Purification and characterization of an allosteric fructose-1,6-bisphosphate aldolase from germinating mung beans (Vigna radiata)

Cytosolic fructose-1,6-P(2) (FBP) aldolase (ALD(c)) from germinated mung beans has been purified 1078-fold to electrophoretic homogeneity and a final specific activity of 15.1 micromol FBP cleaved/min per mg of protein. SDS-PAGE of the final preparation revealed a single protein-staining band of 40 kDa that cross-reacted strongly with rabbit anti-(carrot ALD(c))-IgG. The enzyme's native M(r) was determined by gel filtration chromatography to be 160 kDa, indicating a homotetrameric quaternary structure. This ALD is a class I ALD, since EDTA or Mg(2+) had no effect on its activity, and was relatively heat-stable losing 0-25% of its activity when incubated for 5 min at 55-65 degrees C. It demonstrated: (i) a temperature coefficient (Q(10)) of 1.7; (ii) an activation energy of 9.2 kcal/mol active site; and (iii) a broad pH-activity optima of 7.5. Mung bean ALD(c) is bifunctional for FBP and sedoheptulose-1,7-P(2) (K(m) approximately 17 microM for both substrates). ATP, ADP, AMP and ribose-5-P exerted inhibitory effects on the activity of the purified enzyme. Ribose-5-P, ADP and AMP functioned as competitive inhibitors (K(i) values=2.2, 3.1 and 7.5mM, respectively). By contrast, the addition of 2mM ATP: (i) reduced V(max) by about 2-fold, (ii) increased K(m)(FBP) by about 4-fold, and (iii) shifted the FBP saturation kinetic plot from hyperbolic to sigmoidal (h=1.0 and 2.6 in the absence and presence of 2mM ATP, respectively). Potent feedback inhibition of ALD(c) by ATP is suggested to help balance cellular ATP demands with the control of cytosolic glycolysis and respiration in germinating mung beans.     

High yield of B-branch electron transfer in a quadruple reaction center mutant of the photosynthetic bacterium Rhodobacter sphaeroides

A new reaction center (RC) quadruple mutant, called LDHW, of Rhodobacter sphaeroides is described. This mutant was constructed to obtain a high yield of B-branch electron transfer and to study P(+)Q(B)(-) formation via the B-branch. The A-branch of the mutant RC contains two monomer bacteriochlorophylls, B(A) and beta, as a result of the H mutation L(M214)H. The latter bacteriochlorophyll replaces bacteriopheophytin H(A) of wild-type RCs. As a result of the W mutation A(M260)W, the A-branch does not contain the ubiquinone Q(A); this facilitates the study of P(+)Q(B)(-) formation. Furthermore, the D mutation G(M203)D introduces an aspartic acid residue near B(A). Together these mutations impede electron transfer through the A-branch. The B-branch contains two bacteriopheophytins, Phi(B) and H(B), and a ubiquinone, Q(B.) Phi(B) replaces the monomer bacteriochlorophyll B(B) as a result of the L mutation H(M182)L. In the LDHW mutant we find 35-45% B-branch electron transfer, the highest yield reported so far. Transient absorption spectroscopy at 10 K, where the absorption bands due to the Q(X) transitions of Phi(B) and H(B) are well resolved, shows simultaneous bleachings of both absorption bands. Although photoreduction of the bacteriopheophytins occurs with a high yield, no significant (approximately 1%) P(+)Q(B)(-) formation was found.     

Elucidation of a monovalent cation dependence and characterization of the divalent cation binding site of the fosfomycin resistance protein (FosA).

The fosfomycin resistance protein FosA is a member of a distinct superfamily of metalloenzymes containing glyoxalase I, extradiol dioxygenases, and methylmalonyl-CoA epimerase. The dimeric enzyme, with the aid of a single mononuclear Mn2+ site in each subunit, catalyzes the addition of glutathione (GSH) to the oxirane ring of the antibiotic, rendering it inactive. Sequence alignments suggest that the metal binding site of FosA is composed of three residues: H7, H67, and E113. The single mutants H7A, H67A, and E113A as well as the more conservative mutants H7Q, H67Q, and E113Q exhibit marked decreases in the ability to bind Mn2+ and, in most instances, decreases in catalytic efficiency and the ability to confer resistance to the antibiotic. The enzyme also requires the monovalent cation K+ for optimal activity. The K+ ion activates the enzyme 100-fold with an activation constant of 6 mM, well below the physiologic concentration of K+ in E. coli. K+ can be replaced by other monovalent cations of similar ionic radii. Several lines of evidence suggest that the K+ ion interacts directly with the active site. Interaction of the enzyme with K+ is found to be dependent on the presence of the substrate fosfomycin. Moreover, the E113Q mutant exhibits a kcat which is 40% that of wild-type in the absence of K+. This mutant is not activated by monovalent cations. The behavior of the E113Q mutant is consistent with the proposition that the K+ ion helps balance the charge at the metal center, further lowering the activation barrier for addition of the anionic nucleophile. The fully activated, native enzyme provides a rate acceleration of >10(15) with respect to the spontaneous addition of GSH to the oxirane.     

Kinetic and allosteric consequences of mutations in the subunit and domain interfaces and the allosteric site of yeast pyruvate kinase.

The mechanism by which pyruvate kinase (PK) is allosterically activated by fructose-1,6-bisphosphate (FBP) is poorly understood. To identify residues key to allostery of yeast PK, a point mutation strategy was used. T403E and R459Q mutations in the FBP binding site caused reduced FBP affinity. Introducing positive charges at the 403, 458, and 406 positions in the FBP binding site had little consequence. The mutation Q299N in the A [bond] A subunit interface caused the enzyme response to ADP to be sensitive to FBP. The T311M A [bond] A interface mutant has a decreased affinity for PEP and FBP, and is dependent on FBP for activity. The R369A mutation in the C [bond] C interface only moderately influenced allostery. Creating an E392A mutation in the C [bond] C subunit interface eliminated all cooperativity and allosteric regulation. None of the seven A [bond] C domain interface mutations altered allostery. A model that includes a central role for E392 in allosteric regulation of yeast PK is proposed.     

Conformational change opening the CFTR chloride channel pore coupled to ATP-dependent gating

Opening and closing of the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel are controlled by ATP binding and hydrolysis by its nucleotide binding domains (NBDs). This is presumed to control opening of a single "gate" within the permeation pathway, however, the location of such a gate has not been described. We used patch clamp recording to monitor access of cytosolic cysteine reactive reagents to cysteines introduced into different transmembrane (TM) regions in a cysteine-less form of CFTR. The rate of modification of Q98C (TM1) and I344C (TM6) by both [2-sulfonatoethyl] methanethiosulfonate (MTSES) and permeant Au(CN)(2)(-) ions was reduced when ATP concentration was reduced from 1mM to 10μM, and modification by MTSES was accelerated when 2mM pyrophosphate was applied to prevent channel closure. Modification of K95C (TM1) and V345C (TM6) was not affected by these manoeuvres. We also manipulated gating by introducing the mutations K464A (in NBD1) and E1371Q (in NBD2). The rate of modification of Q98C and I344C by both MTSES and Au(CN)(2)(-) was decreased by K464A and increased by E1371Q, whereas modification of K95C and V345C was not affected. These results suggest that access from the cytoplasm to K95 and V345 is similar in open and closed channels. In contrast, modifying ATP-dependent channel gating alters access to Q98 and I344, located further into the pore. We propose that ATP-dependent gating of CFTR is associated with the opening and closing of a gate within the permeation pathway at the level of these pore-lining amino acids.     

A molecular design that stabilizes active state in bacterial allosteric L-lactate dehydrogenases

l-Lactate dehydrogenase (l-LDH) of Lactobacillus casei (LCLDH) is a typical bacterial allosteric l-LDH that requires fructose 1,6-bisphosphate (FBP) for its enzyme activity. A mutant LCLDH was designed to introduce an inter-subunit salt bridge network at the Q-axis subunit interface, mimicking Lactobacillus pentosus non-allosteric l-LDH (LPLDH). The mutant LCLDH exhibited high catalytic activity with hyperbolic pyruvate saturation curves independently of FBP, and virtually the equivalent K(m) and V(m) values at pH 5.0 to those of the fully activated wild-type enzyme with FBP, although the K(m) value was slightly improved with FBP or Mn(2+) at pH 7.0. The mutant enzyme exhibited a markedly higher apparent denaturating temperature (T(1/2)) than the wild-type enzyme in the presence of FBP, but showed an even lower T(1/2) without FBP, where it exhibited higher activation enthalpy of inactivation (ΔH(?)). This result is consistent with the fact that the active state is more unstable than the inactive state in allosteric equilibrium of LCLDH. The LPLDH-like network appears to be conserved in many bacterial non-allosteric l-LDHs and dimeric l-malate dehydrogenases, and thus to be a key for the functional divergence of bacterial l-LDHs during evolution.     

Quinone reduction via secondary B-branch electron transfer in mutant bacterial reaction centers

Symmetry-related branches of electron-transfer cofactors-initiating with a primary electron donor (P) and terminating in quinone acceptors (Q)-are common features of photosynthetic reaction centers (RC). Experimental observations show activity of only one of them-the A branch-in wild-type bacterial RCs. In a mutant RC, we now demonstrate that electron transfer can occur along the entire, normally inactive B-branch pathway to reduce the terminal acceptor Q(B) on the time scale of nanoseconds. The transmembrane charge-separated state P(+)Q(B)(-) is created in this manner in a Rhodobacter capsulatus RC containing the F(L181)Y-Y(M208)F-L(M212)H-W(M250)V mutations (YFHV). The W(M250)V mutation quantitatively blocks binding of Q(A), thereby eliminating Q(B) reduction via the normal A-branch pathway. Full occupancy of the Q(B) site by the native UQ(10) is ensured (without the necessity of reconstitution by exogenous quinone) by purification of RCs with the mild detergent, Deriphat 160-C. The lifetime of P(+)Q(B)(-) in the YFHV mutant RC is >6 s (at pH 8.0, 298 K). This charge-separated state is not formed upon addition of competitive inhibitors of Q(B) binding (terbutryn or stigmatellin). Furthermore, this lifetime is much longer than the value of approximately 1-1.5 s found when P(+)Q(B)(-) is produced in the wild-type RC by A-side activity alone. Collectively, these results demonstrate that P(+)Q(B)(-) is formed solely by activity of the B-branch carriers in the YFHV RC. In comparison, P(+)Q(B)(-) can form by either the A or B branches in the YFH RC, as indicated by the biexponential lifetimes of approximately 1 and approximately 6-10 s. These findings suggest that P(+)Q(B)(-) states formed via the two branches are distinct and that P(+)Q(B)(-) formed by the B side does not decay via the normal (indirect) pathway that utilizes the A-side cofactors when present. These differences may report on structural and energetic factors that further distinguish the functional asymmetry of the two cofactor branches.     

Expression and characterization of Lactobacillus 30a histidine decarboxylase in Escherichia coli

The genes coding for histidine decarboxylase from a wild-type strain and an autoactivation mutant strain of Lactobacillus 30a have been cloned and expressed in Escherichia coli. The mutant protein, G58D, has a single Asp for Gly substitution at position 58. The cloned genes were placed under control of the beta-galactosidase promoter and the products are natural length, not fusion proteins. The enzyme kinetics of the proteins isolated from E. coli are comparable to those isolated from Lactobacillus 30a. At pH 4.8 the Km of wild-type enzyme is 0.4 mM and the kcat = 2800 min-1; the corresponding values for G58D are 0.5 mM and 2750 min-1. The wild-type and G58D have autoactivation half-times of 21 and 9 h respectively under pseudophysiological conditions of 150 mM K+ and pH 7.0. At pH 7.6 and 0.8 M K+ the half-times are 4.9 and 2.9 h. The relatively slow rate of autoactivation for purified protein and the differences in cellular and non-cellular activation rates, coupled with the fact that wild-type protein is readily activated in wild-type Lactobacillus 30a but poorly activated in E. coli, suggest that wild-type Lactobacillus 30a contains a factor, possibly an enzyme, that enhances the activation rate.     

Determinants of allosteric activation of yeast pyruvate kinase and identification of novel effectors using computational screening

We have analyzed the structural determinants of the allosteric activation of yeast pyruvate kinase (YPK) by mutational and kinetic analysis and initiated a structure-based design project to identify novel effectors that modulate its allosteric response by binding to the allosteric site for fructose-1,6-bisphosphate (FBP). The wild-type enzyme is strongly activated by fructose-1,6-bisphosphate and weakly activated by both fructose-1-phosphate and fructose-6-phosphate; the strength of the activation response is proportional to the affinity of the allosteric effector. A point mutation within the 6'-phosphate binding loop of the allosteric site (T403E) abolishes activation of the enzyme by fructose-1, 6-bisphosphate. The mutant enzyme is also not activated by F1P or F6P. The mutation alone (which incorporates a glutamic acid that is strictly conserved in mammalian M1 isozymes) slightly reduces cooperativity of substrate binding. Three novel compounds were identified that effect the allosteric regulation of YPK by FBP and/or act as novel allosteric activators of the enzyme. One is a physiologically important diphospho sugar, while the other two are hydrophobic compounds that are dissimilar to the natural effector. These results demonstrate that novel allosteric effectors may be identified using structure-based screening and are indicative of the potential of this strategy for drug discovery. Regulatory sites are generally more divergent than catalytic sites and therefore offer excellent opportunities for discrimination and specificity between different organisms or between different tissue types.     

An unusual fructose 1,6-bisphosphate-activated lactate dehydrogenase from the ascidian Pyura stolonifera

Lactate dehydrogenase (LDH) was purified from the siphon muscle of the intertidal ascidian Pyura stolonifera. The enzyme is unique among chordate LDHs but resembles some bacterial and platyhelminth LDHs in being activated by fructose 1,6-bisphosphate (FBP). Concentrations of FBP in the range 5μM to 0.5 mM increase V_max of the pyruvate reductase reaction by 130% to 210%, and decrease K_m pyruvate 5 to 11 fold and K_m NADH 2.5 to 5 fold. The enzyme is also activated by inorganic phosphate, but requires a 50 fold higher concentration to attain the maximum activation achieved by 0.5 mM FBP. Of a range of metabolites tested, including other glycolytic sugar phosphates, only FBP and inorganic phosphate activated the enzyme. FBP activation was not observed with 16 representative vertebrate LDH homotetramers, but did occur to a limited extent with LDH from an echinoderm. LDH was the only pyruvate reductase enzyme detected in P. stolonifera siphon muscle, and its activity was much greater than that of phosphorylase or phosphofructokinase. The LDH reaction is utilized by P. Stolonifera during prolonged siphon closure on exposure to air when lactate, but not succinate, accumulates in the siphon muscle. While the ascidian enzyme provides the first example of a FBP activated LDH from a chordate, it remains to be determined if this unusual property has any role in metabolic regulation.     

Characterization of the bonding interactions of Q(B) upon photoreduction via A-branch or B-branch electron transfer in mutant reaction centers from Rhodobacter sphaeroides

In Rhodobacter sphaeroides reaction centers (RCs) containing the mutation Ala M260 to Trp (AM260W), transmembrane electron transfer along the full-length of the A-branch of cofactors is prevented by the loss of the Q(A) ubiquinone, but it is possible to generate the radical pair P(+)H(A)(-) by A-branch electron transfer or the radical pair P(+)Q(B)(-) by B-branch electron transfer. In the present study, FTIR spectroscopy was used to provide direct evidence for the complete absence of the Q(A) ubiquinone in mutant RCs with the AM260W mutation. Light-induced FTIR difference spectroscopy of isolated RCs was also used to probe the neutral Q(B) and the semiquinone Q(B)(-) states in two B-branch active mutants, a double AM260W-LM214H mutant, denoted WH, and a quadruple mutant, denoted WAAH, in which the AM260W, LM214H, and EL212A-DL213A mutations were combined. The data were compared to those obtained with wild-type (Wt) RCs and the double EL212A-DL213A (denoted AA) mutant which exhibit the usual A-branch electron transfer to Q(B). The Q(B)(-)/Q(B) spectrum of the WH mutant is very close to that of Wt RCs indicating similar bonding interactions of Q(B) and Q(B)(-) with the protein in both RCs. The Q(B)(-)/Q(B) spectra of the AA and WAAH mutants are also closely related to one another, but are very different to that of the Wt complex. Isotope-edited IR fingerprint spectra were obtained for the AA and WAAH mutants reconstituted with site-specific (13)C-labeled ubiquinone. Whilst perturbations of the interactions of the semiquinone Q(B)(-) with the protein are observed in the AA and WAAH mutants, the FTIR data show that the bonding interaction of neutral Q(B) in these two mutants are essentially the same as those for Wt RCs. Therefore, it is concluded that Q(B) occupies the same binding position proximal to the non-heme iron prior to reduction by either A-branch or B-branch electron transfer.     

Dominant negative role of the glutamic acid residue conserved in the pyruvate kinase M(1) isozyme in the heterotropic allosteric effect involving fructose-1,6-bisphosphate

Pyruvate kinase M(1), a nonallosteric isozyme, lacks heterotropic allosteric effect involving fructose-1,6-bisphosphate (FBP). To explore the molecular basis for this, a series of mutants were prepared and characterized, in which the possible candidate, Glu-432, was replaced in the rat M(1) isozyme and its allosteric mutant with the replacement of Ala-398 by Arg. Although these single mutants of Glu-432 remained nearly fully active, similar to the wild type, only the mutants with replacements by Lys and Ala were more efficiently activated by FBP when the enzymes were inhibited by L-phenylalanine. Kinetic analyses and ligand-induced fluorescence quenching studies using the allosteric double mutants indicated that the loss of a negative charge at residue 432 led to a dramatic decrease in the apparent activation constant and apparent K(d) for FBP. Furthermore, this enhancement was found to be associated with the modification of the FBP-binding site rather than the alteration of the subunit assembly. These findings suggest that Glu-432 hinders the heterotropic allosteric effect by preventing the binding of FBP through a repulsive electrostatic interaction and thereby contributes to its unique unregulated properties, independent of the shifted allosteric transition.     

Quaternary organic amines inhibit Na,K pump current in a voltage-dependent manner: direct evidence of an extracellular access channel in the Na,K-ATPase

The effects of organic quaternary amines, tetraethylammonium (TEA) chloride and benzyltriethylammonium (BTEA) chloride, on Na,K pump current were examined in rat cardiac myocytes superfused in extracellular Na(+)-free solutions and whole-cell voltage-clamped with patch electrodes containing a high Na(+)-salt solution. Extracellular application of these quaternary amines competitively inhibited extracellular K(+) (K(+)(o)) activation of Na,K pump current; however, the concentration for half maximal inhibition of Na,K pump current at 0 mV (K(0)(Q)) by BTEA, 4.0 +/- 0.3 mM, was much lower than the K(0)(Q) for TEA, 26.6 +/- 0.7 mM. Even so, the fraction of the membrane electric field dissipated during K(+)(o) activation of Na,K pump current (lambda(K)), 39 +/- 1%, was similar to lambda(K) determined in the presence of TEA (37 +/- 2%) and BTEA (35 +/- 2%), an indication that the membrane potential (V(M)) dependence for K(+)(o) activation of the Na,K pump current was unaffected by TEA and BTEA. TEA was found to inhibit the Na,K pump current in a V(M)-independent manner, i.e., inhibition of current dissipated 4 +/- 2% of the membrane electric field. In contrast, BTEA dissipated 40 +/- 5% of the membrane electric field during inhibition of Na,K pump current. Thus, BTEA inhibition of the Na,K-ATPase is V(M)-dependent. The competitive nature of inhibition as well as the similar fractions of the membrane electric field dissipated during K(+)(o)-dependent activation and BTEA-dependent inhibition of Na,K pump current suggest that BTEA inhibits the Na,K-ATPase at or very near the enzyme's K(+)(o) binding site(s) located in the membrane electric field. Given previous findings that organic quaternary amines are not occluded by the Na,K-ATPase, these data clearly demonstrate that an ion channel-like structure provides access to K(+)(o) binding sites in the enzyme.     

Fluorescence studies of ligand-induced conformational changes of the Na(+)/glucose cotransporter.

Conformational changes in the human Na(+)/glucose cotransporter (hSGLT1) were examined using hSGLT1 Q457C expressed in Xenopus laevis oocytes and tagged with tetramethylrhodamine-6-maleimide (TMR6M). Na(+)/glucose cotransport is abolished in the TMR6M-labeled mutant, but the protein binds Na(+) and sugar [Loo et al. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 7789-7794]. Under voltage clamp the fluorescence of labeled Q457C was dependent on external cations. Increasing [Na(+)] increased fluorescence with a Hill coefficient of 2 and half-maximal concentration (K(Na)(0.5)) of 49 mM at -90 mV. Li(+) also increased fluorescence, whereas choline, tetraethylammonium, and N-methyl-D-glucamine did not. Fluorescence was increased by sugars with specificity: methyl alpha-D-glucopyranoside > D-glucose > D-galactose > D-mannitol. Voltage-jump experiments (in 100 mM NaCl buffer in absence of sugar) elicited parallel changes in pre-steady-state charge movement and fluorescence. Charge vs voltage and fluorescence vs voltage curves followed Boltzmann relations with the same median voltage (V(0.5) = -50 mV), but the apparent valence was 1 for charge movement and 0.4 for fluorescence. V(0.5) for fluorescence and charge movement was shifted by -100 mV per 10-fold decrease in [Na(+)]. Under Na(+)-free conditions, there was a voltage-dependent change in fluorescence. Voltage-jump experiments showed that the maximal change in fluorescence increased 20% with sugar. These results indicate that Na(+), sugar, and membrane voltage change the local environment of the fluorophore at Q457C. Our interpretation of these results is (1) the conformational change of the empty transporter is voltage dependent, (2) two Na(+) ions can bind cooperatively to the protein before sugar, and (3) sugar binding induces a conformational change.     

Identification of the proton pathway in bacterial reaction centers: decrease of proton transfer rate by mutation of surface histidines at H126 and H128 and chemical rescue by imidazole identifies the initial proton donors.

The pathway for proton transfer to Q(B) was studied in the reaction center (RC) from Rhodobacter sphaeroides. The binding of Zn(2+) or Cd(2+) to the RC surface at His-H126, His-H128, and Asp-H124 inhibits the rate of proton transfer to Q(B), suggesting that the His may be important for proton transfer [Paddock, M. L., Graige, M. S., Feher, G. and Okamura, M. Y. (1999) Proc. Natl. Acad. Sci. U.S.A. 96, 6183-6188]. To assess directly the role of the histidines, mutant RCs were constructed in which either one or both His were replaced with Ala. In the single His mutant RCs, no significant effects were observed. In contrast, in the double mutant RC at pH 8.5, the observed rates of proton uptake associated with both the first and the second proton-coupled electron-transfer reactions k(AB)(()(1)()) [Q(A)(-)(*)Q(B)-Glu(-) + H(+) --> Q(A)(-)(*)Q(B)-GluH --> Q(A)Q(B)(-)(*)-GluH] and k(AB)(()(2)()) [Q(A)(-)(*)Q(B)(-)(*) + H(+) --> Q(A)(-)(*)(Q(B)H)(*) --> Q(A)(Q(B)H)(-)], were found to be slowed by factors of approximately 10 and approximately 4, respectively. Evidence that the observed changes in the double mutant RC are due to a reduction in the proton-transfer rate constants are provided by the observations: (i) k(AB)(1) at pH approximately pK(a) of GluH became biphasic, indicating that proton transfer is slower than electron transfer and (ii) k(AB)(2) became independent of the driving force for electron transfer, indicating that proton transfer is the rate-limiting step. These changes were overcome by the addition of exogenous imidazole which acts as a proton donor in place of the imidazole groups of His that were removed in the double mutant RC. Thus, we conclude that His-H126 and His-H128 facilitate proton transfer into the RC, acting as RC-bound proton donors at the entrance of the proton-transfer pathways.     

Lysine 5 and phenylalanine 9 of the factor IX omega-loop interact with phosphatidylserine in a membrane-mimetic environment

The binding of factor IX to cell membranes requires a structured N-terminal omega-loop conformation that exposes hydrophobic residues for a highly regulated interaction with a phospholipid. We hypothesized that a peptide comprised of amino acids Gly4-Gln11 of factor IX (fIX(G4)(-)(Q11)) and constrained by an engineered disulfide bond would assume the native factor IX omega-loop conformation in the absence of Ca(2+). The small size and freedom from aggregation-inducing calcium interactions would make fIX(G4)(-)(Q11) suitable for structural studies for eliciting details about phospholipid interactions. fIX(G4)(-)(Q11) competes with factor IXa for binding sites on phosphatidylserine-containing membranes with a K(i) of 11 microM and inhibits the activation of factor X by the factor VIIIa-IXa complex with a K(i) of 285 microM. The NMR structure of fIX(G4)(-)(Q11) reveals an omega-loop backbone fold and side chain orientation similar to those found in the calcium-bound factor IX Gla domain, FIX(1-47)-Ca(2+). Dicaproylphosphatidylserine (C(6)PS) induces HN, Halpha backbone, and Hbeta chemical shift perturbations at residues Lys5, Leu6, Phe9, and Val10 of fIX(G4)(-)(Q11), while selectively protecting the NHzeta side chain resonance of Lys5 from solvent exchange. NOEs between the aromatic ring protons of Phe9 and specific acyl chain protons of C(6)PS indicate that these phosphatidylserine protons reside 3-6 A from Phe9. Stabilization of the phosphoserine headgroup and glycerol backbone of C(6)PS identifies that phosphatidylserine is in a protected environment that is spatially juxtaposed with fIX(G4)(-)(Q11). Together, these data demonstrate that Lys5, Leu6, Phe9, and Val10 preferentially interact with C(6)PS and allow us to correlate known hemophilia B mutations of factor IX at Lys5 or Phe9 with impaired phosphatidylserine interaction.     

Phosphatidylglycerol requirement for the function of electron acceptor plastoquinone Q(B) in the photosystem II reaction center

Phosphatidylglycerol (PG), a ubiquitous constituent of thylakoid membranes of chloroplasts and cyanobacteria, is demonstrated to be essential for the functionality of plastoquinone electron acceptor Q(B) in the photosystem II reaction center of oxygenic photosynthesis. Growth of the pgsA mutant cells of Synechocystis sp. PCC6803 that are defective in phosphatidylglycerolphosphate synthase and are incapable of synthesizing PG, in a medium without PG, resulted in a 90% decrease in PG content and a 50% loss of photosynthetic oxygen-evolving activity as reported [Hagio, M., Gombos, Z., Várkonyi, Z., Masamoto, K., Sato, N., Tsuzuki, M., and Wada, H. (2000) Plant Physiol. 124, 795-804]. We have studied each step of the electron transport in photosystem II of the pgsA mutant to clarify the functional site of PG. Accumulation of Q(A)(-) was indicated by the fast rise of chlorophyll fluorescence yield under continuous and flash illumination. Oxidation of Q(A)(-) by Q(B) plastoquinone was shown to become slow, and Q(A)(-) reoxidation required a few seconds when measured by double flash fluorescence measurements. Thermoluminescence measurements further indicated the accumulation of the S(2)Q(A)(-) state but not of the S(2)Q(B)(-) state following the PG deprivation. These results suggest that the function of Q(B) plastoquinone was inactivated by the PG deprivation. We assume that PG is an indispensable component of the photosystem II reaction center complex to maintain the structural integrity of the Q(B)-binding site. These findings provide the first clear identification of a specific functional site of PG in the photosynthetic reaction center.     

The role of glutamic acid-69 in the activation of Citrobacter freundii tyrosine phenol-lyase by monovalent cations

Tyrosine phenol-lyase (TPL) from Citrobacter freundii is activated about 30-fold by monovalent cations, the most effective being K(+), NH(4)(+), and Rb(+). Previous X-ray crystal structure analysis has demonstrated that the monovalent cation binding site is located at the interface between subunits, with ligands contributed by the carbonyl oxygens of Gly52 and Asn262 from one chain and monodentate ligation by one of the epsilon-oxygens of Glu69 from another chain [Antson, A. A., Demidkina, T. V., Gollnick, P., Dauter, Z., Von Tersch, R. L., Long, J., Berezhnoy, S. N., Phillips, R. S., Harutyunyan, E. H., and Wilson, K. S. (1993) Biochemistry 32, 4195]. We have studied the effect of mutation of Glu69 to glutamine (E69Q) and aspartate (E69D) to determine the role of Glu69 in the activation of TPL. E69Q TPL is activated by K(+), NH(4)(+), and Rb(+), with K(D) values similar to wild-type TPL, indicating that the negative charge on Glu69 is not necessary for cation binding and activation. In contrast, E69D TPL exhibits very low basal activity and only weak activation by monovalent cations, even though monovalent cations are capable of binding, indicating that the geometry of the monovalent cation binding site is critical for activation. Rapid-scanning stopped-flow kinetic studies of wild-type TPL show that the activating effect of the cation is seen in an acceleration of rates of quinonoid intermediate formation (30-50-fold) and of phenol elimination. Similar rapid-scanning stopped-flow results were obtained with E69Q TPL; however, E69D TPL shows only a 4-fold increase in the rate of quinonoid intermediate formation with K(+). Preincubation of TPL with monovalent cations is necessary to observe the rate acceleration in stopped flow kinetic experiments, suggesting that the activation of TPL by monovalent cations is a slow process. In agreement with this conclusion, a slow increase (k < 0.5 s(-)(1)) in fluorescence intensity (lambda(ex) = 420 nm, lambda(em) = 505 nm) is observed when wild-type and E69Q TPL are mixed with K(+), Rb(+), and NH(4)(+) but not Li(+) or Na(+). E69D TPL shows no change in fluorescence under these conditions. High concentrations (>100 mM) of all monovalent cations result in inhibition of wild-type TPL. This inhibition is probably due to cation binding to the ES complex to form a complex that releases pyruvate slowly.     

Activation of NF-kappa B by bradykinin through a Galpha(q)- and Gbeta gamma-dependent pathway that involves phosphoinositide 3-kinase and Akt

Recent work has suggested a role for the serine/threonine kinase Akt and IkappaB kinases (IKKs) in nuclear factor (NF)-kappaB activation. In this study, the involvement of these components in NF-kappaB activation through a G protein-coupled pathway was examined using transfected HeLa cells that express the B2-type bradykinin (BK) receptor. The function of IKK2, and to a lesser extent, IKK1, was suggested by BK-induced activation of their kinase activities and by the ability of their dominant negative mutants to inhibit BK-induced NF-kappaB activation. BK-induced NF-kappaB activation and IKK2 activity were markedly inhibited by RGS3T, a regulator of G protein signaling that inhibits Galpha(q), and by two Gbetagamma scavengers. Co-expression of Galpha(q) potentiated BK-induced NF-kappaB activation, whereas co-expression of either an activated Galpha(q)(Q209L) or Gbeta(1)gamma(2) induced IKK2 activity and NF-kappaB activation without BK stimulation. BK-induced NF-kappaB activation was partially blocked by LY294002 and by a dominant negative mutant of phosphoinositide 3-kinase (PI3K), suggesting that PI3K is a downstream effector of Galpha(q) and Gbeta(1)gamma(2) for NF-kappaB activation. Furthermore, BK could activate the PI3K downstream kinase Akt, whereas a catalytically inactive mutant of Akt inhibited BK-induced NF-kappaB activation. Taken together, these findings suggest that BK utilizes a signaling pathway that involves Galpha(q), Gbeta(1)gamma(2), PI3K, Akt, and IKK for NF-kappaB activation.     

A conformation-specific interhelical salt bridge in the K+ binding site of gastric H,K-ATPase

Homology modeling of gastric H,K-ATPase based on the E2 model of sarcoplasmic reticulum Ca2+-ATPase (Toyoshima, C., and Nomura, H. (2002) Nature 392, 835-839) revealed the presence of a single high-affinity binding site for K+ and an E2 form-specific salt bridge between Glu820 (M6) and Lys791 (M5). In the E820Q mutant this salt bridge is no longer possible, and the head group of Lys791, together with a water molecule, fills the position of the K+ ion and apparently mimics the K+-filled cation binding pocket. This gives an explanation for the K+-independent ATPase activity and dephosphorylation step of the E820Q mutant (Swarts, H. G. P., Hermsen, H. P. H., Koenderink, J. B., Schuurmans Stekhoven, F. M. A. H., and De Pont, J. J. H. H. M. (1998) EMBO J. 17, 3029-3035) and, indirectly, for its E1 preference. The model is strongly supported by a series of reported mutagenesis studies on charged and polar amino acid residues in the membrane domain. To further test this model, Lys791 was mutated alone and in combination with other crucial residues. In the K791A mutant, the K+ affinity was markedly reduced without altering the E2 preference of the enzyme. The K791A mutation prevented, in contrast to the K791R mutation, the spontaneous dephosphorylation of the E820Q mutant as well as its conformational equilibrium change toward E1. This indicates that the salt bridge is essential for high-affinity K+ binding and the E2 preference of H,K-ATPase. Moreover, its breakage (E820Q) can generate a K+-insensitive activity and an E1 preference. In addition, the study gives a molecular explanation for the electroneutrality of H,K-ATPases.