The sensor kinase CitA (DpiB) of Escherichia coli functions as a high-affinity citrate receptor

For the CitA-CitB (DpiB-DpiA) two-component signal transduction system from Escherichia coli, three diverse functions have been reported: induction of the citrate fermentation genes citCDEFXGT, repression of the regulator gene appY, and destabilization of the inheritance of iteron-containing plasmids such as pSC101. This poses the question of the principal biological role of this system. Here it is shown that the periplasmic domain of the E. coli sensor kinase CitA functions as a high-affinity citrate receptor. Two CitA derivatives were purified by affinity chromatography and subjected to binding studies using isothermal titration calorimetry (ITC). One of them, termed CitA215MBP, comprised the N-terminal part of CitA (amino acid residues 1-215), including the two transmembrane helices, and was fused to the amino terminus of the E. coli maltose-binding protein lacking its signal peptide. The second CitA derivative, designated CitAP(Ec), encompassed only the periplasmic domain (amino acid residues 38-177). CitA215MBP bound citrate at 25 degrees C with a K(d) of 0.3 microM and a binding stoichiometry of up to 0.9 in 50 mM sodium phosphate buffer, pH 7. Binding was driven by the enthalpy change (Delta H of -95.7 kJ mol(-1)), whereas the entropy change was not favorable for binding ( T Delta S of -58.6 kJ mol(-1)). ITC experiments with CitAP(Ec) yielded similar K(d) values for citrate (0.15-1.0 microM). Besides citrate, also isocitrate ( K(d) approximately tricarballylate ( K(d) approximately t not malate were bound by CitAP(Ec). The results favor the assumption that the primary biological function of the CitA-CitB system is the regulation of the citrate fermentation genes.     

The structure of the periplasmic ligand-binding domain of the sensor kinase CitA reveals the first extracellular PAS domain

The integral membrane sensor kinase CitA of Klebsiella pneumoniae is part of a two-component signal transduction system that regulates the transport and metabolism of citrate in response to its environmental concentration. Two-component systems are widely used by bacteria for such adaptive processes, but the stereochemistry of periplasmic ligand binding and the mechanism of signal transduction across the membrane remain poorly understood. The crystal structure of the CitAP periplasmic sensor domain in complex with citrate reveals a PAS fold, a versatile ligand-binding structural motif that has not previously been observed outside the cytoplasm or implicated in the transduction of conformational signals across the membrane. Citrate is bound in a pocket that is shared among many PAS domains but that shows structural variation according to the nature of the bound ligand. In CitAP, some of the citrate contact residues are located in the final strand of the central beta-sheet, which is connected to the C-terminal transmembrane helix. These secondary structure elements thus provide a potential conformational link between the periplasmic ligand binding site and the cytoplasmic signaling domains of the receptor.     

A ligand-induced switch in the periplasmic domain of sensor histidine kinase CitA

Sensor histidine kinases of two-component signal-transduction systems are essential for bacteria to adapt to variable environmental conditions. However, despite their prevalence, it is not well understood how extracellular signals such as ligand binding regulate the activity of these sensor kinases. CitA is the sensor histidine kinase in Klebsiella pneumoniae that regulates the transport and anaerobic metabolism of citrate in response to its extracellular concentration. We report here the X-ray structures of the periplasmic sensor domain of CitA in the citrate-free and citrate-bound states. A comparison of the two structures shows that ligand binding causes a considerable contraction of the sensor domain. This contraction may represent the molecular switch that activates transmembrane signaling in the receptor.     

The periplasmic domain of the histidine autokinase CitA functions as a highly specific citrate receptor.

The two-component regulatory system CitA/CitB is essential for induction of the citrate fermentation genes in Klebsiella pneumoniae. CitA represents a membrane-bound sensor kinase consisting of a periplasmic domain flanked by two transmembrane helices, a linker domain and the conserved kinase or transmitter domain. A fusion protein (MalE-CitAC) composed of the maltose-binding protein and the CitA kinase domain (amino acids 327-547) showed constitutive autokinase activity and transferred the gamma-phosphate group of ATP to its cognate response regulator CitB. The autokinase activity of CitA was abolished by an H350L exchange, and phosphorylation of CitB was inhibited by a D56N exchange, indicating that H-350 and D-56 represent the phosphorylation sites of CitA and CitB respectively. In the presence of ATP, CitB-D56N formed a stable complex with MalE-CitAC. To analyse the sensory properties of CitA, the periplasmic domain (amino acids 45-176) was overproduced as a soluble, cytoplasmic protein with a C-terminally attached histidine tag (CitAPHis). Purified CitAPHis bound citrate, but none of the other tri- and dicarboxylates tested, with high affinity (KD approximately 5 microM at pH 7) in a 1:1 stoichiometry. As shown by isothermal titration calorimetry, the binding reaction was driven by the enthalpy change (DeltaH = -76.3 kJ mol-1), whereas the entropy change was opposed (-TDeltaS = + 46.3 kJ mol-1). The pH dependency of the binding reaction indicated that the dianionic form H-citrate2- is the citrate species recognized by CitAPHis. In the presence of Mg2+ ions, the dissociation constant increased significantly, suggesting that the Mg-citrate complex is not bound by CitAPHis. This work defines the periplasmic domain of CitA as a highly specific citrate receptor and elucidates the binding characteristics of CitAPHis.     

Citrate sensing by the C4-dicarboxylate/citrate sensor kinase DcuS of Escherichia coli: binding site and conversion of DcuS to a C4-dicarboxylate- or citrate-specific sensor

The histidine protein kinase DcuS of Escherichia coli senses C(4)-dicarboxylates and citrate by a periplasmic domain. The closely related sensor kinase CitA binds citrate, but no C(4)-dicarboxylates, by a homologous periplasmic domain. CitA is known to bind the three carboxylate and the hydroxyl groups of citrate by sites C1, C2, C3, and H. DcuS requires the same sites for C(4)-dicarboxylate sensing, but only C2 and C3 are highly conserved. It is shown here that sensing of citrate by DcuS required the same sites. Binding of citrate to DcuS, therefore, was similar to binding of C(4)-dicarboxylates but different from that of citrate binding in CitA. DcuS could be converted to a C(4)-dicarboxylate-specific sensor (DcuS(DC)) by mutating residues of sites C1 and C3 or of some DcuS-subtype specific residues. Mutations around site C1 aimed at increasing the size and accessibility of the site converted DcuS to a citrate-specific sensor (DcuS(Cit)). DcuS(DC) and DcuS(Cit) had complementary effector specificities and responded either to C(4)-dicarboxylates or to citrate and mesaconate. The results imply that DcuS binds citrate (similar to the C(4)-dicarboxylates) via the C(4)-dicarboxylate part of the molecule. Sites C2 and C3 are essential for binding of two carboxylic groups of citrate or of C(4)-dicarboxylates; sites C1 and H are required for other essential purposes.     

Role of acid metabolism in Streptomyces coelicolor morphological differentiation and antibiotic biosynthesis

Studies of citrate synthase (CitA) were carried out to investigate its role in morphological development and biosynthesis of antibiotics in Streptomyces coelicolor. Purification of CitA, the major vegetative enzyme activity, allowed characterization of its kinetic properties. The apparent K(m) values of CitA for acetyl coenzyme A (acetyl-CoA) (32 microM) and oxaloacetate (17 microM) were similar to those of citrate synthases from other gram-positive bacteria and eukaryotes. CitA was not strongly inhibited by various allosteric feedback inhibitors (NAD(+), NADH, ATP, ADP, isocitrate, or alpha-ketoglutarate). The corresponding gene (citA) was cloned and sequenced, allowing construction of a citA mutant (BZ2). BZ2 was a glutamate auxotroph, indicating that citA encoded the major citrate synthase allowing flow of acetyl-CoA into the tricarboxylic acid (TCA) cycle. Interruption of aerobic TCA cycle-based metabolism resulted in acidification of the medium and defects in morphological differentiation and antibiotic biosynthesis. These developmental defects of the citA mutant were in part due to a glucose-dependent medium acidification that was also exhibited by some other bald mutants. Unlike other acidogenic bald strains, citA and bldJ mutants were able to produce aerial mycelia and pigments when the medium was buffered sufficiently to maintain neutrality. Extracellular complementation studies suggested that citA defines a new stage of the Streptomyces developmental cascade.     

An aspartate residue at the extracellular boundary of TMII and an arginine residue in TMVII of the gastrin-releasing peptide receptor interact to facilitate heterotrimeric G protein coupling.

The mammalian bombesin receptor subfamily of G protein-coupled receptors currently consists of the gastrin-releasing peptide receptor (GRP-R), neuromedin B receptor, and bombesin receptor subtype 3. All three receptors contain a conserved aspartate residue (D98) at the extracellular boundary of transmembrane domain II and a conserved arginine residue (R309) near the extracellular boundary of transmembrane domain VII. To evaluate the functional role of these residues, site-directed GRP-R mutants were expressed in fibroblasts and assayed for their ability to both bind agonist and catalyze exchange of guanine nucleotides. Alanine substitution at GRP-R position 98 or 309 reduced agonist binding affinity by 24- and 56-fold, respectively, compared to wild-type GRP-R. Single swap GRP-R mutations either resulted in no receptor expression in the membrane (D98R) or the protein was not able to bind agonist (R309D). In contrast, the double swap mutation (D98R/R309D) had high-affinity agonist binding, reduced from wild-type GRP-R by only 6-fold. In situ reconstitution of urea-extracted membranes expressing either wild-type or mutant (D98A or R309A) GRP-R with G(q) indicated that alanine substitution greatly reduced G protein catalytic exchange compared to wild-type GRP-R. The D98R/R309D GRP-R had both a higher intrinsic basal activity and a higher overall catalytic exchange activity compared to wild-type; however, the wild-type GRP-R produced a larger agonist-stimulated response relative to the double swap mutant. Taken together, these data show that GRP-R residues D98 and R309 are critical for efficient coupling of GRP-R to G(q). Furthermore, our findings are consistent with a salt bridge interaction between these two polar and oppositely charged amino acids that maintains the proper receptor conformation necessary to interact with G proteins.     

The enhanced affinity for thiolate anion and activation of enzyme-bound glutathione is governed by an arginine residue of human Mu class glutathione S-transferases

A series of chimeric human Mu class glutathione S-transferases were designed to determine mechanisms by which they activate enzyme-bound glutathione (GSH) for reaction with electrophilic substrates. In view of evidence that the His(107) residue of hGSTM1a-1a is important for catalysis (Patskovsky, Y. V., Patskovska, L. N., and Listowsky, I. (1999) Biochemistry 38, 1193-1202), the cognate Arg(107) residue of the hGSTM2 subunit was replaced (R107N or R107H) and arginine residues were also incorporated into position 107 of hGSTM1 (H107R) and hGSTM4 (S107R) subunits. The major distinguishing kinetic properties invariably associated with enzymes containing an Arg(107) residue include an inverse dependence of k(cat) on viscosity and lower K(m(GSH values relative to enzymes with other residues at that position. Moreover, affinities for GSH thiolate anion binding are greater for enzymes containing Arg(107))), with K(d) values of 20-50 microM that are consistent with the K(m(GSH values (10-25 microM) obtained by steady-state kinetic analyses. Both thermodynamic and kinetic and data indicate that the Arg(107))) residue is specifically involved in enhancing the binding affinity of GSH thiolate anion relative to that of the protonated form. These enzymes therefore, can be more effective at lower GSH concentrations. Combined mutations indicate that both Arg(107) and Tyr(6) residues are required for thiolate anion formation and stabilization. The three-dimensional structure of ligand-free hGSTM2-2 determined by x-ray crystallography suggests that Arg(107) maintains an electrostatic interaction with the Asp(161) side chain (3 A apart), but is distant from the GSH-binding site. However, an alternative energetically favorable model places the guanidino group 4 A from the sulfur atom of bound GSH. It is suggested therefore, that in solution, motion of the positively charged arginine into the catalytic pocket could provide a counter ion to promote ionization of the sulfhydryl group of GSH, thereby accounting for the observed greater affinity of enzymes containing Arg(107) for binding of thiolate anion.     

Crystal structure of a functional dimer of the PhoQ sensor domain

The PhoP-PhoQ two-component system is a well studied bacterial signaling system that regulates virulence and stress response. Catalytic activity of the histidine kinase sensor protein PhoQ is activated by low extracellular concentrations of divalent cations such as Mg2+, and subsequently the response regulator PhoP is activated in turn through a classic phosphotransfer pathway that is typical in such systems. The PhoQ sensor domains of enteric bacteria contain an acidic cluster of residues (EDDDDAE) that has been implicated in direct binding to divalent cations. We have determined crystal structures of the wild-type Escherichia coli PhoQ periplasmic sensor domain and of a mutant variant in which the acidic cluster was neutralized to conservative uncharged residues (QNNNNAQ). The PhoQ domain structure is similar to that of DcuS and CitA sensor domains, and this PhoQ-DcuS-CitA (PDC) sensor fold is seen to be distinct from the superficially similar PAS domain fold. Analysis of the wild-type structure reveals a dimer that allows for the formation of a salt bridge across the dimer interface between Arg-50' and Asp-179 and with nickel ions bound to aspartate residues in the acidic cluster. The physiological importance of the salt bridge to in vivo PhoQ function has been confirmed by mutagenesis. The mutant structure has an alternative, non-physiological dimeric association.     

CitA/CitB two-component system regulating citrate fermentation in Escherichia coli and its relation to the DcuS/DcuR system in vivo

Citrate fermentation by Escherichia coli requires the function of the citrate/succinate antiporter CitT (citT gene) and of citrate lyase (citCDEFXG genes). Earlier experiments suggested that the two-component system CitA/CitB, consisting of the membrane-bound sensor kinase CitA and the response regulator CitB, stimulates the expression of the genes in the presence of citrate, similarly to CitA/CitB of Klebsiella pneumoniae. In this study, the expression of a chromosomal citC-lacZ gene fusion was shown to depend on CitA/CitB and citrate. CitA/CitB is related to the DcuS/DcuR two-component system which induces the expression of genes for fumarate respiration in response to C(4)-dicarboxylates and citrate. Unlike DcuS, CitA required none of the cognate transporters (CitT, DcuB, or DcuC) for function, and the deletion of the corresponding genes showed no effect on the expression of citC-lacZ. The citAB operon is preceded by a DcuR binding site. Phosphorylated DcuR bound specifically to the promoter region, and the deletion of dcuS or dcuR reduced the expression of citC. The data indicate the presence of a regulatory cascade consisting of DcuS/DcuR modulating citAB expression (and CitA/CitB levels) and CitA/CitB controlling the expression of the citCDEFXGT gene cluster in response to citrate. In vivo fluorescence resonance energy transfer (FRET) and the bacterial two-hybrid system (BACTH) showed interaction between the DcuS and CitA proteins. However, BACTH and expression studies demonstrated the lack of interaction and cross-regulation between CitA and DcuR or DcuS and CitB. Therefore, there is only linear phosphoryl transfer (DcuS→DcuR and CitA→CitB) without cross-regulation between DcuS/DcuR and CitA/CitB.     

Role of walker motif A of RuvB protein in promoting branch migration of holliday junctions. Walker motif a mutations affect Atp binding, Atp hydrolyzing, and DNA binding activities of Ruvb.

Escherichia coli RuvB protein, an ATP-dependent hexameric DNA helicase, acts together with RuvA protein to promote branch migration of Holliday junctions during homologous recombination and recombinational repair. To elucidate the role of the Walker motif A of RuvB (GXGKT; X indicates a nonconserved residue) in ATP hydrolysis and branch migration activities, we constructed four ruvB mutant genes by site-directed mutagenesis, altering the highly conserved Lys(68) and Thr(69). K68R, K68A, and T69A mutants except T69S failed to complement UV-sensitive phenotype of the ruvB strain. These three mutant proteins, when overexpressed, made the wild-type strain UV-sensitive to varying degrees. K68R, K68A, and T69A were defective in ATP hydrolysis and branch migration activities in vitro. In the presence of Mg(2+), K68R showed markedly reduced affinity for ATP, while K68A and T69A showed only mild reduction. K68A and T69A could form hexamers in the presence of Mg(2+) and ATP, while K68R failed to form hexamers and existed instead as a higher oligomer, probably a dodecamer. In contrast to wild-type RuvB, K68R, K68A, and T69A by themselves were defective in DNA binding. However, RuvA could facilitate binding of K68A and T69A to DNA, whereas it could not promote binding of K68R to DNA. All of the three mutant RuvBs could physically interact with RuvA. These results indicate the direct involvement in ATP binding and ATP hydrolysis of the invariant Lys(68) and Thr(69) residues of Walker motif A of RuvB and suggest that these residues play key roles in interrelating these activities with the conformational change of RuvB, which is required for the branch migration activity.     

Identification of functionally important residues of the epidermal growth factor-2 domain of factor IX by alanine-scanning mutagenesis. Residues Asn(89)-Gly(93) are critical for binding factor VIIIa

This paper describes the consequences of alanine-scanning mutagenesis on 28 positions of the second epidermal growth factor (EGF-2) domain of factor IX. We identified four positions of Gln(97), Phe(98), Tyr(115), and Leu(117) that are critical for secretion of factor IX. Of the remaining mutations, 4 mutants (V86A, E113A, K122A, and S123A) are as active as wild-type factor IX (IXwt); 16 (D85A, K100A, N101A, D104A, N105A, R116A, E119A, T87A, I90A, K91A, R94A, E96A, S102A, K106A, T112A, and N120A) retain reduced but detectable activity, and 4 (N89A, N92A, G93A, and V107A) are nearly inert in the clotting assay. Both factor XIa and the factor VIIa-tissue factor complex effectively catalyzed the activation of these mutants except N89A. The mutant V107A failed to form the factor tenase complex with factor VIIIa because of a 35-fold increase in K(d). The mutants N89A and N92A did not compete with factor IXwt for factor VIIIa binding, and G93A exhibited a 6-fold increase in K(i) values in the competitive binding assay. It appears that mutations at these positions have significantly affected the interaction between factor IX and factor VIIIa, although other mutations had little effect on the binding of factor IX to factor VIIIa. Mutations in two regions, Thr(87)-Gly(93) and Asn(101)-Val(107), significantly increased the K(m) value of factor IXa (2-10-fold) in cleavage of factor X in the absence of factor VIIIa. In the presence of factor VIIIa, the catalytic efficiency of each mutant toward factor X paralleled its clotting activity. Briefly, we propose two relatively distinctive functions of factor IX for two adjacent regions in the EGF-2 domain; the first loop region (residues 89-94) is involved with the binding of its cofactor, factor VIIIa, and the third loop with connected beta-sheets (residues 102-108) is involved in the proper binding to the substrate, factor X.     

Kinetic mechanism of fully activated S6K1 protein kinase

S6K1 is a member of the AGC subfamily of serine-threonine protein kinases, whereby catalytic activation requires dual phosphorylation of critical residues in the conserved T-loop (Thr-229) and hydrophobic motif (Thr-389). Previously, we described production of the fully activated catalytic kinase domain construct, His(6)-S6K1alphaII(DeltaAID)-T389E. Now, we report its kinetic mechanism for catalyzing phosphorylation of a model peptide substrate (Tide, RRRLSSLRA). First, two-substrate steady-state kinetics and product inhibition patterns indicated a Steady-State Ordered Bi Bi mechanism, whereby initial high affinity binding of ATP (K(d)(ATP)=5-6 microM) was followed by low affinity binding of Tide (K(d)(Tide)=180 microM), and values of K(m)(ATP)=5-6 microM and K(m)(Tide)=4-5 microM were expressed in the active ternary complex. Global curve-fitting analysis of ATP, Tide, and ADP titrations of pre-steady-state burst kinetics yielded microscopic rate constants for substrate binding, rapid chemical phosphorylation, and rate-limiting product release. Catalytic trapping experiments confirmed rate-limiting steps involving release of ADP. Pre-steady-state kinetic and catalytic trapping experiments showed osmotic pressure to increase the rate of ADP release; and direct binding experiments showed osmotic pressure to correspondingly weaken the affinity of the enzyme for both ADP and ATP, indicating a less hydrated conformational form of the free enzyme.     

Differential effect toward inhibition of papain and cathepsin C by recombinant human salivary cystatin SN and its variants produced by a baculovirus system

Human salivary cystatin SN (CsnSN) is a member of the cystatin superfamily of cysteine proteinase inhibitors. In this study we used a baculovirus expression system to produce a full-length unaltered CsnSN and its variants. The variants were constructed with the changes in the three predicted proteinase-binding regions: the N-terminus (variant N(12-13), G12A-G13A), beta-hairpin loop I (variant L(56-58), Q56G-T57G-V58G) and beta-hairpin loop II (variant L(106-107), P106G-W107G). The secreted CsnSNs were purified using sequential spiral cartridge ultrafiltration and DE-52 radial flow chromatography. The purified proteins were examined for papain- and cathepsin C-inhibition. The wild-type CsnSN, and variants N(12-13) and L(106-107) bound tightly to papain (K(i) < 10 pM), whereas mutation in the loop I reduced binding affinity 5700-fold (K(i) = 57 nM). On the other hand, the wild-type CsnSN bound to cathepsin C less tightly (K(i) = 100 nM). The mutation in the N-terminus or loop I reduced binding affinity by 16 (K(i) = 1.6 microM)- and 19-fold (K(i) = 1.9 microM), respectively, while mutation in loop II resulted in an ineffective cathepsin C inhibitor (K(i) = 14 microM). Collectively, these results suggest that the N-terminal G12-G13 residues of CsnSN are not essential for papain inhibition but play a role in cathepsin C inhibition; residues Q56-T57-V58 in the loop I are essential for both papain and cathepsin C inhibitions, and residues P106-W107 in the loop II are not important for papain inhibition but essential for cathepsin C inhibition. These results demonstrated that CsnSN variants have different effects toward different cysteine proteinases.     

Characterization of three essential residues in the conserved ATP-binding region of Epstein-Barr virus thymidine kinase

The thymidine kinase encoded by Epstein-Barr virus (EBV TK) is an important target for antiviral therapy and the treatment of EBV-associated malignancies. Through computer-assisted alignment with other human herpesviral TK proteins, EBV TK was shown to contain a conserved ATP-binding motif as for the other TK enzymes. To investigate functional roles of three highly conserved residues (G294, K297, T298) within this region, site-directed mutagenesis was employed to generate various mutants. The TK enzyme activity and ATP-binding ability of these mutant TK enzymes were determined and compared with EBV wild-type TK (wtTK). Mutant G294V lost its ATP-binding ability and was inactive in enzyme activity assay. As the enzyme activity of G294A was reduced to 20% of that of wtTK, the K(m) for ATP binding of G294A was 48.7 microM as compared with 30.0 microM of EBV wtTK. These results suggested that G294 participates in ATP binding and contributes to maintenance of structure. EBV TK mutants K297E, K297Q, and K297R lost their ATP-binding ability and enzyme activity. However, K297R was shown to have a preference for usage of GTP (K(m): 43.0 microM) instead of ATP (K(m): 87.6 microM) as the phosphate donor. This implies that, in addition to nucleotide binding, K297 was involved in the selection of phosphate donor. While EBV TK mutant T298S retained approximately 80% of wtTK enzyme activity, T298A lost its enzyme activity, suggesting that a hydroxyl group at this position is important for the enzyme activity. Interestingly, T298A retained its ATP-binding ability, suggesting a role of T298 in the catalytic process but not in the coordination of ATP. This study demonstrated that amino acid residues G294, K297, and T298 in the ATP-binding motif of EBV TK enzyme are essential for the enzymatic activity but are involved in different aspects of its action.     

Engineering genetically encoded nanosensors for real-time in vivo measurements of citrate concentrations

Citrate is an intermediate in catabolic as well as biosynthetic pathways and is an important regulatory molecule in the control of glycolysis and lipid metabolism. Mass spectrometric and NMR based metabolomics allow measuring citrate concentrations, but only with limited spatial and temporal resolution. Methods are so far lacking to monitor citrate levels in real-time in-vivo. Here, we present a series of genetically encoded citrate sensors based on Förster resonance energy transfer (FRET). We screened databases for citrate-binding proteins and tested three candidates in vitro. The citrate binding domain of the Klebsiella pneumoniae histidine sensor kinase CitA, inserted between the FRET pair Venus/CFP, yielded a sensor highly specific for citrate. We optimized the peptide linkers to achieve maximal FRET change upon citrate binding. By modifying residues in the citrate binding pocket, we were able to construct seven sensors with different affinities spanning a concentration range of three orders of magnitude without losing specificity. In a first in vivo application we show that E. coli maintains the capacity to take up glucose or acetate within seconds even after long-term starvation.     

Characterization of the phosphotransferase domain of casein kinase II by site-directed mutagenesis and expression in Escherichia coli.

The catalytic alpha subunit of casein kinase II contains the 11 conserved domains characteristic of all protein kinases. Domain II and VII are involved in nucleotide binding and phosphotransfer. Two residues of the alpha subunit, Val-66 (in domain II) and Trp-176 (in domain VII), were changed to Ala-66 and Phe-176, the residues present in more than 95% of the identified protein kinase sequences. These changes altered the selectivity of the alpha subunit for ATP and GTP. The Ala-66 mutant showed an increase in the Km value for GTP from 45 to 71 microM, while the Km value for ATP decreased from 13 to 9 microM. The Km value for ATP with the Phe-176 mutant showed a decrease from 13 to 7 microM. A double mutant of Ala-66/Phe-176 showed the combined effects, with a Km of 6 microM for ATP and 70 microM for GTP. Alteration of Trp-176 to Lys-176, an amino acid which is not present in the corresponding position of any known protein kinase, resulted in a lack of phosphotransferase activity. The mutations, Val-66 to Ala-66 and Trp-176 to Phe-176, also altered the interaction of the alpha subunit with the regulatory beta subunit. In contrast to the wild-type alpha subunit, which was stimulated 4-fold by addition of the beta subunit, the Ala-66 and Ala-66/Phe-176 mutants were not stimulated by the beta subunit, while the Phe-176 mutant was stimulated only 2.5-fold. All of the reconstituted holoenzymes were similar in molecular weight to the native holoenzyme. The stimulation of the phosphotransferase activity toward beta-casein B by spermine and polylysine, which is mediated by the beta subunit, was similar for holoenzymes reconstituted with either wild-type or mutant alpha subunits. Therefore, binding of the beta subunit appears to alter the active site of the alpha subunit directly or indirectly by inducing a conformational change. Ala-66 and Phe-176 mutations appear to change the structure of the alpha subunit sufficiently so that interaction of the subunits is altered and the stimulatory effect of the beta subunit is reduced or eliminated.     

C4-dicarboxylates sensing mechanism revealed by the crystal structures of DctB sensor domain

C₄-dicarboxylates are the major carbon and energy sources during the symbiotic growth of rhizobia. Responses to C₄-dicarboxylates depend on typical two-component systems (TCS) consisting of a transmembrane sensor histidine kinase and a cytoplasmic response regulator. The DctB-DctD system is the first identified TCS for C₄-dicarboxylates sensing. Direct ligand binding to the sensor domain of DctB is believed to be the first step of the sensing events. In this report, the water-soluble periplasmic sensor domain of Sinorhizobium meliloti DctB (DctBp) was studied, and three crystal structures were solved: the apo protein, a complex with C₄ succinate, and a complex with C₃ malonate. Different from the two structurally known CitA family of carboxylate sensor proteins CitA and DcuS, the structure of DctBp consists of two tandem Per-Arnt-Sim (PAS) domains and one N-terminal helical region. Only the membrane-distal PAS domain was found to bind the ligands, whereas the proximal PAS domain was empty. Comparison of DctB, CitA, and DcuS suggests a detailed stereochemistry of C₄-dicarboxylates ligand perception. The structures of the different ligand binding states of DctBp also revealed a series of conformational changes initiated upon ligand binding and propagated to the N-terminal domain responsible for dimerization, providing insights into understanding the detailed mechanism of the signal transduction of TCS histidine kinases.     

The phosphatidylserine binding site of the factor Va C2 domain accounts for membrane binding but does not contribute to the assembly or activity of a human factor Xa-factor Va complex

Factors V(a) and X(a) (FV(a) and FX(a), respectively) assemble on phosphatidylserine (PS)-containing platelet membranes to form the essential "prothrombinase" complex of blood coagulation. The C-terminal domain (C2) of FV(a) (residues 2037-2196 in human FV(a)) contains a soluble phosphatidylserine (C6PS) binding pocket flanked by a pair of tryptophan residues, Trp(2063) and Trp(2064). Mutating these tryptophans abolishes FV(a) membrane binding. To address both the roles of these tryptophans in C6PS or membrane binding and the role of the C2 domain lipid binding site in regulation of FV(a) cofactor activity, we expressed W(2063,2064)A mutants of the recombinant C2 domain (rFV(a2)-C2) and of a B domain-deleted factor V light isoform (rFV(a2)) in Hi-5 and COS cells, respectively. Intrinsic fluorescence showed that wild-type rFV(a2)-C2 binds to C6PS and to 20% PS/PC membranes with apparent K(d) values of 2.8 microM and 9 nM, respectively, while mutant rFV(a2)-C2 does not. Equilibrium dialysis confirmed that mutant rFV(a2)-C2 does not bind to C6PS. Mutant rFV(a2) binds to C6PS (K(d) approximately 37 microM) with an affinity comparable to that of wild-type rFV(a2) (K(d) approximately 20 microM), although it does not bind to PS/PC membranes to which wild-type rFV(a2) binds with native affinity (K(d) approximately 3 nM). Both wild-type and mutant rFV(a2) bind to active site-labeled FX(a) (DEGR-X(a)) in the presence of 400 microM C6PS with native affinity (K(d) approximately 3-4 nM) to produce a solution rFV(a2)-FX(a) complex of native activity. We conclude that (1) the C2 domain PS site provides all but approximately 1 kT of the free energy of FV(a) membrane binding, (2) tryptophans lining the C2 lipid binding pocket are critical to C6PS and membrane binding and insert into the bilayer interface during membrane binding, (3) occupancy of the C2 lipid binding pocket is not necessary for C6PS-induced formation of the FX(a)-FV(a) complex or its activity, but (4) another PS site on FV(a) does have a regulatory role.     

Kinetic, stereochemical, and structural effects of mutations of the active site arginine residues in 4-oxalocrotonate tautomerase.

Three arginine residues (Arg-11, Arg-39, Arg-61) are found at the active site of 4-oxalocrotonate tautomerase in the X-ray structure of the affinity-labeled enzyme [Taylor, A. B., Czerwinski, R. M., Johnson, R. M., Jr., Whitman, C. P., and Hackert, M. L. (1998) Biochemistry 37, 14692-14700]. The catalytic roles of these arginines were examined by mutagenesis, kinetic, and heteronuclear NMR studies. With a 1,6-dicarboxylate substrate (2-hydroxymuconate), the R61A mutation showed no kinetic effects, while the R11A mutation decreased k(cat) 88-fold and increased K(m) 8.6-fold, suggesting both binding and catalytic roles for Arg-11. With a 1-monocarboxylate substrate (2-hydroxy-2,4-pentadienoate), no kinetic effects of the R11A mutation were found, indicating that Arg-11 interacts with the 6-carboxylate of the substrate. The stereoselectivity of the R11A-catalyzed protonation at C-5 of the dicarboxylate substrate decreased, while the stereoselectivity of protonation at C-3 of the monocarboxylate substrate increased in comparison with wild-type 4-OT, indicating the importance of Arg-11 in properly orienting the dicarboxylate substrate by interacting with the charged 6-carboxylate group. With 2-hydroxymuconate, the R39A and R39Q mutations decreased k(cat) by 125- and 389-fold and increased K(m) by 1.5- and 2.6-fold, respectively, suggesting a largely catalytic role for Arg-39. The activity of the R11A/R39A double mutant was at least 10(4)-fold lower than that of the wild-type enzyme, indicating approximate additivity of the effects of the two arginine mutants on k(cat). For both R11A and R39Q, 2D (1)H-(15)N HSQC and 3D (1)H-(15)N NOESY-HSQC spectra showed chemical shift changes mainly near the mutated residues, indicating otherwise intact protein structures. The changes in the R39Q mutant were mainly in the beta-hairpin from residues 50 to 57 which covers the active site. HSQC titration of R11A with the substrate analogue cis, cis-muconate yielded a K(d) of 22 mM, 37-fold greater than the K(d) found with wild-type 4-OT (0.6 mM). With the R39Q mutant, cis, cis-muconate showed negative cooperativity in active site binding with two K(d) values, 3.5 and 29 mM. This observation together with the low K(m) of 2-hydroxymuconate (0.47 mM) suggests that only the tight binding sites function catalytically in the R39Q mutant. The (15)Nepsilon resonances of all six Arg residues of 4-OT were assigned, and the assignments of Arg-11, -39, and -61 were confirmed by mutagenesis. The binding of cis,cis-muconate to wild-type 4-OT upshifts Arg-11 Nepsilon (by 0.05 ppm) and downshifts Arg-39 Nepsilon (by 1.19 ppm), indicating differing electronic delocalizations in the guanidinium groups. A mechanism is proposed in which Arg-11 interacts with the 6-carboxylate of the substrate to facilitate both substrate binding and catalysis and Arg-39 interacts with the 1-carboxylate and the 2-keto group of the substrate to promote carbonyl polarization and catalysis, while Pro-1 transfers protons from C-3 to C-5. This mechanism, together with the effects of mutations of catalytic residues on k(cat), provides a quantitative explanation of the 10(7)-fold catalytic power of 4-OT. Despite its presence in the active site in the crystal structure of the affinity-labeled enzyme, Arg-61 does not play a significant role in either substrate binding or catalysis.