follows. Plasmid pBluescript II (Stratagene) was linearized with SacI and blunt-ended using Klenow DNA polymerase; a 783-bp HincII-digested fragment containing rrnB terminator, purified from pKK223-3 (Pharmacia), was ligated into pBluescript II at the blunt-ended SacI site to yield plasmid pBST. A 261-bp HincII-EcoRV fragment containing osmY promoter, isolated from pDY.1.4(23) , was inserted into pBST between HincII and EcoRV to yield pBSOY. On the other hand, pBSLU was constructed after insertion of the 205-bp lacUV5 fragment from pKB252 (21) into pBST between HincII and EcoRI. These circular DNA templates produced in vitro transcripts of 357 (lacUV5 promoter), 346 (osmY promoter), and 108 (primer RNA for ColE1) nucleotides, respectively, in length. These template plasmids were prepared from transformed DH5alpha cells using QIAGEN plasmid kit (QIAGEN).

RNA Polymerase

RNA polymerase core enzyme was purified by passing RNA polymerase at least three times through phosphocellulose columns (the repeated chromatography is essential for complete removal of minor factors from core enzyme). (the rpoD gene product) was overexpressed using pGEMD and purified by the method of Igarashi and Ishihama(24) , while was overexpressed using pETF and purified as described by Tanaka et al.(10) .

In Vitro Single-round Transcription System

Single-round mixed transcription by holoenzyme was carried out under the standard conditions described previously(28) . In brief, a mixture of template DNA and RNA polymerase reconstituted from purified core enzyme and either purified or was pre-incubated for 30 min at 37 °C to allow open complex formation in the standard reaction mixture, which contained (in 35 µl) 50 mM Tris-HCl (pH 7.8 at 37 °C), 3 mM magnesium acetate, 50 mM NaCl, 0.1 mM EDTA, 0.1 mM DTT, and 25 µg/ml bovine serum albumin. A 15-µl mixture of substrate and heparin was then added to make the final concentrations of 160 µM each of ATP, GTP, and CTP; 50 µM UTP; 2 µCi of [alpha-P]UTP; and 200 µg/ml heparin. After 5 min of incubation at 37 °C, transcripts were precipitated with ethanol and subjected to PAGE in the presence of 8 M urea. Gels were dried and exposed to imaging plates. The exposed plates were analyzed with a BAS-2000 image analyzer (Fuji).

Preparation of a Set of Templates with Various Superhelical Densities

Covalently closed plasmids (5 µg each) were treated with 6 units of calf thymus DNA topoisomerase I (Takara Shuzo) in 100 µl of a reaction mixture, which contained 35 mM Tris-HCl (pH 8.0), 72 mM KCl, 5 mM MgCl(2), 5 mM DTT, 5 mM spermidine, and 0.01% bovine serum albumin. The enzyme reaction was carried out at 37 °C for 5 h in the presence of various concentrations of ethidium bromide (0-40 µM). After the incubation, plasmids were purified by two cycles of phenol-chloroform treatment, followed by ethanol precipitation. The average linking number (DeltaLk) of each DNA molecule was measured by electrophoresis on 0.8% agarose gels containing appropriate concentrations of ethidium bromide, according to the method of Keller(25) . The mean superhelical density () was calculated by the equation = 10DeltaLk/N, where N represents the number of the base pairs of plasmid DNA.


RESULTS

Difference in the Core Enzyme Binding Activity between Two Factors

Both and were overproduced in E. coli and purified to apparent homogeneity as determined by Coomassie Brilliant Blue staining of the proteins separated by PAGE. On the other hand, core enzyme was purified from exponentially growing E. coli cells by repeated chromatography on phosphocellulose. The affinity of the two species of subunit to core enzyme was examined by measuring two parameters, i.e. the saturation level of subunit required for the maximum level of holoenzyme formation from a fixed amount of core enzyme and the saturation level of subunit to achieve the maximum level of in vitro transcription by a fixed amount of core enzyme.

First, the affinity of the two subunits to core enzyme was compared by directly measuring the holoenzyme formation. For this purpose, we mixed a fixed amount of core enzyme and various amounts of either or at 30 °C, and the mixtures were fractionated by gel filtration-HPLC on a Superose 6 column. The to core enzyme ratio was measured for the peak fraction of RNA polymerase (Fig. 1). The core enzyme was saturated with at the input molar ratio between 2 and 3, while the saturation of the same amount of core enzyme with required at least 2-fold more protein than . The observed difference might be due to a difference in the activity of purified subunits. To test this possibility, the second-cycle assay was performed using the unassembled subunits recovered after the first cycle of binding assay. The core binding patterns of both subunits were essentially the same with those of the first cycle experiments (data not shown).


Figure 1: saturation curve for holoenzyme formation. Core enzyme (50 pmol) and various amounts of or subunit were mixed in 10 mM Tris-HCl (pH 7.8 at 4 °C), 10 mM MgCl(2), 1 mM DTT, 0.1 mM EDTA, 0.2 M KCl, and 50% glycerol and incubated for 10 min at 30 °C to form holoenzymes. The mixtures were fractionated by gel filtration-HPLC using a Superose 6 (Pharmacia) column. Proteins were eluted with 10 mM Tris-HCl (pH 7.8 at 4 °C), 200 mM NaCl, 0.1 mM DTT, 0.1 mM EDTA, and 5% glycerol. Each fraction was analyzed by SDS-PAGE, and gels were stained with Coomassie Brilliant Blue and scanned with an Ultroscan-XL laser densitometer (LKB). The molar ratio of alpha, betabeta`, and was calculated for the peak fractions. The dotted lines represent the standard deviations of four or five independent measurements.



Difference in the Promoter Recognition Activity between Two Factors

The level of subunit required for maximum transcription by a fixed amount of core enzyme was also compared between the two subunits. For this purpose, single-round transcription was carried out using a fixed amount of core enzyme and various amounts of subunits. The core enzyme was saturated by adding only 2-fold molar excess of subunit, i.e. 2 pmol of per pmol core as measured using alaS promoter (Fig. 2), and this level was observed for all the -dependent promoters analyzed (data not shown). The molar concentration of required for the maximum transcription of fic, katE, and lacUV5 was 10, 8, and 4 pmol, respectively, per pmol of core enzyme (Fig. 2). Since the difference in core enzyme binding activity between the two subunits is about 2-fold (see above), the transcription assay indicates that the promoter recognition activity is also weaker for than . The promoter recognition activity of is, however, variable depending on the promoter. For instance, only less than 2 molar excess of was needed for maximum transcription of the osmo-regulated promoters, osmB and osmY, in the presence of 0.3-0.5 M potassium glutamate (or acetate)(16) .


Figure 2: saturation curve for maximum transcription. Core enzyme (1 pmol) and various amounts of (A-C) or (D) subunit were mixed as in Fig. 1. To the RNA polymerase mixtures, one of the truncated DNA templates (0.1 pmol) carrying fic (A), katE (B), lacUV5 (C), or alaS (D) promoter was added and incubated for 30 min at 37 °C to form open complexes. After addition of a substrate mixture containing [alpha-P]UTP as a labeled substrate, RNA synthesis was carried out for 5 min at 37 °C. RNA was analyzed by electrophoresis on 6% polyacrylamide gel in the presence of 8 M urea. Gels were analyzed with a BAS-2000 Bio-Imaging Analyzer (Fuji). The transcription levels represent the average values of four or five independent assays for each template and the standard deviations. The 100% level corresponds to about 0.05 (about 0.5 molecule RNA per molecule DNA template), 0.03, 0.015, and 0.015 pmol transcript for alaS, lacUV5, katE, and fic promoter, respectively.



Effect of RNA Polymerase on Promoter Selectivity Control

Since both the core enzyme binding and the promoter recognition activities under our standard assay conditions for in vitro transcription were lower for E than E, the promoter selection pattern was analyzed with use of the increased concentration of RNA polymerase. Fig. 3summarizes the effect of enzyme/promoter ratio on the relative transcription level by two holoenzymes. At low enzyme concentrations, lacUV5 was transcribed preferentially by E, but E started to transcribe lacUV5 at high enzyme concentrations. Likewise, fic was transcribed by both E and E at low enzyme concentrations, but E transcribed better than E at high enzyme concentrations. These observations altogether lead to the recognition that the classification of promoters with respect to selectivity varies depending on the concentrations of individual holoenzyme species.


Figure 3: Effect of the holoenzyme concentration on transcription. Truncated DNA templates (0.1 pmol each) carrying fic (A), katE (B), or lacUV5 (C) were transcribed in vitro by various amounts of either E or E holoenzyme under the standard single-round assay conditions. Transcripts were analyzed by 8 M urea, 6% PAGE, and gels were analyzed with a BAS-2000 Bio-Imaging Analyzer (Fuji). The maximum levels of transcription for each template were set as 100% value, measured using 4 pmol of E for fic, 2 pmol of E for katE, and 1-4 pmol of E for lacUV5, respectively. The 100% value corresponds to about 0.015, 0.015, and 0.5 pmol transcript for fic, katE, and lacUV5, respectively. The ratios of transcription levels between two holoenzymes are plotted in the lower panels (fic (D), katE (E), and lacUV5 (F)).



The katE promoter was always transcribed better with E than E, but the E/E activity ratio increased from 1.3 at 0.5 pmol (per 0.1 pmol promoter; promoter/enzyme ratio of 5) to about 4 at the holoenzyme concentration higher than 1 pmol. For all the promoters examined, the transcription activity by E increased at high protein concentrations, supporting the notion that either the affinity of to core enzyme is weaker than that of or the affinity of E to promoters is weaker than that of E.

Effect of the Superhelical Density of DNA on Promoter Selectivity Control

plays a major role in transcription of a set of genes essential for survival in stationary phase and/or nutrient starvation(7) . Under such starved growth conditions, the superhelicity of chromosomal DNA in bacterial cells is known to decrease(17, 18) . We then examined the effect of DNA superhelicity on transcription in vitro by two RNA polymerase holoenzymes, E and E. For this purpose, the DNA fragments containing the test promoters were inserted into a single and the same vector plasmid containing rrnB transcription termination sequence so as to produce in vitro transcripts of defined sizes (for construction see ``Materials and Methods''). The resulting plasmids were treated with calf thymus DNA topoisomerase I in the presence of various concentrations of ethidium bromide. The superhelicity of each template thus obtained was measured by gel electrophoresis (see ``Materials and Methods''). Using these circular template DNAs with different degrees of superhelicity, an in vitro transcription assay was carried out under the standard conditions. The gel patterns, shown in Fig. 4, indicated that the effect of DNA superhelicity on transcription was different between E and E. The quantitative analysis data, shown in Fig. 5, indicated that the optimum superhelical density for maximum transcription by E was low for all the promoters (lacUV5, osmY, and RNA-I) tested, i.e. the superhelical density of around 0-0.03. In general, E required lower levels of DNA superhelicity for maximum transcription than E. In particular, the activity of E is enhanced with the decrease in DNA superhelicity in transcription of stationary-specific promoters.


Figure 4: Effect of the superhelical density of template DNA on transcription. A set of circular DNA templates, pBSLU (A) and pBSOY (B) (0.1 pmol each), with various superhelical densities was transcribed in vitro by reconstituted E and E holoenzymes under the standard single-round assay conditions. Transcripts were subjected by 8 M urea, 4% PAGE, and the gel was analyzed with a BAS-2000 Bio-Imaging Analyzer (Fuji).




Figure 5: Effect of the superhelical density of template DNA on transcription. The in vitro transcription reaction was carried out as described in Fig. 4. Transcripts, lacUV5 RNA derived from pBSLU (A), osmY RNA derived from pBSOY (B), and RNA-I derived from the ColE1 origin promoter from both plasmids (C) were measured with a BAS-2000 Bio-Imaging Analyzer (Fuji). The maximum level of transcription for each template was set as 100% value. These data represent the averages of three independent experiments for lacUV5 and osmY and six independent experiments for RNA-I.



In contrast, E required high levels of DNA superhelicity for maximum activity. The optimum DNA superhelicity for the maximum transcription of osmY promoter by E was high (above 0.1), and upon decrease in DNA superhelicity, E becomes inactive in transcription of the osmY promoter. Transcription of lacUV5 and RNA-I by E was rather insensitive to the change in DNA superhelicity (these promoters are classified into a group of promoters that are recognized by both E and E holoenzymes(10, 15) ).

Effect of Growth Phase on DNA Superhelicity and Promoter Activity

To correlate these in vitro observations with in vivo situations, we next examined the levels of DNA superhelicity for the plasmids that were purified from transformed DH5alpha cells at various phases grown in Luria broth at 37 °C. The results, shown in Fig. 6, indicated that the superhelicity of plasmids, prepared from the stationary phase cells, was approximately half of the level of plasmids from the exponentially growing cells. Furthermore, the plasmids from the stationary phase cells showed nearly the same extent of superhelicity as the plasmids that gave the maximum transcription in vitro by E (see Fig. 5). To confirm this relationship, we examined the template activity in in vitro transcription by E and E for all the templates prepared at various phases of the cell growth. The level of transcription by E was maximum for the promoters prepared at the stationary phase, i.e. about 2-fold higher than the levels of DNA from the log phase cells (data not shown). Again, the transcription levels by E stayed at constant levels (lacUV5 and RNA-I) or rather decreased (osmY) with the decrease in DNA superhelicity (data not shown). Thus, we concluded that E preferentially transcribes template DNA with the low superhelicity.


Figure 6: Effect of cell growth phase on the superhelical density of plasmid DNA. E. coli DH5alpha cells carrying a plasmid, pBSOY, were grown in Luria-broth. At the times indicated, the plasmid was isolated using QIAGEN plasmid kit, and the superhelical density was determined by electrophoresis on 8% agarose gels and in the presence of appropriate concentrations of ethidium bromide as described under ``Materials and Methods.''



Transcription Step Affected by DNA Superhelicity

To identify the step(s) of transcription that were affected by the DNA superhelicity, we examined the effect of E concentration on the relative level of transcription from osmY templates with different superhelicity. At low enzyme concentrations, the maximum transcription level on the template with low superhelical density was about 2-fold higher than that on the high helical density template, but at high enzyme concentrations, the maximum transcription level was almost the same between the two templates (Fig. 7). The results suggest that the affinity of E is higher for DNA with low superhelical density than for DNA with high superhelical density.


Figure 7: Promoter activity of plasmid DNA isolated from exponentially growing and stationary phase cells. Low and high superhelical density DNA templates (0.1 pmol each) carrying the osmY promoter were prepared from transformed DH5alpha cells at 4 and 24 h, respectively, after inoculation and transcribed in vitro by various amounts of the reconstituted E holoenzyme under the standard single-round assay conditions. Transcripts were analyzed by 8 M urea, 4% PAGE, and gels were analyzed with a BAS-2000 Bio-Imaging Analyzer (Fuji). The maximum level of transcription for the low superhelical density template was set as 100% value.



To confirm this prediction, we measured the rate of open complex formation. The time course of open complex formation by E is roughly the same between the two templates (the formation of open complexes was achieved within 15 min of preincubation at 37 °C). However, the maximum level of open complexes formed differed, indicating that the DNA superhelicity difference does not affect the rate of open complex formation but influences the promoter recognition activity by RNA polymerase (see ``Discussion'').

Additive Effect of Potassium Glutamate and DNA Superhelicity on Transcription

The level of osmY transcription by E holoenzyme increases with the increase in potassium glutamate concentration(16) . We then examined the effect of potassium glutamate concentration on transcription directed by circular DNA templates with different superhelicity. The patterns of lacUV5 and osmY transcription level by E were essentially the same between DNA from the exponentially growing and stationary phase cells, both showing decreased activity concomitantly with the increase in potassium glutamate concentration (Fig. 8, A and C). On the other hand, the maximum transcription level by E holoenzyme was observed at high concentrations of potassium glutamate (Fig. 8, B and D). In particular, E preferentially transcribed the osmY promoter only at high potassium glutamate concentrations, and this result agreed with the previous result by using truncated osmo-regulated gene promoters(16) . The maximum transcription of DNA with low superhelicity was observed between 200 and 300 mM concentrations of potassium glutamate, while using DNA with high superhelicity the maximum transcription was observed above 300 mM potassium glutamate (Fig. 8D). Thus, the requirement for high concentrations of potassium glutamate is partly replaced by the decrease in DNA superhelicity.


Figure 8: Effect of potassium glutamate concentrations on in vitro transcription of templates with different superhelical densities. A and B, low and high superhelical density DNA templates (0.1 pmol each) carrying lacUV5 promoter, were prepared from 4 and 24 h, respectively, after inoculation and were transcribed in vitro by various amounts of reconstituted E (A) and E (B) holoenzymes under the standard single-round assay conditions, except that 50 mM NaCl was replaced with the indicated concentrations of potassium glutamate. Transcripts were analyzed by 8 M urea, 4% PAGE, and gels were analyzed with a BAS-2000 Bio-Imaging Analyzer (Fuji). The maximum level of transcription for each template was set as 100% value. C and D, low and high superhelical density DNA templates (0.1 pmol each) carrying the osmY promoter, prepared from 4 and 24 h, respectively, were transcribed in vitro by various amounts of reconstituted E (C) and E (D) holoenzymes under the same conditions as in panels A and B. Analyses of transcripts were carried out as in panels A and B. These data represent the averages of three independent experiments.




DISCUSSION

The saturation experiments of in vitro transcription indicate that the affinity of to core enzyme is lower than that of (see Fig. 2). Direct measurement of the core enzyme-bound subunits by gel filtration-HPLC on Superose 6 column indeed showed that the binding affinity of to core enzyme is at least 2-fold weaker than that of (see Fig. 1). This was rather unexpected because the intracellular concentration of is not higher than that of even after prolonged starvation in the stationary phase(26) . Growth-coupled replacement of core enzyme-associated subunit from to may therefore require an additional factor(s) or a yet unidentified condition(s). For example, the modification of core enzyme in stationary phase cells (12, 13) may increase selective binding of .

The single-round in vitro transcription assays also indicated that the level of E holoenzyme required for maximum transcription of a fixed amount of template was higher than that of E holoenzyme (see Fig. 2and Fig. 3). However, the maximum yields of transcription in the presence of saturated amounts of enzyme were often lower than the template levels and were different between the promoters. The difference in abortive initiation between promoters provides a part of the explanation as has been experimentally demonstrated(27, 28) . In addition, the role of sensitivity difference of various initiation complexes to heparin cannot be excluded as a possible cause for the differing yields because our preliminary gel retardation assay indicated that EbulletlacUV5 initiation complexes were partly dissociated at 200 µg/ml heparin, while EbulletlacUV5 complexes stayed unchanged. (^2)

Another unexpected observation is that the affinity of E holoenzyme to -dependent promoters was rather weaker than that of E to -dependent promoters at least under the standard transcription assay conditions employed. Thus, in mixed transcription assays, -dependent promoters are preferentially transcribed at low enzyme concentrations, but upon the increase in enzyme concentration, the -dependent promoters become predominantly transcribed. Again, this is apparently in conflict with the intracellular concentrations of the two holoenzymes during the transition from exponentially growing to stationary growth phase. Thus, promoter-E interaction may also be influenced by a specific factor(s) and/or condition(s) present in stationary phase E. coli cells. Previously, we found that addition of high concentrations of potassium glutamate selectively enhances transcription by E, although E activity is inhibited at the high salt concentrations(16) . In addition, we found in this study that E preferentially transcribed the promoters on low superhelical density DNA (see Fig. 4and Fig. 5). Moreover, the optimum superhelical density for maximum transcription by E was almost the same as that of plasmids prepared from stationary phase E. coli (see Fig. 6). Preferential transcription of the low superhelical density templates by E was due to the high affinity of E binding to promoter on the low superhelical density DNA (see Fig. 7).

The selective transcription of osmY by E increases by adding high concentrations of potassium glutamate(16) . The optimum potassium glutamate concentrations for the maximum transcription of osmY on the stationary phase plasmid template with low superhelical density by E was 200-300 mM, where as that on the DNA with high superhelical density prepared from log phase E. coli cells was above 300 mM (see Fig. 8). Transcription in vivo of osmY in cells growing in nutrient-rich media such as Luria-broth is observed only at the stationary phase, whereas in cells growing in poor media such as M9-glucose, osmY transcription occurs at both log and stationary phases(23, 29) . In good agreement with these observations, the superhelical density of plasmids prepared from cells grown in M9-glucose is about half the density of plasmids prepared from exponentially growing cells in Luria-broth.^2 These results altogether raise such a model of global regulation that transcription by E is enhanced with the decrease in DNA superhelical density under starved conditions. In addition, the increase in intracellular potassium glutamate concentration may lead to enhanced transcription of at least osmo-regulated genes. As an extension of this consideration, each of the stationary phase-specific gene promoters may require a specific transcription factor(s) or condition(s) for efficient transcription. Such predictions are in good agreement with the observations that the -dependent promoters do not carry a consensus promoter sequence(10, 11, 14, 15, 16) .

In addition to selective activation of E, a nucleoid-associated protein, H-NS (or H1a), which accumulates in the stationary growth phase, represses -dependent transcription in vitro and in vivo(30, 31, 32) . Likewise, Dps accumulating in the stationary growth phase cells may play dual roles in not only DNA protection but also repressing gene transcription(33) . The differential repression by these DNA binding proteins on transcription between E and E may also lead to apparently selective transcription of -dependent genes in the stationary phase.


FOOTNOTES

*
This work was supported by grants-in-aid from the Ministry of Education, Science, and Culture of Japan. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
On leave of absence from the Wuhan Institute of Virology, Chinese Academy of Sciences, Wuhan, Hubei 430071, China.

To whom correspondence should be addressed. Tel.: 81-559-81-6741; Fax: 81-559-81-6746; :aishiham{at}lab.nig.ac.jp.

(^1)
The abbreviations used are: bp, base pair(s); DTT, dithiothreitol; PAGE, polyacrylamide gel electrophoresis; HPLC, high pressure liquid chromatography.

(^2)
S. Kusano, unpublished results.


ACKNOWLEDGEMENTS

-We thank Miki Jishage for experimental support and Kan Tanaka for discussion.


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