Activation of the glnA, glnK, and nac Promoters as Escherichia coli Undergoes the Transition from Nitrogen Excess Growth to Nitrogen Starvation

The nitrogen-regulated genes and operons of the Ntr regulonof Escherichia coli are activated by the enhancer-binding transcriptionalactivator NRI $~$ P (NtrC $~$ P). Here, we examined the activation ofthe glnA, glnK, and nac promoters as cells undergo the transitionfrom growth on ammonia to nitrogen starvation and examined theamplification of NRI during this transition. The results indicatethat the concentration of NRI is increased as cells become starvedfor ammonia, concurrent with the activation of Ntr genes thathave less- efficient enhancers than does glnA. A diauxic growthpattern was obtained when E. coli was grown on a low concentrationof ammonia in combination with arginine as a nitrogen source,consistent with the hypothesis that Ntr genes other than glnAbecome activated only upon amplification of the NRI concentration.

INTRODUCTION

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Introduction

Escherichia coli contains six operons that are known to be partof the Ntr regulon (argThisJQMP, astCADBE, glnALG, glnHPQ, glnKamtB,and nac). These operons require ${sigma}$ ⁵⁴-RNA polymerase for expressionand are activated by the phosphorylated form of enhancer-bindingtranscription factor NRI (NtrC) (reviewed in reference 16).A seventh operon, consisting of the ygiG gene, may also be apart of the Ntr regulon (16). E. coli also contains numerousadditional genes that become activated or repressed upon nitrogenstarvation (27).

The mechanism of activation by NRI $~$ P at ${sigma}$ ⁵⁴-dependent promotershas been studied in some detail (reviewed in reference 10).NRI $~$ P binds to upstream enhancer elements, oligomerizes, anddisplays ATPase activity. This complex interacts with ${sigma}$ ⁵⁴-RNApolymerase bound at the promoter to bring about formation ofthe open transcription complex. The interaction between NRI $~$ Pand ${sigma}$ ⁵⁴-RNA polymerase requires the formation of a DNA loop,bringing the enhancer-bound activator and promoter-bound polymeraseinto proximity. In some cases, regulatory factors bind the interveningDNA and activate or repress transcription by topological alterationof the DNA.

The different nitrogen-regulated promoters contain distinctarrangements of NRI-binding sites that constitute their enhancerelements. The glnAp2 promoter apparently contains the most potentenhancer, consisting of two adjacent high-affinity NRI-bindingsites (14, 20). The glnHp2 promoter, consisting of overlappinghigh-affinity sites, appears to be slightly less effective invitro (4). The Klebsiella pneumoniae nifLA enhancer containsadjacent low-affinity NRI-binding sites and is only effectiveat high NRI $~$ P concentrations in vitro (26). Similarly, the nacpromoter of Klebsiella aerogenes has a weak enhancer that isonly effective at high NRI $~$ P concentrations in vitro; this enhancerconsists of a high-affinity NRI-binding site and an adjacentsite that is bound by NRI $~$ P only at high concentration (7). Thus,in vitro transcription studies are consistent with the hypothesisthat amplitude modulation of the NRI $~$ P concentration resultsin the sequential activation of Ntr genes.

A considerable body of additional evidence also supports thishypothesis. The intracellular concentration of NRI rises dramaticallyin cells growing under nitrogen-limiting conditions (19), owingto the activation of the glnAp2 promoter by NRI $~$ P (15). Also,cells that have been genetically manipulated such that the NRIconcentration is always low retain the ability to fully activateglnAp2 but are unable to grow on arginine as a nitrogen source(15) or activate the glnK promoter (2). The inability to growon arginine probably reflects the inability to activate theastC promoter (16, 23). Similarly, the activation of the K.pneumoniae nifLA promoter requires a high concentration of NRI $~$ Pin vivo (10). It seems reasonable that the nac, glnK, astC,and nifLA promoters should be activated by NRI $~$ P only at highconcentrations, since the products resulting from their activationare useful under starvation conditions (16-18).

Finally, the signal transduction system that regulates the NRIphosphorylation state is able to provide rheostat-like controlof NRI $~$ P in response to signals of nitrogen status (reviewedin reference 13). This, in combination with the observationthat the NRI concentration is dramatically regulated in cells,suggests that cells may widely vary the concentration of NRI $~$ Pin response to changes in environmental conditions.

Nevertheless, there are a few significant gaps in our knowledge.The great instability of NRI $~$ P has prevented its direct measurementin situ. Furthermore, most of the experiments with intact cellssummarized above were conducted with log-phase cells growingunder nitrogen excess or nitrogen-limiting conditions; our conclusionsconcerning transitions represent extrapolations from these results.Here, we focused on the growth of cells as their environmentchanges from nitrogen replete to nitrogen starved and measuredthe activation of the glnA, glnK, and nac promoters, as wellas the amplification of the intracellular concentration of NRI.In addition, we examined the patterns of growth when E. coliwas provided with ammonia and arginine as nitrogen sources.

MATERIALS AND METHODS

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Materials and Methods

Bacteriological techniques. Luria-Bertani broth and W salts-based defined media, preparationof plasmid DNA, preparation of competent cells, transformationof cells with DNA, sequencing of plasmid DNA, PCR amplificationof DNA, preparations of P1vir phage lysates, P1-mediated transduction,recombination of DNA onto the bacterial chromosome, and long-termstorage of strains were by standard techniques or were as describedpreviously (1, 2, 5, 8, 12, 22, 24). The bacterial strains,plasmids, and oligonucleotides used in this work are describedin Tables 1 to 3. Turbidity of bacterial cultures was measuredwith a Beckman DU65 spectrophotometer.

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TABLE 1. Strains used in this study

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TABLE 3. Primers used in this study

Construction of glnAp-lacZ and nacp-lacZ fusions and recombination onto the bacterial chromosome PCR was used to amplify the glnA control region with primersglnApD.S.5 and glnApU.S.2 (Table 3). Similarly, primers NacpLacZus2and NacpLacZds2 were used to amplify the nac control region(Table 3). The amplification products were cleaved with EcoRIand BamHI and then cloned into similarly cleaved pRS551 (25)to form a transcriptional fusion to lacZ bracketed by transcriptionalterminators with flanking sequence homology to trp genes. Thefusions were recombined onto the bacterial chromosome by electroporationof strain TE2680 with PstI-digested plasmid DNA and selectionfor kanamycin-resistant, chloramphenicol-sensitive transformants(5). The recombinants were confirmed to have a new auxotrophicrequirement for tryptophan, indicating correct recombinationinto the trp locus. The fusions were then moved into variousgenetic backgrounds by P1vir-mediated generalized transduction,with selection for the nearby kanamycin resistance marker.

GS and ß-galactosidase assays. The ${gamma}$ -glutamyl transferase activity of glutamine synthetase (GS)was measured as described previously (21). Protein determinationswere as described by Lowry et al. (11). Two cultures were usedfor each determination, and the experiments were repeated onthree different occasions. Within a given experiment, valuesfor duplicate cultures were within 10%, while the day-to-dayreproducibility was ±20%. ß-Galactosidase wasmeasured by the Miller assay and expressed as Miller units,and sodium dodecyl sulfate and chloroform were used to disruptthe cells as described previously (24). In previous work, wemeasured the expression of the glnKp-lacZ fusion using cellsonicates (2). Comparison of the two methods indicated thatthe Miller assay reproducibly detects about one-fourth of theactivity found in cell extracts (A. J. Ninfa and M. R. Atkinson,unpublished data).

Immunoblotting. A crude rabbit anti-NRI antibody was kindly provided by LawrenceReitzer. Immunoblotting was performed with the Amersham ECLWestern blotting system according to the manufacturer's directions.

In vitro transcription assays. The assay methods were identical to those described in reference7. Transcription templates pTH8 and pLR100, containing the glnApcontrol region, were as described previously (7, 9, 14). TheglnKp transcription template, pglnK13, was constructed by PCRamplification using primers 7159I and 4804J (Table 3), cleavagewith BamHI and HindIII, and ligation into similarly cleavedpTE103, essentially as described previously (9). The plasmidwas sequenced to verify that no alterations were introducedto the glnK control region during these manipulations. NRI,NRII, core RNA polymerase, and ${sigma}$ ⁵⁴ were purified as describedearlier (7, 14).

RESULTS

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Results

Establishing conditions to study the transition from nitrogen excess growth to nitrogen starvation. Since the preferred nitrogen source for E. coli is ammonia,we examined the effect of growth in the presence of variousconcentrations of ammonia. We found that while cell yield dependedon the ammonia concentration, the growth rate did not (Fig.1). Apparently, E. coli is very effective in capturing ammonia,even when it is present at low concentration. These resultscall into question the validity of the common practice in whichmedium containing limiting ammonia is used to establish lowsteady-state rates of growth in chemostat experiments. The amtBgene, encoding a putative ammonia transporter, had no effecton the utilization of ammonia in our experiments, even at verylow ammonia concentrations (Fig. 1).

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FIG. 1. Growth of YMC10 (wild type) and X (amtB::Cam^r) on various concentrations of ammonium sulfate. Overnight cultures grown at 30°C in 0.4% (wt/vol) glucose and 0.2% (wt/vol) ammonium sulfate were washed and resuspended in medium containing 0.4% (wt/vol) glucose and the following concentrations of ammonium sulfate: for YMC10, 0.2 (x), 0.05 (+), 0.01 ( ${blacklozenge}$ ), 0.005 ( ${blacktriangleup}$ ), and 0.001% ( ${blacktriangledown}$ ); for X, 0.2 ( ${circ}$ ), 0.05( ${square}$ ), 0.01 ( ${lozenge}$ ), 0.005 ( ${triangleup}$ ), and 0.001% ( ${triangledown}$ ). OD₆₀₀, optical density at 600 nm.

To study the activation of the glnA, glnK, and nac promoterswith high precision in dilute bacterial cultures, we engineeredtranscriptional fusions of these promoter regions to lacZ. Thesefusions were placed onto the chromosome in single copy withinthe trp operon (25) (see Materials and Methods). The glnKp-lacZfusion was described previously (2); construction of the glnAand nac fusions is described in Materials and Methods. Expressionof the glnAp-lacZ fusion was observed to parallel the expressionof GS in adapted log-phase cells growing under nitrogen-richand nitrogen-limiting conditions (data not shown).

Activation of glnAp, glnKp, and nacp as cells growing on ammonia became nitrogen starved. A comparison of the activation of glnAp and glnKp as cells underwentthe transition from growth on ammonia to nitrogen starvationis shown in Fig. 2. A significant difference in the patternsof expression of glnKp and glnAp was observed. When grown onlow concentrations of ammonium (0.005 [A] or 0.01% [B] ammoniumsulfate), expression of glnAp was approximately one-third toone-fourth of the maximum level observed during exponentialgrowth, while glnKp was essentially silent (Fig. 2A and B).In both cases, glnKp became highly expressed as the cells ranout of ammonia and growth ceased (Fig. 2A and B). In contrast,at 0.2% ammonium sulfate, where cell yield was not limited byammonia, glnAp was expressed at approximately one-ninth of itsmaximum level, while glnKp was silent even after the cells stoppedgrowing (Fig. 2C). Thus, the regulation of glnAp and glnKp wasdifferent in that under certain conditions (i.e., when cellsreached stationary phase before exhaustion of the ammonia) glnApwas the only promoter expressed. Although the growth rate wasnot significantly altered at different concentrations of ammonia(provided as ammonium sulfate), the level of glnA transcriptionwas clearly affected.

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FIG. 2. Induction of glnAp and glnKp in response to nitrogen starvation. Isogenic cells, wild type except that they contained either trp:: ${Phi}$ (glnAp-lacZ) (YMC10Ap ${Phi}$ 2; +) or trp:: ${Phi}$ (glnKp-lacZ) (YMC10 ${Phi}$ ; ${circ}$ ) were grown at 30°C in defined media containing 0.004% tryptophan and 0.4% glucose with either 0.005 (A), 0.01 (B), or 0.2% (C) ammonium sulfate. At the indicated times, samples were removed and assayed for ß-galactosidase. Symbols: + and o, growth (optical density at 600 nm [OD₆₀₀]); bars, ß-galactosidase expression (white bars, YMC10Ap ${Phi}$ 2; grey bars, YMC10 ${Phi}$ ). Maximum expression was 2,640 Miller units for YMC10Ap ${Phi}$ 2 and 1,680 Miller units for YMC10 ${Phi}$ .

In similar experiments, we observed that the nac promoter, likeglnK, became activated only when growth became limited by ammoniastarvation. To better focus on the relationship between thenac and glnK promoters, we compared their activation side byside in experiments where cells became limited for ammonia attwo different optical densities, owing to different initialconcentrations of ammonium sulfate. These experiments indicatedthat nac and glnK were activated at about the same point, withnac perhaps lagging slightly behind glnK (Fig. 3).

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FIG. 3. Comparison of the activation of glnKp and nacp in response to nitrogen starvation. Isogenic cells, wild type except that they contained either trp:: ${Phi}$ (glnKp-lacZ) (YMC10 ${Phi}$ ; ${circ}$ and •) or trp:: ${Phi}$ (nacp-lacZ) (YMC10Np ${Phi}$ ; ${square}$ and ${blacksquare}$ ) were grown at 30°C in defined media containing 0.004% tryptophan and 0.4% glucose with either 0.005 ( ${circ}$ and ${square}$ ) or 0.01% (• and ${blacksquare}$ ) ammonium sulfate. The growth curves in both experiments for the two different strains were identical. At the indicated culture densities, samples were removed and assayed for ß-galactosidase. OD₆₀₀, optical density at 600 nm.

We directly examined the intracellular concentration of NRIas cells transitioned from growth on ammonia to nitrogen starvationin immunoblotting experiments (Fig. 4). Reitzer and Magasanikhad previously shown that the level of NRI in log-phase cellsgrown on nitrogen-limiting glucose-glutamine medium was $~$ 10-foldhigher than that in cells grown on nitrogen-rich glucose-ammonia-glutaminemedium (20). We observed that a low and fairly constant levelof NRI was present in cells growing on ammonia (Fig. 4). Asthe ammonia became depleted and cell growth stopped, the concentrationof NRI increased (Fig. 4). The increase in NRI concentrationoccurred concurrently with the activation of glnK and nac (compareFig. 2 and 4).

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FIG. 4. Immunoblotting analysis of the NRI concentration during growth on ammonia and the transition to nitrogen starvation. Strain YMC10 (wild type) was grown at 30°C on defined medium containing 0.4% glucose and 0.005% ammonium sulfate. Samples were harvested for Western blot analysis at the indicated times. The standard lane (std) contains 6 ng of purified NRI. Each sample lane contains 5 µg of crude protein extract. OD₆₀₀, optical density at 600 nm.

Activation of glnAp, glnKp, and nacp as cells grow on glutamine as the sole nitrogen source. Most studies of Ntr gene activation are focused on the expressionof genes in log-phase cultures growing on glutamine as the solenitrogen source. Here, we examined lac fusion expression asadapted cells grow on glutamine, providing a view of glnA, glnK,and nac regulation under these conditions (Fig. 5). When cellsgrew on glutamine, a reduction in the rate of growth occurredin mid-log phase, at an optical density at 600 nm (OD₆₀₀) of $~$ 0.5 (Fig. 5B). Prior to this reduction in growth, fusion expressionwas similar to that in cells growing on ammonia, namely, glnAwas partially activated and glnK and nac were not activated(Fig. 5A). At the point where the growth rate was reduced, fusionexpression was similar to that seen in cells that depleted alimiting ammonia concentration, namely, all three promoterswere sharply activated. The sharp transition between these twostates occurred in mid-log phase; thus, use of mid-log phaseglutamine-adapted cultures for assessment of Ntr gene expressionlevels is somewhat risky.

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FIG. 5. Activation of glnA, glnK, and nac promoter fusions in cells growing on glutamine as the sole nitrogen source. Overnight cultures were grown in 0.4% glucose-0.2% glutamine to stationary phase. Cells were diluted into similar medium, except that it contained 0.1% (wt/vol) glutamine, and incubated at 30°C. (A) Expression of ß-galactosidase. Symbols: ${square}$ , glnA-lacZYA; ${lozenge}$ , glnKp-lacZYA; ${circ}$ , nacp-lacZYA. (B) Growth of the three cultures. Symbols are as in panel A.

In vitro transcription from the glnK promoter. Since the glnAp2 and nac promoters had been examined in vitrobut the glnK promoter had not, we examined the NRI $~$ P dependenceof transcription from this promoter by using purified components.NRI $~$ P stimulates the isomerization of the closed promoter-polymerasecomplex to the open complex, competent for transcription initiation.The formation of the open complex may be assayed by examiningthe rate at which uninitiated complexes are formed in the presenceof ATP alone or by measuring the formation of short initiatedcomplexes in the absence of a single nucleotide. Because complexesof the latter type are very stable, their formation permitsassessment of activation at promoters where the open complexis unstable (7). In our transcription assays, as before (7),we controlled the concentration of NRI $~$ P by adding various concentrationsof NRI in the presence of excess NRII (NtrB). As templates weused supercoiled plasmids containing a strong transcriptionalterminator positioned downstream from the promoter of interest(7, 9, 14).

As expected, activation of glnAp2 required a lower concentrationof NRI $~$ P than did activation of glnKp when single promoters wereexamined, as well as when both promoters were present in thesame transcription reaction mixture (Fig. 6). In contrast, twotemplates containing the glnAp2 promoter positioned differentdistances from the transcriptional terminator were simultaneouslyactivated as the concentration of NRI $~$ P was increased (Fig. 6).The relative behaviors of the promoters in the in vitro transcriptionsystem were the same regardless of whether open complexes (Fig.6A) or initiated complexes (Fig. 6B) were assayed; thus, theopen complexes formed at these two promoters may have similarstabilities. The open complex at the glnK promoter seemed tobe considerably more stable than the corresponding open complexat the nac promoter since we could see evidence of their formationin experiments where heparin challenge preceded initiation (7)(Fig. 6B).

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FIG. 6. Transcription from glnAp2 and glnKp by purified components of E. coli. Transcription reaction mixtures contained the indicated supercoiled templates (10 nM each), core RNA polymerase (100 nM), ${sigma}$ ⁵⁴ (200 nM), NRII (100 nM), and the indicated concentration of NRI (nanomolar units). Reaction mixtures were incubated in the presence of ATP for the formation of open complexes (A) or in the presence of ATP, CTP, and GTP for the formation of short initiated complexes (B). Complex formation was stopped by addition of heparin, complexes were extended by addition of the missing nucleotide(s), and transcripts were recovered by phenol extraction and ethanol precipitation, subjected to electrophoresis on sequencing gels, and detected by autoradiography as described previously (7). Transcripts were labeled by use of [ ${alpha}$ -³²P]UTP. Templates pTH8 and pLR100 contained the glnA promoter positioned different distances upstream from the phage T7 terminator in the pTE103 vector. Template pglnK13 contained the glnK promoter positioned upstream from the phage T7 terminator in the pTE103 vector.

Patterns of growth on the combination of ammonia and arginine. Arginine can serve as the sole nitrogen source for E. coli,supporting a doubling time of $~$ 4 h in defined medium with excessglucose. Growth on arginine requires the presence of NRI, asthe astCADBE operon is part of the Ntr regulon (16, 23). Weexamined the growth of E. coli when both ammonia at low concentrationand arginine at high concentration were provided. The rate ofgrowth on ammonia plus arginine was indistinguishable from thatobserved with ammonia alone until all the ammonia was consumed.At that point, the cells began growing at the rate characteristicof cells using only arginine. In some cases, a short lag wasdetected. Thus, the pattern of growth on the mixture of arginineand ammonia was diauxic (Fig. 7).

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FIG. 7. Growth of E. coli on limiting ammonium sulfate and excess arginine is diauxic. Growth of YMC10 (wild type) at 30°C on defined minimal medium containing 0.4% glucose and 0.001% ammonium sulfate (+) or 0.001% ammonium sulfate and 0.2% arginine (x). OD₆₀₀, optical density at 600 nm.

DISCUSSION

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Discussion

The Ntr regulon has some resemblance to a developmental genecascade, in that genes are sequentially activated in responseto an environmental stimulus. Our results support the hypothesisthat, in the Ntr system, temporal staging of gene expressionresults from amplitude modulation of the phosphorylated formof the enhancer-binding activator protein. This amplitude modulationgives rise to the sequential activation of transcription becauseof the distinct features of the enhancers and promoter architectureat the various regulated promoters.

In cells growing on ammonia, the glnAp promoter was partiallyactivated, while the glnK and nac promoters were not. This suggeststhat, when cells grew on defined glucose-ammonia medium, thelevel of NRI $~$ P was sufficient to permit significant expressionof glnA while glnK and nac remained silent. The modest (approximatelythreefold) regulation of glnA expression by ammonia concentrationthat we observed probably reflects the fine regulation of theNRI $~$ P level when it is at the low end of its physiological range.Our immunoblotting analysis of NRI did not detect a significantincrease in NRI as the ammonia concentration of the medium wasreduced by consumption. The fairly uniform growth rate of bacteriairrespective of ammonia concentration suggests that this finecontrol of NRI $~$ P at the low end of its physiological range andthe attendant fine control of GS expression and activity enablecells to grow optimally without recourse to activation of theother Ntr genes.

The glnK and nac promoters became strongly activated when cellsstopped growing due to ammonia starvation, suggesting that atthis point the NRI $~$ P concentration was significantly increased.Our immunoblotting analysis confirmed that NRI concentrationwas increased as cells became starved. Experiments examiningthe use of arginine as a nitrogen source suggested that theastCADBE operon (16, 23) was not expressed when cells had ammoniaavailable but rather was only activated as ammonia became depleted.Thus, the glnK, nac, and astC promoters define a group of promotersthat are regulated differently from glnAp.

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TABLE 2. Plasmids used in this study

ACKNOWLEDGMENTS

This work was supported by grant GM57393 from the NIH-NIGMSto A.J.N.

FOOTNOTES

* Corresponding author. Mailing address: Department of Biological Chemistry, University of Michigan Medical School, 1301 E. Catherine, Ann Arbor, MI 48109-0606. Phone: (734) 763-8065. Fax: (734) 763-4581. E-mail: aninfa{at}umich.edu.

REFERENCES

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