Sensing of Nitrogen Limitation by Bacillus subtilis: Comparison to Enteric Bacteria

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Journal of Bacteriology, August 1999, p. 5042-5050, Vol. 181, No. 16
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Sensing of Nitrogen Limitation by Bacillus subtilis: Comparison to Enteric Bacteria

Ping Hu,¹^, Terrance Leighton,² Galina Ishkhanova,¹ and Sydney Kustu¹^,^*

Department of Plant and Microbial Biology¹ and Department of Molecular and Cell Biology,² University of California, Berkeley, California 94720

Received 4 February 1999/Accepted 11 June 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Previous studies showed that Salmonella typhimurium apparently senses external nitrogen limitation as a decrease in the concentrationof the internal glutamine pool. To determine whether the inverserelationship observed between doubling time and the glutaminepool size in enteric bacteria was also seen in phylogeneticallydistant organisms, we studied this correlation in Bacillus subtilis,a gram-positive, sporulating bacterium. We measured the sizesof the glutamine and glutamate pools for cells grown in batchculture on different nitrogen sources that yielded a range ofdoubling times, for cells grown in ammonia-limited continuousculture, and for mutant strains (glnA) in which the catalyticactivity of glutamine synthetase was lowered. Although the glutaminepool size of B. subtilis clearly decreased under certain conditionsof nitrogen limitation, particularly in continuous culture, theinverse relationship seen between glutamine pool size and doublingtime in enteric bacteria was far less obvious in B. subtilis.To rule out the possibility that differences were due to the factthat B. subtilis has only a single pathway for ammonia assimilation,we disrupted the gene (gdh) that encodes the biosynthetic glutamatedehydrogenase in Salmonella. Studies of the S. typhimurium gdhstrain in ammonia-limited continuous culture and of gdh glnA double-mutantstrains indicated that decreases in the glutamine pool remainedprofound in strains with a single pathway for ammonia assimilation.Simple working hypotheses to account for the results with B. subtilisare that this organism refills an initially low glutamine poolby diminishing the utilization of glutamine for biosynthetic reactionsand/or replenishes the pool by means of macromoleculardegradation.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

How cells perceive and respond to nutrient limitation are basic questions in microbial physiology. We have posed the firstquestion with respect to nitrogen limitation in enteric bacteriabecause nitrogen metabolism has a number of simplifying features.Among the important simplifications is that most compounds derivenitrogen by secondary transfers from only two central intermediates,the amino acids glutamate and glutamine. Because a decrease ingrowth rate is the most direct indication of nutrient limitation,we examined the correlation between nitrogen-limited growth andthe pool sizes of these two central intermediates in Salmonellatyphimurium. The results indicated that Salmonella apparentlyperceives extracellular nitrogen limitation as a decrease in theintracellular concentration of the glutamine pool (21). Similarresults were obtained for Escherichia coli and Klebsiella pneumoniae(35a), and hence the conclusion appears to generalize for entericbacteria.

To investigate whether lowering the intracellular glutamine pool was a general response to nitrogen limitation in the bacteria,we assessed this response in Bacillus subtilis. B. subtilis, alow-GC gram-positive bacterium, is phylogenetically distant fromthe proteobacteria (20), the group to which enteric bacteriabelong, and has the capacity to sporulate under certain conditionsof nutrient deprivation including nitrogen limitation (6, 34,35). In addition, B. subtilis differs from enteric bacteriain at least two other important regards. First, it has only asingle pathway for assimilation of ammonia into glutamate, theso-called glutamine synthase (GS)/glutamate synthase (GOGAT) cycle(Fig. 1), whereas enteric bacteria have this pathway and an additionalone, the reductive amination of 2-oxoglutarate catalyzed by biosyntheticglutamate dehydrogenase (7, 21, 36). Second, regulationof GS in B. subtilis is very different from that in enteric bacteria.Transcription of the glnA gene of B. subtilis, which encodes GS,is controlled negatively by the products of the glnR and tnrAgenes, and GS is not known to be posttranslationally modified(10, 12, 37, 49). By contrast, transcription of the glnAgene of enteric bacteria is controlled by the positive regulatoryelement NtrC in conjunction with the $sigma$ ⁵⁴ holoenzyme form of RNA polymerase, and GS is covalently modifiedby adenylylation (21, 45). The signals that control the functionof the GlnR and TnrA repressors of B. subtilis have not been identified(12, 36, 37, 49). Although it has been postulated thatboth glnA transcription and covalent modification of GS in entericbacteria are controlled by a ratio of glutamine to 2-oxoglutarate,in vivo evidence for this is limited (30, 44).

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FIG. 1. Pathways for assimilation of ammonia in B. subtilis (only pathway A) and enteric bacteria (pathways A and B). (A) GS/GOGAT cycle. One mole of ammonia is assimilated into glutamate for each turn of the cycle (heavy arrows). A portion of the glutamine is withdrawn for biosynthesis. Because GS has a high affinity for ammonia and ATP hydrolysis is coupled to glutamate synthesis, this pathway operates efficiently even at low ammonia concentrations. (B) Biosynthetic glutamate dehydrogenase (GDH) pathway. Because GDH has a relatively low affinity for ammonia and the reaction it catalyzes is reversible, this pathway operates efficiently only at high ammonia concentrations. GS catalyzes synthesis of glutamine from the glutamate generated by GDH (not shown).

To achieve nitrogen limitation in B. subtilis, we grew it on poor nitrogen sources in batch culture and in ammonia-limitedcontinuous culture, as we had done previously for enteric bacteria(21). We made use of a wild-type strain of B. subtilis 168 thatgrows well on minimal medium in the absence of glutamate or tricarboxylicacid cycle intermediates and a minimal medium that allows goodgrowth of this strain in the absence of such supplements (34,35). In addition, we studied glnA mutant strains that requiredglutamine for optimal growth on ammonia to see whether we coulddetect a decrease in their internal glutamine pools. Such strainsof S. typhimurium simulate nitrogen limitation internally evenwhen grown on high concentrations of ammonia. In the aggregate,our results indicate that B. subtilis initially depletes its glutaminepool upon nitrogen limitation but seems to have a mechanism(s)for refilling it. Apparently as a consequence of the latter, theclear correlation observed between the size of the glutamine pooland growth rate in enteric bacteria is far less obvious in B.subtilis.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Growth conditions for B. subtilis and S. typhimurium. The minimal medium (34, 35) was modified from Neidhardt medium (32) to optimize growth of B. subtilis. The importantmodifications were (i) increasing the morpholinepropanesulfonicacid (MOPS) buffer from 40 to 80 mM and raising the initial pHto 7.6 to provide more buffering capacity; (ii) setting the concentrationsof magnesium and manganese to 0.4 and 0.1 mM, respectively, thosesuggested by Hageman et al. (18); (iii) decreasing the calciumconcentration to 0.14 mM, 10% of that suggested by Hageman etal. (18); and (iv) removing NaCl. The B. subtilis strain failsto use either MOPS or Tricine as carbon or nitrogen source (25a),and consequently this medium serves well for ourpurposes.

S. typhimurium was grown on the MOPS medium of Neidhardt et al. (32) at 37°C, and B. subtilis was grown on modified MOPSmedium (34, 35) at the same temperature. Minimal media weresupplemented with glucose or glycerol (0.2 to 0.4%) as the carbonsource and the nitrogen sources indicated (at 10 mM total nitrogen).They were supplemented with glutamine (5 mM) and/or other aminoacids as necessary to satisfy auxotrophies. Cultures used as inoculawere grown to the late exponential phase on the same medium. Luriabroth (LB), nutrient broth, or tryptose blood agar base agar plates(Difco) were used for routine maintenance purposes; when required,the following antibiotics were added at the concentrations indicated:chloramphenicol, 10 µg/ml; ampicillin, 100 µg/ml; kanamycin, 25µg/ml; and tetracycline, 10 µg/ml.

Upshift of B. subtilis cells from nitrogen limitation to sufficiency. B. subtilis cells were grown on minimal medium with glucose or glycerol (0.2%) as the carbon source and N-acetylglucosamine(10 mM) as the sole nitrogen source. When the cells had enteredearly exponential phase (optical density at 650 nm [OD₆₅₀] of0.1 to 0.2), NH₄Cl, or arginine was added to a final concentrationof 10 mM (NH₄Cl) or 2.5 or 5 mM (arginine). As the cultures continuedto grow, samples were taken foranalysis.

Growth in ammonia-limited continuous culture. A New Brunswick Scientific BioFloC30 chemostat with a culture volume of 325 ml was used for continuous culture. The reservoirmedium contained 0.2% glucose as the carbon source and 2 mM NH₄Clas the nitrogen source. These concentrations were similar to thoseused by Dawes and Mandelstam (6) for ammonia-limited continuouscultures of B. subtilis, and the excess of glucose over NH₄Cl,which minimizes autolytic tendencies (22), was similar to thatused by Pierce et al. (34, 35) in ammonia-limited batch cultures.An exponential-phase culture of B. subtilis (OD₆₅₀ of ~0.8; 180ml) grown in the same medium with 10 mM NH₄Cl was used to inoculatethe chemostat. The culture was aerated rapidly with stirring at>500 rpm and maintained constant pH. Dilution rates were adjustedas shown in Table 3. Samples were taken to determine (i) opticaldensity of the culture; (ii) amount of ammonia remaining in themedium (Ammoniak kit [Sigma Chemical Co., St. Louis, Mo.]); detectionlimit, (~20 µM); (iii) $beta$ -galactosidase activity; and (iv) glutamateand glutamine pool sizes. The samples were stored at $-$ 80°C untilthey wereanalyzed.

To determine the percentage of spores in chemostat cultures, fresh samples were diluted with LB medium and spread on LB ortryptose blood agar base agar plates for cell counts. Sampleswere also heated at 80°C for 20 min or extracted with chloroformand then diluted and spread to determine the number of spores.In addition to this quantitative method for assessing sporulation,samples were examined microscopically for the appearance of refractility.Refractile spores were seen microscopically when the incidenceof sporulation was 0.5% or higher but not when the incidence was $<=$ 0.1%.

The S. typhimurium gdh strain SK3121 (Table 1) was grown in ammonia-limited continuous culture as described previously (21).

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TABLE 1. Bacterial strains used

Plasmid and strain constructions. Plasmid pSF14, which carries the glnR and glnA genes of B. subtilis and the region upstream of the transcriptional start sitenecessary for nitrogen regulation (14, 17, 40), was providedby H. J. Schreier. Plasmid pHJS57, which carries just the glnAgene of B. subtilis (37), was a gift from A. L. Sonenshein.Genetic manipulations of B. subtilis were performed as describedby Harwood and Cutting (19).

The promoter for the glnRA operon of B. subtilis was subcloned from pSF14 to pDH32, a B. subtilis integration vector witha promoterless lacZ gene, in the following several steps. TheDraI-SacI fragment from pSF14, which begins at position $-$ 84 withrespect to the glnR transcriptional start and carries the promoterand part of the glnR gene, was cloned into the HincII-SacI sitesof a pBluescript II SK vector (Stratagene) to yield pGH1. TheXhoI-SacI fragment from pGH1, which carries the entire glnR promoterinsert, was then cloned into the SalI and SacI sites of pTZ19to yield pGH2, and the HindIII-EcoRI fragment from pGH2 that carriesthe glnR promoter insert was recloned into pBluescript to yieldpGH3. Plasmid pGH3 was digested with HpaI, which cleaves at position+75 with respect to the glnR transcriptional start (55 bp downstreamof the translational start), and SmaI; the larger fragment wasreligated to delete the portion of glnR after position +75 (plasmidpGH4). The BamHI-KpnI fragment of pGH4, which carries the glnRpromoter insert (positions $-$ 84 to +75), was cloned into pTZ19to yield pGH5. The EcoRI-BamHI fragment of pGH5, which carriesthe glnR promoter insert, was then cloned into pDH32, which carriesonly EcoRI and BamHI as cloning sites, to yield the requisitelacZ fusion (plasmid pGH6). Finally, pGH6 was linearized withScaI and transformed into B. subtilis to yield a glnRA promoter(glnRAp)-lacZ transcriptional fusion integrated at the amyE locus(16, 47). In this cloning, the DraI and HpaI sites were inthe glnRAp insert whereas all other sites were in thevectors.

Integration of a Salmonella glnA-lacZ fusion at the put locus of S. typhimurium has been described elsewhere (21). Thisfusion was transferred to other strains by phage P22-mediatedtransduction. Plasmid pGln14, which carries $Delta$ glnA14::Spc^r (2), was obtained from Susan Fisher and was used to constructstrain B134, which carries the deletion-insertion on the chromosome(Table 1, footnote e).

Isolation and growth of leaky glnA mutants. Isolation of leaky glnA mutants of B. subtilis (Table 1) was accomplished in two steps: (i) isolation of glutamine auxotrophicstrains and (ii) selection of revertant strains that could growwith NH₄Cl as the sole nitrogen source in the absence ofglutamine.

We first attempted to isolate leaky glnA mutant strains of B. subtilis by the positive selection procedure of Kustu and McKereghan(25), which was initially used in S. typhimurium and was thensuccessfully employed to isolate glutamine auxotrophs of B. subtilis(7). Selection is for growth on D-histidine as the histidinesource in a strain carrying a stable lesion in the histidine biosyntheticoperon. The nitrogen source is NH₄Cl. In Salmonella, the selectionis known to be based on the fact that a decrease in the glutaminepool leads to physiological derepression of a transport systemfor D-histidine and that transport rather than racemization limitsuse of D-histidine to satisfy histidine auxotrophy (24, 25).To employ the selection in B. subtilis, we first introduced thehisA82::Tn917 lesion into our wild-type strain by phage PBS1-mediatedtransduction from donor strain 1A626 (Table 1), with selectionfor erythromycin resistance. The resulting strain, B278, was thenused as the parental strain for selection of spontaneous D-histidineutilizers. Of the small colonies picked after 3 days of incubation,12 grew normally on minimal medium containing L-histidine whenit was supplemented with glutamine. Of these 12, only 1 had alesion in glnA (see below). This strain, B13, was a glutamineauxotroph (that is, it did not grow detectably on NH₄Cl in liquidculture in the absence of glutamine or of glutamate or a sourceof glutamate such as proline); since glutamine is the obligatoryprecursor of glutamate in B. subtilis (Fig. 1), glutamate sparesthe glutamine requirement. The lesion in B13 was localized toglnA by three means: (i) it could be transferred to strain B134( $Delta$ glnA14::Spc^r) by transformation to growth on proline plus NH₄Cl, and othergrowth phenotypes (Table 6) were also inherited; (ii) it couldbe complemented by plasmid pHJS57, which carries just glnA; and(iii) it was cloned, and the sequence change in glnA was determined.(Nine of the twelve strains that grew optimally with glutaminealso grew optimally with glutamate. Based on Western blottingfor glutamine synthetase, at least three or four of these werenot derepressed for glnA expression, and hence these nine strainswere not studied further. Two of the twelve strains that grewoptimally with glutamine were glutamine auxotrophs with lesionsin glnR [apparently glnR* lesions] [37, 39].)

From the glutamine auxotrophs B13 and 1A174 (8) and the glutamine auxotroph SK3095 (glnA53 gdh-51 zch-1453::Tn10) of S.typhimurium, we selected partial revertants that could grow onammonia, which included leaky glnA mutant strains. The lesionsin strains 1A174 and B40, which was derived from 1A174, were localizedto glnA by the three means described above. The glnA region ofall mutant strains of B. subtilis was cloned by PCR, and its sequencewas determined to identify mutations. For strains B32, B277, andB276, mutations resulted in the following amino acid substitutionsin GS: P306H, G243S, and both G243S and Y308H, respectively (19a).The GS activities of these strains in crude cell extracts withMg²⁺ as the divalent cation were <0.005, <0.005, and 0.018 µmol/min/mgof protein, respectively, whereas that of the wild-type strainwas 0.022 µmol/min/mg of protein (19a).

Determination of enzyme activities. GS activities of wild-type and mutant strains of B. subtilis were determined as described by Dean et al. (8) except thatcells were broken by sonication and the assay temperature was37°C. $beta$ -Galactosidase activity was determined by the method ofMiller (29), and protein concentration was determined by themethod of Bradford (4). Polyclonal antiserum directed againstB. subtilis GS was obtained from A. L.Sonenshein.

Measurement of amino acid pool size (no-harvest protocol). All strains used to measure amino acid pools were histidine prototrophs. Cell suspension (0.2 volume) was added directly toice-cold methanol (0.8 volume) so that the cell membrane wouldbe disrupted immediately with minimum disturbance of prior physiologicalstate (21). Aspartic acid and $alpha$ -aminoadipic acid were addedas internal standards to correct for losses during subsequentmanipulations. Generally, $alpha$ -aminoadipic acid was used for calculations,because the aspartate pool of B. subtilis was substantial in somecases. After lyophilization, samples were stored at $-$ 80°C andwere then prepared for analysis as described elsewhere (21).Amino acids were derivatized with o-phthaldialdehyde, and derivativeswere separated on a reversed-phase high-pressure liquid chromatographycolumn (4.6 by 100 mm; C₁₈; Rainin model 80-OPA-C3), using theconditions described previously (21). Amounts of amino acidswere determined by fluorescence; the limit of detection is 2 to3 pmol (26).

To check for the presence of amino acids in media, cell suspensions were rapidly filtered (0.2-µm-pore-size Millipore filters),and the first medium to be collected was analyzed. Glutamate wasdetected in the culture medium when cells were grown on prolineas the nitrogen source, presumably due to leakage or excretion.No significant amount of glutamine was observed in the culturemedium under these conditions, and little of either amino acidwas detected in the medium when cells were grown on any of theother nitrogen sourcesused.

Errors for the glutamate and glutamine pool concentrations in Tables 2, 5, and 6 are the maximum difference between individualvalues for an experiment and the average value that is presented.Values were determined for cells at three points during exponentialgrowth (OD₆₅₀ of between 0.12 and 0.75). Errors for the glutamatepool concentration were rounded up to the nearest 5, whereas thosefor the glutamine pool concentration were rounded up to the nearestunit.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Glutamine pools of B. subtilis grown on different nitrogen sources in batch culture. As we had for S. typhimurium (21), we used two criteria for nitrogen-limited growth of B. subtilis: first, that the doublingtime of the culture was longer than that on glutamine or arginine,the optimal nitrogen sources for Bacillus; and second, that glnAexpression was elevated (12, 36). We took the latter as anindication that slowing of growth was due to nitrogen limitationrather than another limitation or an inhibitory effect of whichwe were unaware. B. subtilis B23, a derivative of wild-type strain168 carrying a fusion of the glnRA promoter to lacZ (glnRAp-lacZ)at the amyE locus, was grown on modified MOPS medium (35) withglucose or glycerol (0.2%) as the carbon source and glutamine,arginine, NH₄Cl, proline, $gamma$ -aminobutyric acid (GABA), urea, orN-acetylglucosamine (10 to 20 mM nitrogen) as the nitrogen source(13). Glutamine and arginine, the best nitrogen sources forB. subtilis, yielded doubling times of ~48 min on both carbonsources (Table 2); ammonia, GABA, proline, and urea yielded doublingtimes of ~60 to 85 min. Commensurate with doubling times, expressionfrom glnRAp was higher on the other nitrogen sources than on glutamineand arginine. N-Acetylglucosamine, which could be catabolizedonly with glycerol as the carbon source, yielded a doubling timeof 395 min, but expression from glnRAp (550 U) was almost as lowas that on arginine (420 U) and was well below that on proline,GABA, or urea ( $>=$ 3,000 U in each case). The latter provided thefirst indication that N-acetylglucosamine was not simply a limitingnitrogensource.

As described previously (21) (see also Materials and Methods), samples were removed from each culture at three times duringexponential growth (OD₆₅₀ of 0.12 to 0.75) and assayed for glutamateand glutamine pools. The data were averaged and are presentedas single points in Table 2. The glutamate pool size was veryhigh with arginine as the nitrogen source (520 or 390 nmol/mg[dry weight] with glucose or glycerol, respectively, as the carbonsource). Although the pool size decreased somewhat with ammoniaas the nitrogen source (360 or 290 nmol/mg [dry weight] with glucoseor glycerol, respectively, as the carbon source), it increasedagain with proline (data not shown) and remained at least as highwith GABA or urea as it was with ammonia. Because doubling timeson proline, GABA, and urea were longer than on ammonia and glnAexpression was higher, nitrogen limitation did not appear to correlatewith a decrease in the glutamate pool size. The glutamate poolwas markedly lower on N-acetylglucosamine than on other nitrogensources (130 nmol/mg [dry weight]).

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TABLE 2. Growth, pool sizes, and glnRAp-lacZ expression of B. subtilis^a batch cultures on different nitrogen sources

Although the glutamine pool was more than 2.5-fold lower on ammonia than on arginine (increase in doubling time of ~13 min),there was no further decrease in this pool on other poor nitrogensources including N-acetylglucosamine. Hence, nitrogen limitationdid not appear to correlate with a drop in the glutaminepool.

Having observed two peculiarities in the behavior of cells grown on N-acetylglucosamine as the nitrogen source (low expressionfrom glnRAp and a low glutamate pool) we wanted to test furtherwhether N-acetylglucosamine was simply a limiting nitrogen sourceor whether it inhibited growth on better nitrogen sources suchas arginine or ammonia (21). When cells were grown on N-acetylglucosamine,addition of arginine or NH₄Cl did not result in an increase inthe growth rate for more than 2 h. Moreover, even when the cellshad fully adapted to the presence of both nitrogen sources, thedoubling time on a mixture of arginine (2.5 or 5 mM) and N-acetylglucosamine(5 mM) or of NH₄Cl (5 mM) and N-acetylglucosamine (5 mM) was 60or 70 min, respectively, whereas the corresponding doubling timein the absence of N-acetylglucosamine was 48 or 60 min. Thus,N-acetylglucosamine appeared to inhibit growth on the two preferrednitrogensources.

Glutamine pools of B. subtilis in ammonia-limited continuous culture. To overcome potential complications of using different compounds to achieve nitrogen limitation, including the complicationthat most yielded carbon skeletons as well as ammonia or othernitrogen-containing intermediates, we turned to the use of ammonia-limitedcontinuous culture. When the dilution rate of an ammonia-limitedchemostat was decreased sufficiently for B. subtilis to depleteammonia from the medium completely (Table 3, sample 6), the glutaminepool dropped sevenfold and glnRAp-lacZ expression was elevatedabout sixfold. (There was no decrease in the glutamate pool.)However, surprisingly, when the dilution rate was decreased slightlymore (samples 7 to 9), the glutamine pool rose to about half ofthe maximum value seen in the chemostat, despite the fact thatresidual ammonia in the medium remained undetectable and glnRAp-lacZexpression remained maximal. When the culture was cycled by againincreasing the dilution rate (samples 10 to 12), all parametersreturned to those characteristic of nitrogen sufficiency (samples1 to 3). Upon a second decrease in the dilution rate (samples15 and 16), ammonia was depleted from the medium, glnRAp-lacZexpression rose to the maximum value seen in the chemostat, andthe glutamine pool again dropped, although only some fourfold.Thus, the glutamine pool decreased to a value between the lowestand highest values seen when the dilution rate was decreased thefirst time.

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TABLE 3. Residual ammonia, pool sizes, and glnRAp-lacZ expression of B. subtilis^a grown in ammonia-limited continuous culture^b

To observe the largest decrease in the glutamine pool upon the first lowering of the dilution rate of the culture (sevenfoldin the experiment above), a sample had to be taken before theculture had adapted. In the two experiments performed, the decreasein the pool size was smaller once the culture had adapted to thelow dilution rate. In a single experiment in which the culturewas started at a low dilution rate and allowed to adapt, we sawno change in pools or glnRAp-lacZ expression when the dilutionrate was increased. We have no explanation for this. Even after40 h at the lowest dilution rate used (0.37), the degree of sporulationwas <3% (see Materials and Methods), comparable to values reportedby Dawes and Mandelstam at this dilution rate (6). At highdilution rates, the degree of sporulation was <0.1% (data notshown).

To eliminate the possibility that the unexpected instability of the glutamine pool in B. subtilis at low dilution rates wasdue to the fact that it had only a single pathway for ammoniaassimilation, we examined the behavior of a gdh mutant strainof S. typhimurium, SK3121, in an ammonia-limited chemostat. Aswas true for wild-type S. typhimurium (21), the glutamine pooldecreased >10-fold at dilution rates low enough to result in depletionof ammonia from the medium (Table 4, samples 1, 2, 8, 9, 10,and 11). The glutamate pool decreased <1.6-fold under these conditions,and glnA expression was maximal. By contrast to the case for B.subtilis, the glutamine pool remained low (below our limit ofreliable detection) until the dilution rate was increased. Thus,results for the gdh mutant strain of Salmonella provided no evidencefor fluctuation of the glutamine pool at low dilution rates inan organism employing only the GOGAT cycle for ammonia assimilation.We note parenthetically that glnA expression decreased littlein the gdh mutant strain of Salmonella at high dilution rates,a result different from that for the wild-type strain (21).As observed by others (27, 41, 42, 46), both glutamineand glutamate pools of S. typhimurium were markedly lower thanthose of B. subtilis even under conditions of ammonia sufficiency.

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TABLE 4. Residual ammonia, pool sizes, and glnA-lacZ expression of an S. typhimurium gdh mutant strain^a grown in ammonia-limited continuous culture^b

Glutamine pools in glnA mutant strains of B. subtilis. Leaky glnA mutant strains (glutamine bradytrophs) of S. typhimurium are able to grow on ammonia as the sole nitrogen sourcebut grow optimally only when glutamine is added (21, 25).When they are grown on ammonia alone, their internal glutaminepools are low and glnA expression is maximal. The growth behaviorof such mutant strains allowed us to calibrate growth rate asa function of glutamine pool size and thereby demonstrate thatdecreases in the glutamine pool observed in wild-type Salmonellaunder nitrogen-limiting conditions were, in fact, sufficient toaccount for slow growth (21).

Growth defects in the four Salmonella glnA mutant strains and the accompanying decreases in the glutamine pool, but not theglutamate pool, are documented in Table 5. When the gdh-51 lesion(28) was present in these strains and hence they had only theGOGAT cycle for synthesis of glutamate, their growth rates onammonia were dramatically lower (Table 5) and, in fact, two ofthe strains failed to grow (i.e., they became outright glutamineauxotrophs). For the two glnA gdh strains of Salmonella that retainedthe ability to grow on ammonia, glutamine pools were very low(Table 5). The glutamate pool in these strains decreased <2-foldeven at a doubling time as long as 300 min.

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TABLE 5. Growth, pool sizes, and glnA-lacZ expression of S. typhimurium glnA and glnA gdh mutants

We made comparable measurements for leaky glnA mutant strains of B. subtilis, which also have only the GOGAT cycle for ammoniaassimilation. These strains grew as rapidly as the congenic wildtype on glutamine as the nitrogen source or on glutamine and NH₄Clas nitrogen sources (Table 6). As had been observed previouslyfor other glnA strains of B. subtilis (12, 36), glnRAp-lacZexpression was very high for these strains (5,300 to 7,000 U/ml/OD₆₅₀)when they were grown on glutamine or glutamine and NH₄Cl as nitrogensources, whereas expression in the wild-type strain was minimalunder these conditions (~140 U/ml/OD₆₅₀).

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TABLE 6. Growth, glutamine pool sizes, and glnRAp-lacZ expression of B. subtilis glnA mutants

All three of the glnA mutant strains could grow on ammonia if proline was also provided as a source of glutamate with glucoseor glycerol as the carbon source (Table 6). However, all of themutant strains grew more slowly than the wild type on ammoniaplus proline (doubling times of 60 to 160 min), whereas the wildtype retained its optimal growth rate (doubling time of 48 min).All three mutant strains had lower glutamine pools than did thewild type, and the two faster-growing strains, B276 (G243S, Y308C)and B277 (G243S), expressed glnRAp-lacZ at very high levels (6,000to 7,500 U/ml/OD₆₅₀). The slowest-growing mutant strain, B32 (P306H),expressed glnRAp-lacZ at about the same level as the wild typeon this mixture of nitrogen sources (~700 U/ml/OD₆₅₀). The lowglnRAp-lacZ expression in strain B32 was reminiscent of that inthe wild-type strain grown on N-acetylglucosamine as the solenitrogen source (Table 2), and we can only speculate that itmay be related to slow growth (doubling time of 150 min orlonger).

The two mutant strains that grew fastest on ammonia plus proline, B276 and B277, could also grow on proline as the sole nitrogensource. Again, their doubling times were longer than that of thewild-type strain on proline and their glutamine pools were lowerthan that of the wild type. Expression of glnRAp-lacZ was highin all of the strains including the wildtype.

Only the mutant strain that grew fastest on proline, B276, was also able to grow on ammonia as the sole nitrogen source. Surprisingly,its glutamine pool was greater than that of the wild-type straindespite its low growth rate (doubling time of ~125 min). Expressionof glnRAp-lacZ was clearly greater than that in the wild-typestrain (4,300 U/ml/OD₆₅₀ for the mutant versus 800 for the wildtype). Both the glutamine pool and glnRAp-lacZ expression arereminiscent of those in the wild-type strain as it adapted tolow dilution rates in an ammonia-limited chemostat (Table 3,samples 7 to 9 and samples 5 and 16). Results of a number of additionalexperiments, in which growth and washing of cultures used as inoculawere varied, indicated (data not shown) (i) that the glutaminepool size of B276 was at least as high as that of B23 (wild type)with NH₄Cl as the sole nitrogen source (NH₄Cl also used as solenitrogen source for inocula); (ii) that the glutamine pool sizeof B276 could be up to four- to fivefold higher than that of B23when cultures used for inocula were supplemented with glutamine(5 mM), whether or not they were subsequently washed; (iii) thatthe glutamate pool size of B276 was normal (see also Table 6,footnote c); and (iv) that glnRAp-lacZ expression in B276 wasmuch greater than that inB23.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Despite a number of peculiarities in its responses, B. subtilis, like S. typhimurium, appears to perceive external nitrogenlimitation as internal glutamine limitation, at least initially.The clearest evidence for this conclusion came from measurementsof pool sizes of glutamate and glutamine for a wild-type strainof B. subtilis 168 grown in an ammonia-limited chemostat (Table3). (Unlike the case for wild-type S. typhimurium (21), poolsof this strain grown on different nitrogen sources in batch culturewere not readily interpretable [Table 2 and Results].) Upon initialdepletion of ammonia from the medium in an ammonia-limited chemostat(low dilution rate), wild-type B. subtilis decreased its glutaminepool 7.5-fold but did not decrease its glutamate pool. Unexpectedly,the glutamine pool was partially refilled with time, althoughglnRAp-lacZ expression remained maximal. On a subsequent cycleof ammonia depletion (cycling through high and then low dilutionrates) the glutamine pool was again decreased, but only ~4-fold.Two simple hypotheses that might account for partial refillingof an initially low glutamine pool are (i) that B. subtilis decreasesutilization of glutamine for biosynthetic reactions and therebypropagates a single primary limitation into several secondarylimitations and (ii) that Bacillus increases degradation of nitrogen-containingcompounds, e.g., by proteolysis (3, 23, 31, 33). Thesehypotheses remain to be tested. Whether replenishment of the glutaminepool is related to the fact that Bacillus can sporulate upon nutrientlimitation (6, 34, 35) is not clear, but it cannot be accountedfor simply by massive sporulation in the chemostat because sporulationremained <3% even at the lowest dilution rateused.

Both wild-type S. typhimurium and a gdh mutant strain deplete their internal glutamine pools abruptly when ammonia is exhaustedfrom the medium in an ammonia-limited chemostat (Table 4) (21).By contrast to the case for Bacillus, the pool remains low foras long as external ammonia remains undetectable, i.e., for aslong as the low dilution rate required for complete depletionof ammonia is maintained. As is usually the case, cycling of theculture through a high and then a low dilution rate yielded exactlythe same results as were obtained the first time. Since the gdhmutant strain has only one pathway for ammonia assimilation $---$ theGOGAT cycle $---$ as does B. subtilis, results with the Salmonella gdhstrain indicate that the peculiar replenishment of the glutaminepool observed in Bacillus is not a consequence of its having onlya single pathway for ammonia assimilation and glutamatesynthesis.

The capacity of B. subtilis to modulate its glutamine pool in ways not seen in S. typhimurium or other enteric bacteria (35b)was apparently manifested in a leaky glnA mutant strain as wellas the wild-type strain (Table 6). Although the three leaky glnAstrains of Bacillus that we tested did deplete their glutaminepools in predictable ways when grown on a combination of ammoniaand proline as nitrogen sources or on proline alone, the one strainable to grow on ammonia in the absence of other supplements, B276,had a higher glutamine pool than the wild type on this nitrogensource despite its long doubling time. We note in this connectionthat the leaky glnA strains generally showed both depletion oftheir internal glutamine pool concentrations and elevation ofglnA expression when they were grown in the presence of an externalsource of glutamate, i.e., proline. Apparent replenishment ofthe glutamine pool in B276 occurred when this strain was grownon ammonia as sole nitrogen source, as it did in the wild-typestrain in an ammonia-limited chemostat (Table 3). Whether thisunexpected behavior in the absence of an external source of glutamateis related to the fact that most strains of B. subtilis requireglutamate, or an amino acid such as proline that yields glutamatereadily, to grow well in defined minimal medium (1, 6, 11,34, 35) is unclear, as is the basis for the growth stimulationbyglutamate.

In both B. subtilis and S. typhimurium, the glnA gene, which encodes GS, is transcribed at high levels when the glutaminepool is low. However, it is clear that a low glutamine pool isnot required for high levels of glnA expression (e.g., resultsfor wild-type B. subtilis grown on GABA or urea in batch culture[Table 2]), glnA mutant strain B276 grown on ammonia in batchculture [Table 6], and a Salmonella gdh mutant strain grown underammonia-sufficient conditions in the chemostat [Table 4]). Schreieret al. (42), Deshpande et al. (9), and Fisher and Sonenshein(15) have all reported that glnA expression in B. subtilis canbe high independent of a drop in the glutamine pool (12, 36).Potential roles of other metabolites in controlling glnA transcriptionin both Bacillus and Salmonella remain to be elucidated, as dothe roles of GS itself and the TnrA product in B. subtilis (5,12, 36, 38, 43, 49).

	ACKNOWLEDGMENTS

We are very grateful to Susan Fisher, Hal Schreier, and Linc Sonenshein for gifts of materials andadvice.

This work was supported by NIH grant GM38361 to S.K.

	FOOTNOTES

^* Corresponding author. Mailing address: 111 Koshland Hall, UC Berkeley, Berkeley, CA 94720-3102. Phone: (510) 643-9308. Fax:(510) 642-4995. E-mail: kustu{at}nature.berkeley.edu.

Present address: diaDexus, LLC, Santa Clara, CA95054.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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	ALL ASM JOURNALS

1.	Aronson, J. N., J. F. Doerner, E. W. Akers, D. P. Borris, and M. Mani (ed.). 1975. $gamma$ -Aminobutyric acid pathway of glutamate metabolism by Bacillus thuringiensis. American Society for Microbiology, Washington, D.C.
2.	Atkinson, M. R., and S. H. Fisher. 1991. Identification of genes and gene products whose expression is activated during nitrogen-limited growth in Bacillus subtilis. J. Bacteriol. 173:23-27[Abstract/Free Full Text].
3.	Bernlohr, R. W. 1972. ¹⁸Oxygen probes of protein turnover, amino acid transport, and protein synthesis in Bacillus licheniformis. J. Biol. Chem. 247:4893-4899[Abstract/Free Full Text].
4.	Bradford, M. M. 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal. Biochem. 72:248-254[Medline].
5.	Brown, S. W., and A. L. Sonenshein. 1996. Autogenous regulation of the Bacillus subtilis glnRA operon. J. Bacteriol. 178:2450-2454[Abstract/Free Full Text].
6.	Dawes, I. W., and J. Mandelstam. 1970. Sporulation of Bacillus subtilis in continuous culture. J. Bacteriol. 103:529-535[Abstract/Free Full Text].
7.	Dean, D. R., and A. I. Aronson. 1980. Selection of Bacillus subtilis mutants impaired in ammonia assimilation. J. Bacteriol. 141:985-988[Abstract/Free Full Text].
8.	Dean, D. R., J. A. Hoch, and A. I. Aronson. 1977. Alteration of the Bacillus subtilis glutamine synthetase results in overproduction of the enzyme. J. Bacteriol. 131:981-987[Abstract/Free Full Text].
9.	Deshpande, K. L., J. R. Katze, and J. F. Kane. 1981. Effect of glutamine on enzymes of nitrogen metabolism in Bacillus subtilis. J. Bacteriol. 145:768-774[Abstract/Free Full Text].
10.	Deuel, T. F., A. Ginsburg, H. Yeh, E. Shelton, and E. R. Stadtman. 1970. Bacillus subtilis glutamine synthetase. Purification and physical characterization. J. Biol. Chem. 245:5195-5205[Abstract/Free Full Text].
11.	Donnellan, J. E., Jr., E. H. Nags, and H. S. Levinson. 1964. Chemically defined synthetic media for sporulation and for germination and growth of Bacillus subtilis. J. Bacteriol. 87:332-336[Abstract/Free Full Text].
12.	Fisher, S. H. 1999. Regulation of nitrogen metabolism in Bacillus subtilis: vive la difference! Mol. Microbiol. 32:223-232[Medline].
13.	Fisher, S. H. 1993. Utilization of amino acids and other nitrogen-containing compounds, p. 221-228. In A. L. Sonenshein, J. A. Hoch, and R. Losick (ed.), Bacillus subtilis and other gram-positive bacteria. American Society for Microbiology, Washington, D.C.
14.	Fisher, S. H., M. S. Rosenkrantz, and A. L. Sonenshein. 1984. Glutamine synthetase gene of Bacillus subtilis. Gene 32:427-438[Medline].
15.	Fisher, S. H., and A. L. Sonenshein. 1984. Bacillus subtilis glutamine synthetase mutants pleiotropically altered in glucose catabolite repression. J. Bacteriol. 157:612-621[Abstract/Free Full Text].
16.	Grandoni, J. A., S. B. Fulmer, V. Brizzio, S. A. Zahler, and J. M. Calvo. 1993. Regions of the Bacillus subtilis ilv-leu operon involved in regulation by leucine. J. Bacteriol. 175:7581-7593[Abstract/Free Full Text].
17.	Gutowski, J. C., and H. J. Schreier. 1992. Interaction of the Bacillus subtilis glnRA repressor with operator and promoter sequences in vivo. J. Bacteriol. 174:671-681[Abstract/Free Full Text].
18.	Hageman, J. H., G. W. Shankweiler, P. R. Wall, K. Franich, G. W. McCowan, S. M. Cauble, J. Grajeda, and C. Quinones. 1984. Single, chemically defined sporulation medium for Bacillus subtilis: growth, sporulation, and extracellular protease production. J. Bacteriol. 160:438-441[Abstract/Free Full Text].
19.	Harwood, C. R., and S. M. Cutting. 1990. Molecular biological methods for Bacillus. John Wiley & Sons, New York, N.Y.
19a.	Hu, P. Unpublished data.
20.	Hugenholtz, P., C. Pitulle, K. L. Hershberger, and N. R. Pace. 1998. Novel division level bacterial diversity in a Yellowstone hot spring. J. Bacteriol. 180:366-376[Abstract/Free Full Text].
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