Phosphotransfer Reactions of the CbbRRS Three-Protein Two- Component System from Rhodopseudomonas palustris CGA010 Appear To Be Controlled by an Internal Molecular Switch on the Sensor Kinase

The CbbRRS system is an atypical three-protein two-componentsystem that modulates the expression of the cbb_I CO₂ fixationoperon of Rhodopseudomonas palustris, possibly in response toa redox signal. It consists of a membrane-bound hybrid sensorkinase, CbbSR, with a transmitter and receiver domain, and tworesponse regulator proteins, CbbRR1 and CbbRR2. No detectablehelix-turn-helix DNA binding domain is associated with eitherresponse regulator, but an HPt domain and a second receiverdomain are predicted at the C-terminal region of CbbRR1 andCbbRR2, respectively. The abundance of conserved residues predictedto participate in a His-Asp phosphorelay raised the questionof their de facto involvement. In this study, the role of themultiple receiver domains was elucidated in vitro by generatingsite-directed mutants of the putative conserved residues. Distinctphosphorylation patterns were obtained with two truncated versionsof the hybrid sensor kinase, CbbSR^T189 and CbbSR^R96 (CbbSR beginningat residues T189 and R96, respectively). These constructs alsoexhibited substantially different affinities for ATP and phosphorylationstability, which was found to be dependent on a conserved Aspresidue (Asp-696) within the kinase receiver domain. Asp-696also played an important role in defining the specificity ofphosphorylation for response regulators CbbRR1 or CbbRR2, andthis residue appeared to act in conjunction with residues withinthe region from Arg-96 to Thr-189 at the N terminus of the sensorkinase. The net effect of concerted interactions at these distinctregions of CbbSR created an internal molecular switch that appearsto coordinate a unique branched phosphorelay system.

INTRODUCTION

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Introduction

Two-component signal transduction systems regulate the expressionof genes important for a myriad of physiological processes commonto prokaryotes (8); such systems have also been recently identifiedto function in eukaryotes as well (5, 9, 13). In its most simpleiteration, two-component systems consist of a membrane-boundsensor histidine kinase protein that receives an environmentalcue and then transfers the signal to a single soluble responseregulator protein. The sensor histidine kinase protein has anonconserved N-terminal region, dedicated to sensing a particularsignal, attached to a conserved kinase domain. The responseregulator protein typically consists of a conserved receiverdomain and a variable effector domain. The general mechanismof signal transduction involves a linear pattern of events wherebyautophosphorylation of the kinase precedes phosphorylation ofthe cognate response regulator protein, ultimately leading toa change in behavior determined by the nature of the effectordomain. Thus, one important manifestation is the regulationof gene expression; alternatively, the signal transduction processmight lead to modification of protein-protein interactions orthe modulation of enzymatic activity (13). Numerous variationsof the basic modular units have been described over the years;e.g., where the kinase core might stand alone as a sensor protein(2). Alternatively, the kinase domain may be associated withone or more receiver domains on the same protein to form a hybridsensor kinase molecule (3, 10, 14). In the latter instance,an HPt domain is often interposed to facilitate phosphotransferreactions between separate receiver domains. By contrast, receiverdomains and HPt domains, where required, may be localized oncompletely separate proteins (2, 7, 9).

The CbbRRS (Calvin Benson Bassham response regulators sensorkinase) of Rhodopseudomonas palustris is a three-protein two-componentsystem (11) consisting of a membrane-bound sensor kinase protein(CbbSR) and two response regulator proteins (CbbRR1 and CbbRR2)(Fig. 1). CbbSR is a large hybrid sensor kinase protein that,in addition to possessing two canonical transmembrane regionsand a transmitter domain, also contains a C-terminal receiverdomain. Two potential PAS motifs, predicted by PFAM analysis(http://www.ncbi.nlm.nih.gov/BLAST), are present in the N-terminalregion (Fig. 1B). Response regulator 1, CbbRR1, has an HPt domainand a receiver domain. Response regulator 2, CbbRR2, has tworeceiver domains (Fig. 1B). Besides this modular organization,common among two-component signal transduction pathways, thecomponents of the CbbRRS system have no homology to other knownproteins (11). Collectively, the CbbRRS system was recentlyshown to regulate expression of the form I ribulose 1,5-bisphosphatecarboxylase/oxygenase or cbbLS genes (Fig. 1A) of the cbb_I operonof R. palustris (11). As the two response regulators, CbbRR1and CbbRR2, presumably do not interact with DNA directly, dueto the absence of a discernible helix-turn-helix motif, it wasproposed that the response regulators posttranslationally modulatethe CbbR transcription factor (encoded by the cbbR gene) (Fig.1A), which is itself indispensable for the expression of thecbbLS genes (11). In a previous investigation, it was also shownthat the full-length membrane-bound kinase, CbbSR, catalyzesphosphorylation of both response regulators (CbbRR1 and CbbRR2)independently, ruling out any absolute requirement for a multistepphosphorelay between the kinase and the two response regulatorproteins. Clearly, a single sensor kinase has the potentialto interact with four distinct receiver domains on three differentproteins, including two different response regulator proteins.The four different receiver domains show limited amino acididentity (Fig. 2), and yet this system plays an important rolewith regard to the control of cbbLS transcription in R. palustris(11). To better understand what appears to be a complex signaltransduction mechanism for modulating expression of genes requiredfor CO₂ assimilation under changing environmental conditions,we dissected the phosphorelay reactions in vitro and determinedthe role of each of the distinct functional domains of the threeproteins. The likely route of the phosphoryl group followingautophosphorylation of the histidine residue (His-409) on thesensor kinase was traced; also the roles of specific residuesimportant for phosphotransfer within the receiver domain ofthe hybrid sensor kinase and each of the two response regulatorproteins were determined. As a result of these studies, a potentialinternal molecular switch was identified within the sensor kinasethat appeared to direct the route and specificity of phosphotransferto the response regulator proteins.

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FIG. 1. Gene organization (A) and potential protein domains (B) found on the CbbRRS system proteins CbbSR, CbbRR1, and CbbRR2. The predicted conserved residues involved in phosphotransfer reactions are indicated. A schematic representation of the two truncated sensor kinase proteins (CbbSR^T189 and CbbSR^R96) is also shown.

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FIG. 2. Sequence alignment of the receiver domains present on proteins of the CbbRRS system (11). SR-REC, sensor kinase CbbSR; RR2-REC A, first receiver domain of response regulator CbbRR2; RR2-REC B, second receiver domain of response regulator CbbRR2; RR1-REC, receiver domain of response regulator CbbRR1. The asterisk indicates the conserved phosphorylation site. Conserved residues are shown in green, and identical residues are shown in yellow, whereas similar residues are shown in cyan.

MATERIALS AND METHODS

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Materials and Methods

Strains, growth conditions, and plasmids. Strains and plasmids used in this study are reported in Table1. Escherichia coli DH5 ${alpha}$ was used for general cloning purposesas well as production of recombinant proteins. Cultures weregrown at 37°C with constant shaking (200 rpm) in Luria-Bertanibroth. Antibiotics were added at the following final concentrations:kanamycin, 50 µg ml^–1; ampicillin, 100 µgml^–1. Standard molecular biology techniques were usedfor chromosomal DNA purification, restriction digests, and cloning(1). A QIAGEN Mini Prep kit was routinely employed to prepareplasmid DNA. When necessary, DNA fragments were purified fromagarose gels using the Gel Purification Kit from QIAGEN. PlasmidspQE8027, pQE8024, pQE8740, pQE8797, and pQE8798 have been describedelsewhere (11). The coding region corresponding to the predictedwhole-cytoplasmic portion of sensor kinase CbbSR was PCR amplifiedby using the primers 5'-GGGGTACCCGGCGCAACGCGCACAAG-3' and 5'-CCCAAGCTTTCAGGTCAGCTCGTG-3'(restriction sites are underlined), in the presence of 1 U ofPfx Platinum DNA polymerase (Invitrogen), and directly clonedinto pCR-Blunt II TOPO to generate plasmid pSR128. After sequencingensured the absence of mutations, a KpnI/BamHI fragment of approximately950 bp was ligated in frame into vector pQE8740 (11) by exploitinga unique BamHI site within the cbbSR gene to generate plasmidpQE12840 (CbbSR^R96, indicating CbbSR starting from residue R96).

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TABLE 1. Strain and plasmids used in this study

Construction of site-directed mutants. Mutagenic PCR was performed to generate site-directed mutantsof the sensor kinase and two response regulators. One specificresidue was substituted at a time, using conditions recommendedby the manufacturer (Quick Change site-directed mutagenic kit;Stratagene). All substitutions were verified after sequencingthe mutagenic PCR products at the Plant-Microbe Genomic Facilityat The Ohio State University before the products were subclonedinto the pQE80 expression vector at appropriate restrictionsites. Double site-directed mutants were generated by performingmutagenic PCRs on templates previously mutagenized. In particular,plasmids pQE8055 (D54NCbbRR1) and pQE8057 (H171DCbbRR1) weregenerated using the following mutagenic primer pairs (mutatedcodons are underlined): the pair 5'-CTGATCCTTAGCAACGTTTCGATGCCG-3'and 5'-CGGCATCGAAACGTTGCTAAGG ATCAG-3' (D54N) and the pair 5'-CGCCATGTGGCTGACAAGCTGGTCGGC-3'and 5'-GCCGACCAGCTTGTCAGCCACATGGCG-3' (H171D), respectively.The expression vector pQE8073 was used for the isolation ofthe recombinant CbbRR1 double mutant protein D54NH171DCbbRR1.Plasmids pQE8060 (D54NCbbRR2) and pQE8061 (D195NCbbRR2) weregenerated by using the following mutagenic primer pairs (mutatedcodons are underlined): the pair 5'-CTGATCATCGTCAACATCAACATGCCG-3'and 5'-CGGCATGTTGATGTTGACGATG ATCAG-3' (D54N) and the pair 5'-GTGGTGGTCACCAACTATCACATGCCG-3'and 5'-CGGCATGTGATAGTTGGTGACCACCAC-3' (D195N). The expressionvector pQE8075 was used for the isolation of the CbbRR2 doublemutant protein (D54ND195NCbbRR2). Plasmid pQE12897 (D696NCbbSR^R96)and pQE12898 (H409NCbbSR^R96) were derived from in-frame ligationof the KpnI/BamHI fragment from pSR128 into plasmids pQE8797and pQE8798, respectively (11), as described above for the constructionof pQE12840.

Purification of recombinant proteins. N-terminal His₆-tagged recombinant proteins, hereafter simplyreferred to as CbbSR, CbbRR1, and CbbRR2, were synthesized inE. coli and purified by nickel column chromatography as previouslydescribed (11).

Phosphorylation reactions. Phosphorylation reactions were performed in 50 mM Tris-Cl, pH8.0, 5 mM MgCl₂, 50 mM KCl, and 0.1 mM dithiothreitol. The finalconcentration of [ ${gamma}$ -³²P]ATP (specific activity of 10 mCi/mmol;1.7 µM stock solution) (Perkin Elmer) varied dependingon the type of reaction being examined and is specified in thefigure legends. The phosphorylation reactions were carried outat room temperature for the desired time and were terminatedby adding 3x sample buffer (37.5 mM Tris-Cl, pH 6.8, 30% glycerol,10% sodium dodecyl sulfate [SDS; wt/vol], 0.6% ß-mercaptoethanol).The reaction products were separated by electrophoresis on 8%or 12% SDS-polyacrylamide gel electrophoresis (PAGE) gels (17by 16.5 by 0.3 cm) and were run at 4°C at 200 V constantvoltage for 2 h. Gels were dried, exposed to a high-resolutionphosphor screen (Kodak), and analyzed using a PhosphorImagerwith ImageQuant software (Molecular Dynamics 5.0; Amersham Biosciences,Pittsburgh, PA). For the label decay experiments, an excessof nonradioactive ATP (100 mM) was added to the reaction mixturefollowing a 20-min preincubation with [ ${gamma}$ -³²P]ATP. Aliquots weretaken prior to the addition of unlabeled ATP (time zero) andat various time points after the addition of cold ATP. Differentdilutions of [ ${gamma}$ -³²P]ATP were used to generate, via ImageQuant,a calibration curve to quantify the label associated with theproducts of the phosphorylation reactions. All time-dependentquantitation results were expressed as the average of at leastthree independent experiments. The gel figures shown are representativeof each set of experiments.

RESULTS

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Results

Phosphotransfer activities of the truncated wild-type sensor kinase. Comparisons of deduced amino acid sequences of CbbRR1, CbbRR2,and sensor kinase CbbSR to well-characterized bacterial responseregulators (data not shown) resulted in the identification ofresidues Asp-54 and His-171 on CbbRR1 and Asp-54 and Asp-195on CbbRR2 as potential specific sites of phosphorylation. Theimportance and role of these residues on each response regulatorprotein during phosphotransfer, along with the conserved functionalresidues identified on the sensor kinase (11), were assessedafter purified site-directed mutant proteins were prepared.Truncated soluble His-tagged recombinant sensor kinase constructsCbbSR^R96 and CbbSR^T189 (CbbSR starting from residue T189) wereprepared and purified using constructs that provided the cytoplasmic(but not membrane-spanning) portion of the protein (Fig. 1).As expected, CbbSR^R96 catalyzed an ATP-dependent autophosphorylationreaction, followed by subsequent phosphotransfer to wild-typeCbbRR1 (11) (Fig. 3A). Alteration of both Asp-54 and His-171of CbbRR1 prevented label incorporation/phosphorylation of CbbRR1(Fig. 3A). By contrast, considerable phosphotransfer to theH171DCbbRR1 mutant protein occurred, while the D54N constructexhibited only weak phosphorylation. These results showed thatAsp-54 is the major phosphoacceptor of CbbRR1; however, thedata also suggested possible phosphotransfer between residuesAsp-696 from CbbSR to His-171 of CbbRR1 (further described below).No phosphorylation of either wild-type or site-directed mutantconstructs of CbbRR2 by CbbSR^R96 was observed (Fig. 3B).

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FIG. 3. Phosphotransfer between sensor kinase CbbSR^R96 and response regulator CbbRR1 (wild-type and wild-type plus D54N, H171D, and D54NH171D mutant CbbRR1 proteins) (A) and response regulator CbbRR2 (wild-type and wild-type plus D54N, D195N, and D54ND195N mutant CbbRR2) (B). A total of 380 pmol of sensor kinase was preincubated with 20 µM [ ${gamma}$ -³²P]ATP for 20 min (far left lanes) before the addition of approximately 1 nmol of each response regulator, and the reaction mixture was incubated at room temperature for 1 h.

To further define phosphotransfer from the sensor kinase toCbbRR1, both the kinetics and specificity of these reactionswere examined. Time course experiments indicated that CbbSR^R96catalyzed rapid transfer of ${gamma}$ -³²P to CbbRR1 (Fig. 4A and B).Similarly, phosphotransfer from CbbSR^R96 to the mutant H171DCbbRR1protein occurred, however at a reduced initial rate (Fig. 4C and D).Both the wild-type and mutant CbbRR1 proteins reached a consistentlevel of phosphorylation in equilibrium with the sensor kinase.Since unincorporated [ ${gamma}$ -³²P]ATP was not removed from the reactionmixture, no significant dephosphorylation of the kinase proteinwas observed concomitant with the phosphorylation of CbbRR1.Analogous results were obtained with the shorter truncated kinase,CbbSR^T189 (data not shown).

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FIG. 4. Time course of phosphorylation between CbbSR^R96 and CbbRR1 (A and B) or H171DCbbRR1 (C and D). The concentration of phosphorylated products obtained at various times was determined (A and C) for CbbSR^R96 ( ${blacktriangleup}$ ), CbbRR1 ( ${blacksquare}$ ), and H171DCbbRR1 ( ${square}$ ). A total of 380 pmol of sensor kinase was preincubated with 20 µM [ ${gamma}$ -³²P]ATP for 20 min (time zero) before the addition of approximately 1 nmol of response regulator. Ten-milliliter aliquots were then removed at the time points indicated; the reactions were stopped by adding 3x SDS loading buffer and stored on ice until the end of the experiment.

Considerable differences in both the kinetics and specificityof phosphotransfer to the CbbRR1 constructs were observed withthe kinase mutant D696NCbbSR^R96 (Fig. 5A and B) and its moretruncated homolog D696NCbbSR^T189 (Fig. 5C and D). Wild-typeCbbRR1 was very poorly phosphorylated in the presence of D696NCbbSR^R96(Fig. 5A) and virtually no phosphotransfer occurred to H171DCbbRR1(Fig. 5B). Variations of the protein molar ratios over a widerange of ATP concentration and incubation times gave identicalpatterns of phosphorylation (data not shown). By contrast, themore truncated D696NCbbSR^T189 protein exhibited activities consistentwith the nonmutant CbbSR^T189 construct, with rapid phosphorylationof CbbRR1 (Fig. 5C). Phosphotransfer to H171DCbbRR1 occurredboth at a slower rate and to a lesser extent (Fig. 5D), withaccentuated transient dephosphorylation of CbbSR and slightlydecreased phosphotransfer efficiency, much like wild-type CbbSR^R96and H171DCbbRR1 (Fig. 4C and D). Incubation of the mutant kinasepreparations, D696NCbbSR with D54NCbbRR1, prevented any phosphotransfer(data not shown).

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FIG. 5. Time course of phosphorylation of CbbRR1 ( ${blacksquare}$ ) and H171DCbbRR1 ( ${square}$ ) catalyzed by D696NCbbSR^R96 ( ${triangleup}$ ) (A and B) and D696NCbbSR^T189 ( ${circ}$ ) (C and D). Reaction conditions were as described in the legend of Fig. 4. Quantitation of phosphorylated products from time courses (left) was obtained from phosphotransfer reactions depicted in gels (right). The arrow indicates where CbbRR1 preparations were added to the reaction mixture.

Properties of the truncated sensor kinase proteins. The basic autophosphorylation reactions catalyzed by all fourtruncated constructs—CbbSR^T189, D696NCbbSR^T189, CbbSR^R96,and D696NCbbSR^R96—were characterized. The D696NCbbSR^R96construct had a much higher affinity for ATP than the otherconstructs (Fig. 6A), with this protein showing optimal phosphorylationat concentrations as low as 2.5 nM ATP (Fig. 6B, F, and G) comparedto CbbSR^T189, D696NCbbSR^T189, and CbbSR^R96 (Fig. 6A, C, D, and E),all of which required at least 20 µM ATP. In addition,there was no difference in the relative rate of autophosphorylationof CbbSR^R96 and D696N CbbSR^R96 at 20 µM and 25 nM [ ${gamma}$ -³²P]ATP,respectively (data not shown). No significant differences inATP affinity were noted for the CbbSR^T189 wild-type and mutantconstructs (11).

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FIG. 6. Kinase autophosphorylation reactions at various concentrations of [ ${gamma}$ -³²P]ATP. Each reaction was carried out with 380 pmol of protein at various concentration of [ ${gamma}$ -³²P]ATP for 20 min at room temperature in a final volume of 10 µl. The reactions were terminated by adding 5 µl of 3x sample buffer. (A) Levels of phosphorylated proteins obtained at increasing concentrations of [ ${gamma}$ -³²P]ATP for CbbSR^T189 (•), D696NCbbSR^T189 ( ${circ}$ ), CbbSR^R96 ( ${blacktriangleup}$ ), and D696NCbbSR^R96 ( ${triangleup}$ ). (B) Levels of phosphorylated products obtained at increasing concentrations of [ ${gamma}$ -³²P]ATP for D696NCbbSR^R96. Representative patterns of autophosphorylation at the various concentrations of [ ${gamma}$ -³²P]ATP of CbbSR^T189 (C), D696NCbbSR^T189 (D), CbbSR^R96 (E), and D696NCbbSR^R96 (F and G) at the indicated concentrations of ATP. The range of [ ${gamma}$ -³²P]ATP concentrations (µM or nM) used in the autophosphorylation assays is reported above each gel.

Previous studies on the chemical stability of phosphorylatedCbbSR^T189 constructs indicated that the wild-type sensor kinaseprotein was mainly acyl-phosphorylated on Asp-696, with rapidphosphotransfer from the autophosphorylated His-409 residueto Asp-696 within the receiver domain of the protein (11). Thisinternal phosphotransfer occurred even in the presence of CbbRR1.However, after histidine autophosphorylation, the absence ofa phosphoacceptor residue within the receiver domain of CbbSRand/or the absence of a response regulator protein would presumablycause dissociation of the phosphoryl group, which would thenbe released into solution. Thus, to further assess the propertiesof the four kinase constructs and their state of phosphorylation,pulse-chase experiments were performed in order to follow thetime-dependent displacement of the label in the presence ofa large excess of unlabeled ATP. Unlabeled ATP should competewith any labeled ATP remaining in solution as a substrate forthe autophosphorylation reaction, ultimately allowing measurementsof the rate of dephosphorylation. With the exception of D696NCbbSR^R96,which was phosphorylated with 25 nM [ ${gamma}$ -³²P]ATP, all constructswere preincubated with 20 µM [ ${gamma}$ -³²P]ATP to allow sufficientautophosphorylation prior to the addition of 100 mM unlabeledATP. Both wild-type truncated constructs (CbbSR^T189 and CbbSR^R96)showed virtually identical rates of dephosphorylation (Fig.7A, B, and D), with gradual label decay throughout the wholeexperimental time frame. However, the two D696NCbbSR constructsexhibited completely different rates of ${gamma}$ -³²P label loss; theD696NCbbSR^T189 protein rapidly lost more than 50% of its labelwithin 1 min of the addition of unlabeled ATP and maintainedonly about 10% of the original level of phosphorylation, thatis, prior to the addition of unlabeled ATP (Fig. 7A and C).By contrast, the phosphorylation level of D696NCbbSR^R96 remainedsubstantially unchanged after 2.5 h (Fig. 7A and E). The lackof dephosphorylation shown by D696NCbbSR^R96 was interesting,in particular with respect to its high affinity for ATP (Fig.6) and weak ability to catalyze phosphotransfer to CbbRR1 (Fig.5). Since H409DCbbSR^R96, much like H409DCbbSR^T189, had no autophosphorylationactivity (11) and contained no label (data not shown), the highaffinity of D696NCbbSR^R96 for ATP was strictly dependent onits kinase activity and not an indirect effect of covalent ATPbinding to the sensor region of the protein, as seen, for instance,in the sporulation master kinase, KinA (12).

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FIG. 7. Pulse-chase analysis of the CbbSR^R96 and CbbSR^T189 wild-type truncated histidine kinase and their D696N site-directed mutants. The phosphorylation levels of the four constructs were normalized to the maximum intensity of signal (100%) of each construct prior to the addition of an excess of unlabeled (100 mM) ATP and plotted against time. Label disappearance ( ${gamma}$ -³²P) is expressed as the percentage of the phosphorylated products obtained at any given time after the addition of unlabeled ATP. The kinase proteins were preincubated with 20 µM [ ${gamma}$ -³²P]ATP for 20 min, with the exception of D696N CbbSR^R96, which was preincubated with 25 nM [ ${gamma}$ -³²P]ATP. The reaction was carried out in a 100-µl final volume. At time zero, 10 µl of the phosphorylation reaction mixture was removed, and 10 µl of unlabeled ATP (100 mM final concentration) was added. Aliquots were removed at the time points indicated. CbbSR^T189, (•); D696NCbbSR^T189, ( ${circ}$ ); CbbSR^R96, ( ${blacktriangledown}$ ); D696NCbbSR^R96, ( ${triangledown}$ ). Raw data were analyzed, normalized, and plotted with SigmaPlot 8.0. Representative pulse-chase patterns of phosphorylation are shown for CbbSR^T189 (B), D696NCbbSR^T189 (C), CbbSR^R96 (D), and D696NCbbSR^R96 (E).

In summary, the results of the kinetic experiments indicatedthe following: (i) that the state of phosphorylation of thewild-type sensor kinase protein is most probably a combinationof its autophosphorylation activity, its internal phosphotransferactivity, and the inherent stability of the phosphorylated residue;and (ii) that the N-terminal region of the sensor kinase betweenresidues Arg-96 and Thr-189, which contains a PAS motif, mustplay a pivotal role in sensing the signal that affects the phosphorylationstate of the protein (i.e., the in vivo signaling mode of theprotein). This region apparently dictates downstream phosphotransferreactions.

Phosphotransfer between D696NCbbSR^R96 and CbbRR2. Although D696NCbbSR^R96 inefficiently catalyzed phosphorylationof CbbRR1 (Fig. 5), this mutant protein, but not wild-type CbbSR^R96(Fig. 3), was able to catalyze a slow rate and moderate levelof phosphotransfer to CbbRR2 (Fig. 8A). In particular, if Asp-195,one of the conserved and potential aspartate phosphoacceptorresidues from the two receiver domains of CbbRR2 was mutated,i.e., by using construct D195NCbbRR2, the apparent rate of phosphotransferfrom D696NCbbSR^R96 to the mutated CbbRR2 proteins was markedlyenhanced (Fig. 8C, D, and E). As for the reaction in the presenceof wild-type CbbSR^R96 (Fig. 3), concomitant mutation of bothaspartate residues completely prevented phosphorylation of CbbRR2(data not shown). Moreover, throughout the 4 h that the phosphorylationexperiments were carried out in the presence of wild-type CbbRR2,further accumulation of phosphorylated D696NCbbSR^R96 was observed(Fig. 8A), suggesting that possible competition for the phosphategroup between residues Asp-54 and Asp-195 of CbbRR2 indirectlyfavored the kinase autophosphorylation reaction. Indeed, thefinal absolute amount of phosphorylated D696NCbbSR^R96 in thepresence of wild-type CbbRR2 was significantly greater thanthat obtained in the presence of the mutant CbbRR2 proteins(Fig. 8D). Finally, D195NCbbRR2 showed greater than double thelevel of phosphorylation compared to wild-type or mutant D54NCbbRR2,strongly suggesting that Asp-54 from CbbRR2 possessed the highestaffinity for the phosphoryl group derived from D696NCbbSR^R96(Fig. 8E).

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FIG. 8. Time course of CbbRR2 phosphorylation. To better resolve the phosphorylation products, the phosphotransfer reaction was performed under the following conditions: 1.2 µM D696NCbbSR^R96 was preincubated with 25 nM [ ${gamma}$ -³²P]ATP for 20 min (time zero), prior to the addition of 24 µM CbbRR2 (A) and its site-directed mutants, D54NCbbRR2 (B) and D195NCbbRR2 (C). Ten-microliter aliquots were removed at the time points indicated. The reaction products were resolved by 12% SDS-PAGE. The phosphorylated proteins are indicated by arrows. (D) Levels of D696NCbbSR^R96 over the time course of phosphotransfer for D696NCbbSR^R96+CbbRR2 (solid line), D696NCbbSR^R96+D54NCbbRR2 (dashed line), and D696NCbbSR^R96+D195NCbbRR2 (dotted line). (E) Levels of phosphorylation for wild-type CbbRR2 ( ${blacklozenge}$ ), D54NCbbRR2 ( ${diamond}$ ), and D195NCbb RR2 (x).

Independent activity of the kinase receiver domain and phosphorylation of the CbbRR1 HPt domain. Because the receiver domain of the sensor kinase appeared toplay a critical role for the reactions thus far described, itsfunction was further addressed by assaying the phosphoacceptoractivity of inactivated kinase constructs, that is, H409DCbbSR,since residue His-409 is essential for kinase activity (11).In a reaction containing 20 µM [ ${gamma}$ -³²P]ATP and equimolarconcentrations of the D696NCbbSR^T189 and H409DCbbSR^R96 proteins(Fig. 9A and B), there was rapid and extensive phosphotransferfrom His-409 of the D696NCbbSR^T189 protein to the receiver domainof the inactive H409DCbbSR^R96 kinase protein. A similar patternof phosphorylation was observed with D696NCbbSR^R96 and H409DCbbSR^T189(data not shown). This result clearly proves that rapid phosphotransferoccurred within the kinase protein; therefore, the kinase receiverdomain functions as a discrete functional unit.

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FIG. 9. The receiver domain on the sensor kinase functions as an independent catalytic unit. (A) Phosphotransfer between D696NCbbSR^T189 and H409DCbbSR^R96 (380 pmol each) in the presence of 20 µM [ ${gamma}$ -³²P]ATP, resolved on an 8% SDS-PAGE gel. Analogous results were obtained with D696NCbbSR^R96 and H409DCbbSR^T189 in the presence of 25 nM [ ${gamma}$ -³²P]ATP (data not shown). (B) Time-dependent accumulation of phosphorylated products when H409DCbbSR^T189 (•) was incubated with D696NCbbSR^R96 ( ${circ}$ ). (C) Residue Asp-696 is a productive phosphodonor to residue His-171 on the CbbRR1 HPt domain. D696NCbbSR^T189 was preincubated with 20 µM [ ${gamma}$ -³²P]ATP for 20 min (lane 1) prior to the simultaneous addition of both H409DCbbSR^R96 (380 pmol) and D54NCbbRR1 (1 nmol). The complete reaction mixture was then incubated for 1 h (lane 2). As additional controls, D696NCbbSR^T189 was incubated with 20 µM [ ${gamma}$ -³²P]ATP (lane 3) prior to adding H409DCbbSR^R96 and D54NH171DCbbRR1 (lane 4). The double mutant D54NH171DCbbRR1 was not phosphorylated.

The function of the CbbRR1 HPt domain was tested for its abilityto receive the phosphoryl group from Asp-696 of the sensor kinase.In general, proteins containing an HPt domain have been shownto participate in multistep phosphorelay processes whereby theactive histidine residue, although incapable of being autophosphorylated,participates in a phosphorylation cascade by providing a "phosphorylation"bridge between two distinct Asp residues (2, 3, 6, 14) eitheras a mono-domain protein or as a functional module of a tripartitehybrid kinase. To assess the interaction between CbbSR and CbbRR1,phosphotransfer was initiated by first preincubating D696NCbbSR^T189with 20 µM [ ${gamma}$ -³²P]ATP for 20 min prior to the simultaneousaddition of both the H409DCbbSR^R96 and D54NCbbRR1 proteins.If there was substantial phosphorylation of the CbbRR1 mutantprotein, this would presumably be due to phosphotransfer fromAsp-696 of the sensor kinase to His-171 of the CbbRR1 protein.Previously, it was established that Asp-54 on CbbRR1 directlyreceived the phosphoryl group from His-409 of the sensor kinase(Fig. 4A); in addition, Asp-696 of the sensor kinase is notrequired for this reaction (11). The pattern of phosphorylation(Fig. 9C, lanes 1 and 2) substantiated the above reasoning.Similar results were obtained by using D696NCbbSR^R96 and H409DCbbSR^T189 (data not shown). A control experiment showed no CbbRR1phosphorylation with a D54NH171DCbbRR1 double mutant (Fig. 9C,lanes 3 and 4). These studies indicated that a multistep phosphorylationreaction occurred whereby the active kinase (mutant D696NCbbSR)catalyzed phosphotransfer to the inactive kinase (mutant H409DCbbSRcontaining the phosphate acceptor residue Asp-696) and eventuallyto His-171 of the D54NCbbRR1 construct. Thus, phosphotransferoccurred from His-409 to Asp-696 on the sensor kinase to His-171on CbbRR1. Since radiolabeled phosphate on the kinase constructswas considerably diminished by the end of the reaction (Fig.9C, lane 2), phosphotransfer appeared to be unidirectional,and His-171 of CbbRR1 did not apparently allow reverse phosphotransferto Asp-696 of the sensor kinase (4). Moreover, D696NCbbSR^R96reacted poorly with CbbRR1 constructs (Fig. 5). This is consistentwith the idea that the kinase receiver domain and the HPt domaininteract as independent functional domains. Finally, experimentswith combinations of all three CbbRRS proteins (i.e., sensorkinase CbbSR and both response regulators CbbRR1 and CbbRR2,in their wild-type as well as mutant forms) indicated that phosphorylatedCbbRR1, in particular, its phosphorylated His-171 residue, wasincapable of passing the phosphoryl group to CbbRR2 (data notshown).

DISCUSSION

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Discussion

Previous results indicated that the CbbRRS system plays a significantrole in the control of form I ribulose 1,5-bisphosphate carboxylase/oxygenasebiosynthesis in R. palustris, with the proper balancing of sensorkinase and response regulator playing an important part in theregulatory mechanism under photoautotrophic (11) and photoheterotrophic(this laboratory, unpublished data) growth conditions. In thecurrent study, phosphotransfer reactions catalyzed by the CbbRRSsystem were analyzed in vitro since a number of events wereconceivable once autophosphorylation of the sensor kinase proteinoccurred. Since these phosphorylation events likely serve aprofound function in vivo, it was particularly important todiscern whether the single kinase, CbbSR, could potentiallyinteract with four distinct receiver domains that show verylimited sequence homology (Fig. 2). Thus, each of the four putativeindependent phosphotransfer reactions was considered here. Twotruncated constructs of different lengths of CbbSR, in combinationwith various active-site residue mutations of CbbSR, CbbRR1,and CbbRR2, provided insight into different signaling statesof the kinase protein. Based on the results of this investigation,hypothetical pathways for the CbbRRS phosphorelay were determined(Fig. 10), and several events were established upon autophosphorylationof residue His-409 of CbbSR: (i) the phosphate group may betransferred to Asp-696 within the kinase receiver domain andthen to the His-171 residue of the CbbRR1 HPt domain; (ii) thephosphate group may also be transferred from His-409 of CbbSRto residue Asp-54 of the receiver domain of CbbRR1; (iii) thephosphate may be transferred from His-409 of CbbSR to eitherAsp-54 or Asp-195 of the two receiver domains of CbbRR2, witha preference for Asp-54. The first of these reactions occurredindependently of the integrity of the N-terminal region of thesensor kinase protein; however, the second and third reactionswere controlled by the presence of residues Arg-96 to Thr-189at the N terminus of CbbSR. Furthermore, it is apparent fromthe in vitro data (Fig. 7) that the extent and degree of phosphorylationof the sensor kinase are influenced by the integrity of theN-terminal region, perhaps defining different conformationalstates of the sensor kinase. This observation raises the possibilitythat the phosphorylation state of the receiver domain of CbbSR,concomitant with the N-terminal region, functions as a majordeterminant to control the specificity of interactions of CbbSRwith either response regulator CbbRR1 or CbbRR2. In the latterinstance, two distinct regions of CbbSR clearly play a cooperativerole in determining the signaling state of the kinase and ultimatelythe phosphotransfer to either CbbRR1 or CbbRR2.

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FIG. 10. Summary of the phosphorylation reactions catalyzed by the CbbRRS system. The conserved residues and motifs on the sensor kinase, CbbSR, and the two response regulators, CbbRR1 and CbbRR2, are indicated.

The HPt domain of CbbRR1 was also intriguing. First of all,CbbRR1 represented the first investigated instance where anHPt domain was found to be part of a response regulator protein.HPt domains appear usually as either independent mono-domainproteins or as subdomains of tripartite hybrid kinases (2, 3,7, 9, 14). The results reported here indicate that the HPt domainof CbbRR1 seems to function as a type of release device, allowingthe kinase and therefore the whole CbbRRS system to reset itssignaling state by removing the phosphate group from residueAsp-696 of the kinase and transferring it to His-171 of CbbRR1.This hypothesis was supported by observations with the mutantH171DCbbRR1 protein, which seemed to react with the wild-typekinase as well as CbbRR1 (Fig. 4); however, no more sequentialtransfer of the phosphate group occurred, either back to thekinase (Fig. 9C) or to CbbRR2 (data not shown). After transferof the phosphate to His-171 of CbbRR1, the phosphorylated HPtdomain likely decays, either by eventual spontaneous hydrolysisof the phosphate group or by means of some as yet unknown phosphatase.

In conclusion, the CbbRRS system was found to catalyze multiplephosphotransfer reactions with at least two functional checkpoints.The integrity of the N-terminal region of the sensor kinaseclearly seems to influence the phosphorylation state of thekinase and specifies active complexes with either one of thetwo response regulators. On the other hand, the multistep phosphotransferreaction to residue His-171 of response regulator CbbRR1 appearedto allow a turnover of the CbbRRS system, so that a new setof phosphorylation reactions might occur. Furthermore, basedupon our findings, we propose that the sensor kinase proteinassumes at least three separate signaling states: (i) an inactivemode, whereby phosphorylation of the kinase is ultimately terminatedby phosphotransfer from His-409 to first its own receiver domainand then to the HPt domain of CbbRR1; (ii) an active mode wherebyCbbSR can catalyze phosphorylation to CbbRR1; and (iii) a secondactive mode in which CbbSR can catalyze phosphorylation of CbbRR2.Transitions between these modes appeared to be determined bythe signaling state of the N-terminal sensor region, possiblyin response to some threshold level of intensity of the activatingstimulus. The consequence would be the creation of an internaldevice to control downstream phosphotransfer reactions. Furtherstudies will seek to identify the signal(s) that determine(s)each single step of the complex phosphorelay identified hereand the physiological consequences of each of the phosphorylationsteps.

ACKNOWLEDGMENTS

This work was supported by Genomics: GTL grant DOE DE-FG02-01ER63241from the U.S. Department of Energy (Office of Biological andEnvironmental Research, Office of Science) and grant GM25404from the National Institutes of Health.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology, The Ohio State University, 484 West 12th Avenue, Columbus, OH 43210-1292. Phone: (614) 292-4297. Fax: (614) 292-6337. E-mail: tabita.1{at}osu.edu.

Published ahead of print on 27 October 2006.

REFERENCES

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