G-Protein Control of the Ribosome-Associated Stress Response Protein SpoT

The bacterial response to stress is controlled by two proteins,RelA and SpoT. RelA generates the alarmone (p)ppGpp under aminoacid starvation, whereas SpoT is responsible for (p)ppGpp hydrolysisand for synthesis of (p)ppGpp under a variety of cellular stressconditions. It is widely accepted that RelA is associated withtranslating ribosomes. The cellular location of SpoT, however,has been controversial. SpoT physically interacts with the ribosome-associatedGTPase CgtA, and we show here that, under an optimized saltcondition, SpoT is also associated with a pre-50S particle.Analysis of spoT and cgtA mutants and strains overexpressingCgtA suggests that the ribosome associations of SpoT and CgtAare mutually independent. The steady-state level of (p)ppGppis increased in a cgtA mutant, but the accumulation of (p)ppGppduring amino acid starvation is not affected, providing strongevidence that CgtA regulates the (p)ppGpp level during exponentialgrowth but not during the stringent response. We show that CgtAis not associated with pre-50S particles during amino acid starvation,indicating that under these conditions in which (p)ppGpp accumulates,CgtA is not bound either to the pre-50S particle or to SpoT.We propose that, in addition to its role as a 50S assembly factor,CgtA promotes SpoT (p)ppGpp degradation activity on the ribosomeand that the loss of CgtA from the ribosome is necessary formaximal (p)ppGpp accumulation under stress conditions. Intriguingly,we found that in the absence of spoT and relA, cgtA is stillan essential gene in Escherichia coli.

INTRODUCTION

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INTRODUCTION

A pleiotropic physiological response termed the "stringent response,"which involves a rapid down regulation of rRNA biosynthesisand ribosome production, occurs when bacterial cells encounternutritional stresses such as amino acid starvation (5). Accompanyingthis response is the accumulation of ppGpp (guanosine 3',5'-bispyrophosphate)and pppGpp (guanosine 3'-diphosphate,5'-triphosphate), collectivelycalled (p)ppGpp (5). (p)ppGpp is a global regulator that accumulatesin response to a variety of nutritional and growth arrest stressconditions. The regulatory function is exerted mainly at thetranscriptional level through binding to the RNA polymerasecore enzyme (33). (p)ppGpp nucleotides are synthesized by transferof the pyrophosphate group from ATP to either GDP or GTP (5,8).

In Escherichia coli, the (p)ppGpp level is maintained by twoproteins, RelA and SpoT (5, 8), although most bacteria haveonly one RelA/SpoT protein. RelA is a (p)ppGpp synthetase anda well-established ribosome-associated protein (15, 40, 55).The (p)ppGpp synthetase activity of RelA is activated by unchargedtRNA at the ribosome A site (19) and is partially dependenton the large ribosomal protein L11 (55, 58). SpoT is a bifunctionalenzyme that possesses both (p)ppGpp synthetase and hydrolaseactivity (ppGpp is hydrolyzed to 5'-GDP and PP_i and pppGpp ishydrolyzed to 5'-GTP and PP_i) (21, 22, 27, 57). The cellularlocalization of SpoT, however, is unclear. SpoT enzymatic activitywas reported in ribosome-containing fractions but not with ribosomeswashed with 0.5 M NH₄Cl, suggesting that it associates weaklywith ribosomes (20, 48). Moreover, the hydrolase activity ofSpoT is inhibited in the presence of uncharged tRNA and moreseverely inhibited in the presence of ribosomes (42), suggestingthat the activity of SpoT may be controlled by tRNA on the ribosome,as seen with RelA. SpoT was not, however, found associated withthe ribosomal particles by sucrose density centrifugation (15).

The E. coli GTPase CgtA (also called ObgE, YhbZ, or CgtA_E) isimportant for late 50S ribosome assembly (25, 43). The Obg/CgtAproteins have also been implicated in a variety of other cellularprocesses including DNA replication, sporulation, morphologicaldifferentiation, and stress responses (3, 11, 13, 29, 39, 46,53, 56). The relationship between the role of Obg/CgtA proteinsin ribosome assembly and these other functions is not well characterized.

Several lines of evidence suggest that Obg/CgtA proteins arerelated to cellular stress responses. First, in Bacillus subtilis,Obg cocrystallized with ppGpp (3). In vitro, higher concentrationsof ppGpp inhibit the GTP hydrolysis activity of Obg, whereaslower concentrations of ppGpp stimulate hydrolysis (3). Second,B. subtilis Obg interacts with several regulators (RsbT, RsbW,and RsbX) necessary for the stress activation of ${sigma}$ ^B, the globalcontroller of the stress regulon in B. subtilis (46). It hasbeen shown that RelA is also important for ${sigma}$ ^B activation independentof (p)ppGpp synthesis, providing a functional relationship betweenObg and RelA in B. subtilis. Third, the Saccharomyces cerevisiaeObg/CgtA protein Rbg1p interacts with Gir2p, which, in turn,interacts with Gcn1p, a protein participating in the stressresponse pathway in yeast (P. K. Wout and J. R. Maddock, unpublisheddata). Rbg1p, Gir2p, and Gcn1p all associate with translatingpolyribosomes (44; Wout and Maddock, unpublished), indicatingthat they may belong to the same complex on the polysomes. Fourth,the E. coli CgtA specifically interacts with SpoT (56). Yeasttwo-hybrid studies demonstrated that CgtA interacts with boththe N-terminal catalytic and the C-terminal regulatory (ACT)domain of SpoT (56).

In this report we provide evidence that CgtA regulates the activityof SpoT on pre-50S particles. We describe the ribosome associationof SpoT and a further examination of the physical and functionalrelationships among CgtA, SpoT, and the ribosome. We show thatSpoT is also ribosome associated and that the positions of SpoTand CgtA in sucrose gradients overlap. Overexpression and loss-of-functionstudies show that the ribosome associations of SpoT and CgtAare mutually independent. Interestingly, CgtA is not associatedwith the ribosomes under conditions in which (p)ppGpp is vastlyaccumulated in the cell. In the steady state, the level of (p)ppGppis increased in a cgtA mutant. In E. coli, the essential natureof CgtA is not entirely due to its control of SpoT. We proposethat, on the pre-50S particle, CgtA regulates the hydrolysisactivity of SpoT during steady-state growth. Moreover, we proposethat the mechanism to prevent the regulation of SpoT by CgtAduring stringent response involves the relocalization of CgtA.

MATERIALS AND METHODS

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MATERIALS AND METHODS

E. coli strains, culture conditions, and growth measurements. E. coli strains used in this study are described in Table 1.The cgtAG80ED85N mutant (hereafter called the cgtA mutant) islethal at 42°C, grows slowly at 30°C, and has been describedpreviously (25, 28). To create a markerless ${Delta}$ relA strain, JM4873(BW25113 ${Delta}$ relA::kan) (1) was transformed with pCP20, (9), screenedfor Kan^s, and subsequently screened for the loss of pCP20, thusgenerating JM4962 (BW25113 ${Delta}$ relA). The ${Delta}$ spoT::cat deletion fromstrain CF1693 (22) was introduced into JM4962 by P1 transduction,resulting in JM4977. The deletion of spoT and relA in JM4977was confirmed by PCR and by immunoblotting using anti-SpoT andanti-RelA antibodies (generous gifts from James Hernandez).To create a repressible cgtA helper plasmid, full-length cgtAwas PCR amplified and cloned into PstI/HindIII sites of pJM4867(a lab derivative of pJN105 [38] with an expanded multiple cloningsite [S. L. Bardy and J. R. Maddock, unpublished data]). pJM4867was transformed into JM4977 to create JM4980. The ${Delta}$ cgtA::kandeletion from GN5002 (28) was introduced into JM4980 by P1 transduction,generating JM4981. The chromosomal deletion of cgtA in JM4981was confirmed by PCR. JM3867 was created by transforming MG1655with a plasmid containing cgtA under an arabinose-induciblepromoter (28).

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TABLE 1. Escherichia coli strains used in this study

For amino acid starvation and carbon starvation, polysome analysis,and (p)ppGpp analysis, cells were grown in MOPS (potassium morpholinopropanesulfonate)medium (37) supplemented with 0.1% glucose and 20 µg/mlof all 20 amino acids, except in amino acid starvation conditions,when serine was omitted. For the amino acid starvation experiment,serine hydroxamate (SH) was added to the culture at a finalconcentration of 1 mg/ml at an optical density at 600 nm (OD₆₀₀)of 0.4 to 0.5 and cells were harvested 20 min after the addition.For carbon starvation, ${alpha}$ -methylglucoside was added to a finalconcentration of 2.6% at an OD₆₀₀ of 0.4 to 0.5 and cells wereincubated for a further 2 min before harvest. For the stationary-phaseexperiment, a saturated overnight culture was diluted 1:100and cells were grown in EP medium (medium E with 0.5% glucoseand 2% peptone) (24) for 24 h before harvest. For all otherpurposes, cells were grown in Luria-Bertani (LB) broth (10 gtryptone, 5 g yeast extract, 10 g NaCl per liter) or on LB agarplates (LB broth plus 1.5% agar). MG1655 and JM3867 were grownat 37°C whereas CF1693, JM3903, JM 3907, JM4977, and JM4981were grown at 30°C. Culture growth was monitored by measuringthe absorption at 600 nm. Antibiotics were used at the followingconcentrations: 100 µg/ml ampicillin, 30 µg/ml kanamycin,and 20 µg/ml chloramphenicol.

Preparation of cell lysates for ribosome profiles, polysome fractionation, and immunoblotting. Cell lysate preparations for polysome analysis, fractionationof the lysates, and the subsequent immunoblotting were performedas previously described (25), except for the stationary-phaseexperiment in which 5 to 20% sucrose gradients [in 100 mM CH₃COONH₄,15 mM (CH₃COO)₂Mg, 20 mM Tris-HCl, pH 7.6] were used to separatethe 100S from the remainder of the ribosomal particles. Forimmunoblotting, the following antibody concentrations were used:anti-CgtA, 1:2,000; anti-SpoT (preabsorbed with acetone powdergenerated from CF1693, as described previously [10]), 1:2,000;anti-S4, 1:4,000; anti-L3, 1:4,000; goat anti-rabbit immunoglobulinG-horseradish peroxidase (Pierce), 1:20,000.

(p)ppGpp measurements. Saturated cultures grown in the presence of 2 mM phosphate (K₂HPO₄)were diluted at least 100-fold in MOPS medium containing 0.4mM phosphate. [³²P]H₃PO₄ was added to a final concentrationof 100 µCi/ml when the OD₆₀₀ reached 0.05, and incubationwas continued for a minimum of two generations before the firstsample was taken (OD₆₀₀ of 0.2 to 0.25). At time zero, SH wasadded to a final concentration of 1 mg/ml to induce amino acidstarvation. Samples were collected at indicated time points,and 100-µl samples were mixed with an equal volume of13 M formic acid and chilled on dry ice. The mixtures were thensubjected to two rounds of freezing and thawing and centrifugedat 14,000 rpm for 2 min to remove debris. Supernatants werespotted onto 20- x 20-cm polyethylenemine-cellulose plates (EMDChemicals) and separated by thin-layer chromatography in 1.5M KH₂PO₄ (pH 3.4) for $~$ 1 h. Following chromatography, labelednucleotides were visualized by autoradiography and quantifiedwith a Molecular Imager FX PhosphorImager and Quantity One software(Bio-Rad). Unlabeled ATP and GTP were spotted on the platesas markers and visualized after chromatography by UV light-inducedfluorescence. The identities of the labeled (p)ppGpp were inferredfrom their positions in the chromatograph relative to the originand GTP. (p)ppGpp levels are normalized to levels of GTP observedin the same sample.

RESULTS

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RESULTS

SpoT is ribosome associated. Intrigued by the controversial results regarding the ribosomeassociation of SpoT (15, 20, 48), we decided to reinvestigatethe localization of SpoT by using sucrose density centrifugationof ribosomal particles. Several experimental details were takeninto consideration. First, it has been demonstrated previouslythat buffer conditions, especially salt conditions, are criticalfor the detection of weakly associated proteins, such as theGTPase CgtA, on ribosomal particles separated by sucrose gradients(28, 32, 56). Different salt concentrations may influence protein-nucleicacid (e.g., rRNA) interactions and change the association patternof certain proteins. Second, the nature of the lysis procedureis critical to obtaining clear immunoblot results. Using thecommon freeze-thaw method (28, 56), significant smearing ratherthan sharp SpoT bands was often observed by immunoblotting (datanot shown). By changing the lysis method to a glass bead-basedmethod (25), we obtained much cleaner immunoblots (Fig. 1).Finally, we optimized the conditions for separating RelA andSpoT by sodium dodecyl sulfate-polyacrylamide gel electrophoresisand included control lysates ( ${Delta}$ relA ${Delta}$ spoT and ${Delta}$ relA) to verifythe specific detection of SpoT and not RelA (SpoT and RelA share31% sequence identity [35]).

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FIG. 1. SpoT associates with ribosomes in E. coli. Cell lysates from MG1655 were sedimented through 7 to 47% sucrose gradients, and the samples were monitored by UV at 254 nm. The subsequent fractions were analyzed by immunoblotting using anti-SpoT, anti-CgtA, or anti-L3, as indicated. The positions of the 30S and 50S subunits, the 70S monosome, and the polysomes are labeled. WT, MG1655 cell extract; ${Delta}$ , ${Delta}$ spoT ${Delta}$ relA cell extract; L, 1/100 of the total sample loaded onto the gradient.

Here we show that SpoT is a bona fide ribosome-associated protein(Fig. 1). SpoT was seen predominantly in the fractions migratingslightly slower than the 50S fractions. This migration patternof SpoT is similar to that of the helicases SrmB and CsdA orthe pseudouridylases RluB and RluC, which predominantly bindto a $~$ 40S particle (6, 7, 26). The trailing of SpoT into earlierfractions (Fig. 1) may result from dissociation of SpoT fromribosomes during centrifugation and suggests a somewhat weakribosome association. Very little free SpoT is found at thetop of the gradient (Fig. 1). Thus, the majority of SpoT, likeRelA, is associated with ribosomes.

We have previously shown that SpoT and the GTPase CgtA physicallyinteract and that CgtA associates with late 50S particles (56)and is required for 50S assembly (25). We show here that theribosome association of CgtA and that of SpoT overlap to a greatextent, indicating that, in vivo, significant amounts of thesetwo proteins associate with the same particles.

Ribosome association of CgtA and SpoT is mutually independent. Since CgtA and SpoT associate with pre-50S particles (Fig. 1)and these two proteins physically interact (56), one possibilityis that SpoT may be important for the association of CgtA withthe ribosome, or vice versa. To examine whether SpoT affectsthe ribosome association of CgtA, the location of CgtA was determinedin a ${Delta}$ relA ${Delta}$ spoT double mutant (Fig. 2A). The spoT gene is essentialin the relA⁺ background due to the necessity to degrade (p)ppGppthat would otherwise accumulate in the absence of SpoT (p)ppGpphydrolase activity. The spoT gene, however, is not essentialin a ${Delta}$ relA background (57). The ${Delta}$ relA ${Delta}$ spoT mutant displays a normalpolysome profile (Fig. 2A), indicating that, although SpoT appearsto bind to a pre-50S particle (Fig. 1), SpoT is not requiredfor ribosome assembly. In the ${Delta}$ relA ${Delta}$ spoT mutant, a significantamount of CgtA binds to the 50S particle, indicating that neitherSpoT nor RelA is critical for the ribosome association of CgtA(Fig. 2A). Moreover, the ${Delta}$ relA ${Delta}$ spoT mutant is a (p)ppGpp⁰ strain,lacking all detectable (p)ppGpp under any conditions (22, 57),and therefore, (p)ppGpp is also not required for CgtA to associatewith the ribosomes.

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FIG. 2. Ribosome association of SpoT and CgtA is mutually independent. (A, C, and D) Cell lysates from CF1693 ( ${Delta}$ spoT::cat ${Delta}$ relA::kan) (A), JM3867 (MG1655 plus P_BAD-cgtA) with CgtA expression induced with 0.001% arabinose (C), and JM3907 ( ${Delta}$ cgtA::kan plus P_cgtA-cgtAG80ED85N) (D) were sedimented through 7 to 47% sucrose gradients, and the subsequent fractions were subjected to immunoblotting using anti-CgtA and anti-SpoT antibodies, as indicated. The positions of the 30S and 50S subunits, the 70S monosome, and the polysomes are labeled. WT, MG1655 cell extract; ${Delta}$ , ${Delta}$ spoT ${Delta}$ relA cell extract; L, 1/100 of the total sample loaded onto the gradient. (B) Immunoblot showing the level of CgtA expression from JM3867 (MG1655 plus P_BAD-cgtA) with various levels of arabinose, as indicated.

We next addressed the question of whether CgtA is a dockingfactor for SpoT. As cgtA is an essential gene, the associationof SpoT with the ribosome cannot be directly assayed in a ${Delta}$ cgtAstrain. Two other approaches were employed to answer this question.First, cgtA was expressed, from a P_BAD promoter, to high levelsby varying the concentrations of arabinose in the medium (Fig.2B). CgtA was vastly overexpressed, even in the presence ofonly 0.001% arabinose (Fig. 2B), and overexpression of CgtAled to a considerable accumulation of free CgtA at the top ofthe gradient, as well as some CgtA migrating with translating70S and polysomes (Fig. 2C). Since CgtA and SpoT can interactdirectly, we asked whether SpoT would migrate with the freeCgtA under these conditions. We found that the ribosome associationof SpoT was similar to that seen in cells expressing nativelevels of CgtA (compare Fig. 1 and 2C) and conclude that excessfree CgtA does not sequester SpoT away from the pre-50S particle.One caveat to this conclusion is that it is possible that onlyribosome-bound CgtA is capable of interacting with SpoT.

To further examine whether SpoT requires CgtA for its ribosomeassociation, we examined the ribosome association of SpoT ina cgtA mutant strain (Fig. 2D). We previously reported thatthis cgtA mutant accumulates a pre-50S particle and concludedthat CgtA is required for late ribosome assembly (25). In thismutant, the majority of the CgtA protein is found at the topof the gradient, indicating a defect in ribosome associationof the mutant CgtA protein (Fig. 2D). SpoT, however, remainedassociated with ribosomes (Fig. 2D), although the distributionof SpoT was somewhat broader than that seen in gradients fromwild-type extracts (Fig. 1), perhaps due to the accumulationof pre-50S particles that accumulate in this mutant (25). Takentogether, we conclude that the ribosome associations of SpoTand CgtA are mutually independent.

Neither CgtA nor SpoT associates with 100S during stationary phase. We next examined the ribosome association of SpoT and CgtA instationary-phase cells, a condition known to accumulate (p)ppGpp,which might be from altered SpoT activity (30). During the transitionfrom exponential growth to the stationary phase, the 70S ribosomeis dimerized into 100S, which has no translational activity(54). This conversion is directed by a protein called ribosomemodulation factor, whose transcription is dependent on (p)ppGpp(24), the level of which increases as cells enter stationaryphase (30). To assay CgtA and SpoT ribosome association in thepresence of increased (p)ppGpp levels, stationary-phase wild-typecell lysates were fractionated by sucrose gradients and theribosome associations of SpoT and CgtA were examined by immunoblotting.Neither SpoT nor CgtA displayed an association with the 100Sribosomal particles (Fig. 3), consistent with the near absenceof these two proteins on the 70S (Fig. 3) from which the 100Sis derived. Interestingly, however, a partial loss of both proteinsfrom the ribosome is seen and a significant amount of both proteinsis found in the lightest fractions (Fig. 3). The physiologicalbasis for this change in location is unknown.

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FIG. 3. Neither CgtA nor SpoT associates with the 100S ribosomal particle that accumulates in stationary phase. Overnight-grown E. coli MG1655 cells were diluted 1:100, grown in EP medium for 24 h, lysed, and fractionated on sucrose gradients. The ribosome profile is shown with the positions of the 30S, 50S, 70S, and 100S particles indicated. Fractions were analyzed by immunoblotting with anti-SpoT, anti-CgtA, or anti-S4, as indicated. WT, MG1655 cell extract; ${Delta}$ , ${Delta}$ spoT ${Delta}$ relA cell extract; L, 1/100 of the total sample loaded onto the gradients.

CgtA is not bound to the pre-50S particle during amino acid starvation. To further examine whether ribosome association influences thefunctions of CgtA and SpoT, their ribosome associations wereexamined under two conditions in which SpoT function is alteredand (p)ppGpp rapidly accumulates. When cells are treated withSH, an inhibitor of seryl-tRNA synthetase, amino acid starvationis induced (49). RelA is quickly activated by uncharged tRNAat the ribosome A site (19), and at the same time, SpoT (p)ppGpphydrolase activity is inhibited (36), leading to the swift accumulationof high levels of (p)ppGpp. When the cells are grown in MOPSminimal medium, the ribosome association of the two proteins(Fig. 4A) is similar to that seen in LB medium (Fig. 1), indicatingthat the richness of the growth medium does not significantlyaffect the ribosome localization of either CgtA or SpoT. Whencells are treated with SH, however, there is a dramatic alterationof the association pattern of CgtA and, to a lesser degree,SpoT (Fig. 4B). The majority of the CgtA is found at the topof the gradient, and very little CgtA is detected associatedwith the 50S particle. The ribosome association of SpoT alsochanged, albeit not as dramatically as that of CgtA. Under theseconditions, approximately half of the SpoT is associated withthe pre-50S particles. In addition, a significant amount ofSpoT migrates in fractions below the 30S subunit but not atthe very top of the gradient, indicating that this SpoT is ina smaller complex. Although we do not know the nature of thecomplex, it does not appear to contain CgtA, as CgtA is predominantlyfound in the very early fractions.

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FIG. 4. Ribosome association of CgtA and SpoT under amino acid and carbon starvation conditions. Cell lysates from E. coli MG1655 cells grown in MOPS minimal medium (A), MOPS medium treated with SH (1 mg/ml) for 20 min before harvest (B), and MOPS medium treated with ${alpha}$ -methylglucoside (2.6%) for 2 min before harvest (C) were fractionated over 7 to 47% sucrose gradients. The subsequent fractions were analyzed by immunoblotting with anti-SpoT or anti-CgtA (1/2,000), as indicated. The positions of the 30S, 50S, and 70S particles and the polysomes are labeled. WT, MG1655 cell extract; ${Delta}$ , ${Delta}$ spoT ${Delta}$ relA cell extract; L, 1/100 of the total sample loaded onto the gradients.

(p)ppGpp levels also increase when cells are starved for carbon.In this case, the accumulation of (p)ppGpp is not as dramaticas that during amino acid starvation (36) and is believed tomainly result from the inhibition of the (p)ppGpp hydrolysisfunction of SpoT but not from the activation of its synthesisactivity (16, 36). We induced carbon starvation by the additionof ${alpha}$ -methylglucoside, an inhibitor of glucose uptake, and harvestedthe cells at the time point when ppGpp is known to accumulatethe most (18). Under these conditions, we observed a modestalteration in the ribosome association of both CgtA and SpoT,consistent with a less dramatic response (Fig. 4C).

The steady-state level of (p)ppGpp is increased in a cgtA mutant. SpoT and CgtA interact (56), but the functional significanceof this interaction is unknown. Because CgtA is not associatedwith ribosomes under amino acid starvation, a condition in whichthe hydrolysis of SpoT is inhibited, we predicted that CgtAmight, on the assembling 50S particle, promote (p)ppGpp hydrolysisby SpoT. If true, then the steady-state levels of (p)ppGpp shouldbe elevated in the absence of CgtA. To determine whether thisis the case, we directly assayed the (p)ppGpp levels in a cgtAmutant and its isogenic wild-type strain under steady-stateand amino acid starvation conditions (Fig. 5). Under normalgrowth conditions, the cellular (p)ppGpp level is relativelylow in the wild-type strain but increases promptly upon SH treatment(Fig. 5A, lanes 1 and 2). In the cgtA mutant, however, thereis a noticeable increase in the steady-state level of (p)ppGppcompared to that of the isogenic control (Fig. 5A, lane 3 versuslane 1). Moreover, the spots that represent PP_i [the hydrolysisproduct of (p)ppGpp] are greatly reduced in the mutant (Fig.5A). Upon amino acid starvation, a quick accumulation of (p)ppGppalso occurs in the mutant, the level of which is comparableto that seen in the wild type (Fig. 5A, lanes 2 and 4). Thesedata indicate that although the steady-state levels of (p)ppGpprequire functional CgtA, the rapid accumulation of (p)ppGppduring amino acid starvation does not. We verified that thiswas the case by quantifying the accumulation of (p)ppGpp levelsin a time course study and showed that (i) the steady-statelevel of (p)ppGpp is consistently two- to threefold higher inthe cgtA mutant and (ii) the accumulation of (p)ppGpp duringamino acid starvation does not differ between the wild typeand the mutant strains (Fig. 5B). Thus, CgtA is important formaintaining the steady-state levels of (p)ppGpp but not foraccumulation of (p)ppGpp during the stringent response.

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FIG. 5. (p)ppGpp steady-state level is increased in a cgtA mutant. (A) JM3903 ( ${Delta}$ cgtA::kan plus P_cgtA-cgtA) and JM3907 ( ${Delta}$ cgtA::kan plus P_cgtA-cgtAG80ED85N) cells were grown at 30°C in low-phosphate medium and uniformly ³²P_i labeled (100 µCi/ml) before being treated with SH (1 mg/ml). Samples were taken immediately before the addition and at 10-min intervals thereafter, as indicated. The formic acid-extracted nucleotides were resolved by one-dimensional thin-layer chromatography on polyethyleneimine-cellulose sheets, autoradiographed, and quantified with a phosphorimager. Unlabeled ATP and GTP were spotted on the plates as markers. (A) Autoradiograms of polyethyleneimine thin-layer chromatography plates with or without SH treatment (20-min time point). Lanes 1 and 2 are JM3903 without and with SH, respectively; lanes 3 and 4 are JM3907 without and with SH, respectively. (B) (p)ppGpp levels normalized according to the GTP levels. Open and closed symbols are nontreated and SH-treated JM3903 (triangles) and JM3907 (squares) samples, respectively. Error bars are standard deviations from triplicate experiments.

cgtA is an essential gene in a relA spoT mutant background. spoT is an essential gene because it is required to hydrolyze(p)ppGpp that would otherwise accumulate in its absence. Sincewe propose that CgtA is involved in promoting the (p)ppGpp hydrolysisof SpoT, one possibility is that the essential nature of CgtAis through its control of SpoT. If true, a relA spoT cgtA triplemutant would be viable. To test this, we generated a ${Delta}$ relA ${Delta}$ spoT::catcgtA::kan triple mutant harboring a plasmid expressing cgtAfrom the inducible/repressible P_BAD promoter (P_BAD-cgtA). Growthof cgtA::kan mutants is complemented by the P_BAD-cgtA plasmidin the presence of arabinose, but cells grow very slowly onplates without arabinose (Fig. 6). The slow growth is likelydue to the leaky expression from this promoter in the absenceof arabinose. A ${Delta}$ relA ${Delta}$ spoT::cat mutant grows well independentlyof arabinose. In contrast, the ${Delta}$ relA ${Delta}$ spoT::cat cgtA::kan triplemutant harboring P_BAD-cgtA grows very slowly on plates withoutarabinose, comparably to the cgtA::kan mutant plus P_BAD-cgtA(Fig. 6). We conclude that, in E. coli, cgtA is essential evenin the absence of spoT and relA.

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FIG. 6. A cgtA relA spoT triple mutant is not viable. GN5002 ( ${Delta}$ cgtA::kan plus P_BAD-cgtA), JM4977 ( ${Delta}$ relA ${Delta}$ spoT::cat), and JM4981 ( ${Delta}$ relA ${Delta}$ spoT::cat cgtA::kan plus P_BAD-cgtA) were streaked on LB plates containing chloramphenicol (Cm) with or without 0.1% arabinose (Ara) at 30°C, as indicated.

DISCUSSION

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DISCUSSION

We demonstrate that SpoT is associated with the pre-50S ribosomalparticle (Fig. 1). This observation is entirely consistent withearlier studies that showed that the (p)ppGpp hydrolase activityof SpoT cofractionates with ribosome and is inhibited by unchargedtRNA (20, 42, 48). Moreover, we had previously shown that SpoTcopurified with the pre-50S-associated protein, CgtA (56), alsosuggesting that SpoT is ribosome associated. It is likely thatprevious attempts to detect a direct association of SpoT withribosomes failed due to less-than-optimal conditions used (15),a problem that was also seen for the CgtA protein (28).

SpoT migrates on sucrose gradients over a number of pre-50Sfractions, peaking at a $~$ 40S position. A similar migration profileis seen with other pre-50S-associated proteins such as the pseudouridinesynthetases RluB and RluC (26) and the helicases CsdA (6) andSrmB (7). SpoT also copurified with these proteins in a large-scaleaffinity purification project (4), further supporting that theseproteins are on the same pre-50S intermediate particles.

In contrast to exponentially growing cells in which a significantamount of CgtA associates with a pre-50S particle, during aminoacid starvation, CgtA is not associated with ribosomes. We envisiontwo possible mechanisms by which amino acid starvation couldresult in a loss of CgtA from the pre-50S particle: either (i)free CgtA does not bind to the ribosomal particles under theseconditions or (ii) ribosome-bound CgtA dissociates from theribosome. We suggest that both of these mechanisms may be responsiblefor the change in ribosome association of CgtA during aminoacid starvation. First, CgtA is involved in late ribosome assemblyand is not significantly associated with translating ribosomes(25) and therefore dissociates from the 50S prior to generationof the 70S particle. Thus, CgtA is normally cycling on and offof the ribosomal particle. Since CgtA proteins have modest affinityfor guanine nucleotides and rapid guanine nucleotide exchangerates (31, 56), it was proposed that their guanine nucleotideoccupancy would be determined by the relative levels of GTP/GDPin the cell (31, 39). In vitro, the GTP-bound CgtA but not theGDP-bound form has a higher affinity for ribosomes (25) andrRNA (43). During amino acid starvation there is a 40% dropin the GTP pool (14). Thus, under these conditions, the cellularbalance of GTP/GDP is altered and may result in more free GDP-boundCgtA. Second, CgtA may be lost from ribosomes due to the accumulationof (p)ppGpp. The B. subtilis Obg protein was crystallized asan asymmetric unit with one monomer in its apo state and theother bound to ppGpp (3). In vitro, low levels of ppGpp acceleratethe hydrolysis of GTP by the B. subtilis Obg (3). Thus, theincrease in (p)ppGpp that accompanies amino acid starvationmay also result in an increase in GTP hydrolysis and thereforean increase in GDP-bound CgtA. Alternatively, it could be that(p)ppGpp-bound CgtA is not ribosome associated independentlyof GTP hydrolysis.

We demonstrate that CgtA is required for maintaining the properlevel of (p)ppGpp in the cell. In the cgtA mutant, the steady-statelevels of (p)ppGpp are elevated by three- to fourfold (Fig.5). The steady-state level of (p)ppGpp in exponentially growingcells depends on the balance of SpoT-dependent (p)ppGpp synthesisand (p)ppGpp hydrolysis (5). An increase in the levels of (p)ppGpp,therefore, could be due to an increase in the (p)ppGpp synthesisor a decrease in the (p)ppGpp hydrolysis rates of SpoT. Thus,there are two mechanisms by which CgtA could control SpoT function,either by promoting (p)ppGpp hydrolysis or by inhibiting (p)ppGppsynthesis. CgtA is not, however, required for the high levelsof (p)ppGpp that accumulate during amino acid starvation (Fig.5B). During amino acid starvation, the accumulation of (p)ppGppis regulated predominantly by the level of (p)ppGpp degradation(36). Moreover, the rate of (p)ppGpp degradation abruptly decreases,indicating that the mechanism for controlling degradation worksrelatively rapidly (36). Consistently, a decrease in (p)ppGpphydrolysis seen during amino acid starvation is independentof protein synthesis (36), indicating that neither the translatingribosome nor the newly synthesized protein is involved in controllingSpoT hydrolase activity. We show that during amino acid starvation,CgtA does not colocalize with SpoT and, therefore, under theseconditions is not involved in controlling SpoT. We suggest thatit is the loss of CgtA from the assembling pre-50S particle(and, therefore, also a lack of interaction between SpoT andCgtA) that is responsible for the rapid inhibition of SpoT (p)ppGpphydrolysis.

It is of interest that the pre-50S intermediates to which CgtAand SpoT predominantly bind are not identical. There are, however,a subset of intermediates to which both proteins bind, indicatedby their overlapping migration on sucrose gradients. Their colocalizationwas also confirmed by the copurification of both CsdA and SpoTwith affinity-purified CgtA (56). A long-standing question hasbeen how the cells maintain two populations of SpoT protein,those that synthesize (p)ppGpp and those that degrade (p)ppGpp.According to the structural analysis, SpoT/RelA protein existsin either a (p)ppGpp-hydrolase-OFF/(p)ppGpp-synthetase-ON ora hydrolase-ON/synthetase-OFF state (23). One possibility isthat the different active states of SpoT may reflect whetherSpoT is on the same assembling 50S particles as CgtA or not.If that is true, we predict that the form of SpoT on the 40Sparticles would be that of a (p)ppGpp synthetase and the formon particles with CgtA would be a (p)ppGpp hydrolase. In thismanner, CgtA would control only a subset of SpoT proteins inthe cell at any given time.

While CgtA is required for late assembly of the 50S subunit(25, 43), SpoT does not seem to play a role in the assemblyprocess as judged by the normal polysome profile of the relAspoT double mutant (Fig. 2A). We have recently identified anumber of additional ribosome-associated proteins that, likeSpoT, are also not critical for ribosome assembly (26). Onepossibility is that association with the maturing ribosomalparticle allows for coupling ribosome assembly with the proteinactivity. Doing so would allow for a coordination between criticalcellular functions with ribosome assembly, as previously proposed(52).

We have shown that CgtA has two distinct cellular functionsand is required for the last stages of 50S assembly (25) andin the control of SpoT (this study). We predicted that the essentialnature of cgtA would not be due to its role in ribosome assembly,as the majority of the assembly factors are not essential. Weshow here, however, that cgtA is essential in mutants also lackingspoT and relA. Thus, the essential function of the E. coli CgtAprotein remains unknown.

A role for CgtA in controlling cellular (p)ppGpp levels mayexplain some of the many pleiotropic phenotypes that have beenassigned to CgtA. We suggest that at least some of the cgtAmutant phenotypes are due to indirect consequences of altering(p)ppGpp levels. For instance, it was recently reported thatCgtA promotes replication fork stability (13). These studiesfocused on two types of cgtA mutations, CgtAP168V and a Tn insertionthat resulted in loss of the C-terminal 9 amino acids and additionof 68 amino acids (13). We have shown that the Caulobacter crescentusCgtAP168V mutant protein does not have a defect in GTP hydrolysisbut does have a reduced affinity for GDP and therefore, in vivo,may be predominantly bound to GTP (11). If that is also truein E. coli, the GTP-bound CgtAP168V may result in increased(p)ppGpp hydrolysis by SpoT and, therefore, result in lowerlevels of (p)ppGpp in the cells. A role for (p)ppGpp levelsin controlling replication fork progression has been previouslyreported (34, 50). It has also been proposed by several groupsthat CgtA controls the initiation of replication initiation(12, 13, 51). The initiation of DNA replication, however, isunder stringent control (45, 59), and therefore, the role ofCgtA may be indirect. Support for this premise comes from arecent report showing that the growth of the cgtAG80ED85N mutantwas partially suppressed by ectopic expression of dnaA (47).Clearly a reinvestigation of the phenotypes associated withcgtA mutants in the context of (p)ppGpp levels is warranted.

Since the submission of the manuscript, Raskin, Judson, andMekalanos (41) have published a very nice paper verifying, inVibrio cholerae, many of the findings that we report here forE. coli. Taking a very different approach, they posit that CgtAis involved in control of SpoT and show that depletion of V.cholerae CgtA results in an increase in ppGpp levels. In contrastto our findings in E. coli, however, they show that in V. choleraeCgtA is not essential in the absence of RelA. Clearly, furtherstudies are necessary to sort out the differences in the essentialnature of this conserved GTPase.

ACKNOWLEDGMENTS

We are grateful to James Hernandez for his ongoing support inproviding strains, antibodies, and advice. We also thank DanielSmith for technical assistance.

This work was supported, in part, by NSF grant MCB-0316357.

FOOTNOTES

* Corresponding author. Mailing address: Department of Molecular, Cellular and Developmental Biology, University of Michigan, 830 North University, Ann Arbor, MI 48109-1048. Phone: (734) 936-8068. Fax: (734) 647-0884. E-mail: maddock{at}umich.edu

Published ahead of print on 6 July 2007.

Present address: Biological Sciences, 337 Campus Drive, StanfordUniversity, Stanford, CA 94305.

REFERENCES

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