Kinetic studies on partially liganded species of carboxyhemoglobin: alpha 2 CO beta 2 and alpha 2 beta 2CO

The valency hybrids of Hb A, alpha 2CO beta 2+, and alpha 2+ beta 2CO have been prepared by a new high pressure liquid chromatography method, and the kinetics of their CO-combination and dissociation reactions have been studied by double mixing and microperoxidase methods. Both reactions are biphasic. The slow phase in CO-combination and the fast phase in CO-dissociation are due to the reactions of alpha CO2 beta T2 or alpha 2 beta 2CO,T. The fast phase in CO-combination reaction has two components, one due to the dimers of the hybrid and the other due to the R-state tetramer. Immediately after the reduction of the valency hybrids, the overall system is represented by the equation: 2 alpha CO beta in equilibrium alpha 2CO beta 2R in equilibrium alpha 2CO beta 2T or (formula: see text) If the solutions are aged for 3-11 s, the R-state population is reduced gradually to a very small size, and the main species after 11 s of aging are dimers and T-state tetramers. Analysis of the kinetic data indicates slow R in equilibrium T equilibria in the absence of phosphates and significant dissociation of the T-state tetramer. It is concluded that the subunit contacts alpha 1-beta 2 (or alpha 2-beta 1) are impaired seriously in the hybrids. Very slow R in equilibrium T relaxation makes these hybrids unlikely intermediates in the sequential binding of CO to Hb tetramer.     

Quaternary structure and geminate recombination in hemoglobin: flow-flash studies on alpha 2CO beta 2 and alpha 2 beta 2CO.

The kinetics of geminate recombination for the diliganded species alpha 2CO beta 2 and alpha 2 beta 2CO of human hemoglobin were studied using flash photolysis. The unstable diliganded species were generated just before photolysis by chemical reduction in a continuous flow reactor from the more stable valency hybrids alpha 2CO beta 2+ and alpha 2+ beta 2CO, which could be prepared by high pressure liquid chromatography. Before the flash photolysis studies, the hybrids had been characterized by double-mixing stopped-flow kinetics experiments. At pH 6.0 in the presence of inositol hexaphosphate (IHP) both of the diliganded species show second order kinetics for overall addition of a third CO that is clearly characteristic of the T state (l' = 1-2 x 10(5) M-1 s-1), whereas at higher pH and in the absence of IHP they show combination rates characteristic of an R state. The kinetics of geminate recombination following photolysis of a bound CO, however, showed little dependence on pH and IHP concentration. This surprising observation is explained on the basis that the kinetics of geminate recombination of CO primarily depends on the tertiary structure of the ligand binding site, which apparently does not differ much between the R state and the liganded T state formed on adding IHP in this system. Since this explanation requires distinguishing different tertiary structures within a particular quaternary structure, it amounts to a contradiction to the two-state allosteric model.     

Double-mixing kinetic studies of the reactions of monoliganded species of hemoglobin: alpha 2(CO)1 beta 2 and alpha 2 beta 2(CO)1.

The kinetics of CO association to and dissociation from the two isomers of monoliganded species alpha ICO beta I(alpha II beta II) and alpha I beta I (alpha II beta COII) has been studied by double-mixing stopped-flow and microperoxidase methods. The monoliganded species were generated by hybridization between excess ferric Hb and alpha CO2 beta +2 or alpha +2 beta CO2 prepared by high-pressure liquid chromatography (HPLC). The results indicated that: 1) there were no significant differences in the reactivities of alpha and beta chains in the first step of ligation; 2) in the second step of ligation there was significant cooperativity in the reaction of deoxyhemoglobin with 0.05 or 0.1 equivalent of CO. Diliganded species were therefore formed in significant amounts. The double-mixing HPLC results suggested that in the second step of ligation alpha chains reacted faster than the beta chains, and the main diliganded species formed was alpha I beta ICO (alpha IICO beta II) or its isomer alpha ICO I(alpha II beta IICO). These results seem to indicate that the reaction of the first CO is mostly random and in the second step of ligation CO binds more to the tetramers in which one beta chain is already ligated: alpha I beta I (alpha II beta II) + CO----alpha ICO beta I (alpha II beta II) and alpha I beta ICO (alpha II beta II) + CO----alpha I beta ICO (alpha IICO beta II).     

Kinetic studies on partially liganded species of carboxyhemoglobin: (alpha 1CO-beta 1CO)alpha 2 beta 2 or (alpha 2CO beta 2CO)alpha 1 beta 1

Kinetics of CO combination with and dissociation from isomer III, (alpha 1CO beta 1CO)alpha 2 beta 2 or alpha 1 beta 1 (alpha 2CO beta 2CO), and Hb Rothschild have been studied using the double mixing and microperoxidase methods. Isomer III was prepared in a manner so that it was the only reactive species in the reaction mixture. The biphasic reaction time course in both the "on" and "off" reactions of isomer III and the CO combination reaction of Hb Rothschild are attributed to slow relaxation between the fast and slow CO-reacting species in the two proteins: isomer III: l'f = 6 x 10(6) M-1 s-1, l'dimer = 1.7 x 10(6) M-1 s-1, l's = 2.2 x 10(5) M-1 s-1, lf = 0.15 s-1, ls = 0.01 s-1; Hb Rothschild: l'f = 2.8 x 10(6) M-1 s-1; l's = 2.7 x 10(5) M-1 s-1.     

The dissociation of carbon monoxide from hemoglobin intermediate

To investigate the mechanism of allosteric switching in human hemoglobin, we have studied the dissociation of the ligand (CO) from several intermediate ligation states by a stopped-flow kinetic technique that utilizes competitive binding of CO by microperoxidase. The hemoglobin species investigated include Hb(CO)4, the diliganded symmetrical species (alpha beta-CO)2 and (alpha-CO beta)2, and the di- and monoliganded asymmetrical species (alpha-CO beta-CO)(alpha beta), (alpha-CO beta)(alpha beta-CO), (alpha beta-CO) (alpha beta), and (alpha-CO beta)(alpha beta). They were obtained by rapid reduction with dithionite of the corresponding valence intermediates that in turn were obtained by chromatography or by hybridization. The nature and concentration of the intermediates were determined by isoelectric focusing at -25 degrees C. The study was performed at varying hemoglobin concentrations (0.1, 0.02, and 0.001 mM [heme]), pH (6.0, 7.0, 8.0), with and without inositol hexaphosphate. The results indicate that: (a) hemoglobin concentration in the 0.1-0.02 mM range does not significantly affect the kinetic rates; (b) the alpha chains dissociate CO faster than the beta chains; (c) the symmetrical diliganded intermediates show cooperativity with respect to ligand dissociation that disappears in the presence of inositol hexaphosphate; (d) the monoliganded intermediates dissociate CO faster than the diliganded intermediates; (e) the asymmetrical diliganded intermediates are functionally different from the symmetrical species.     

Differences in local conformation around cysteine residues in alpha alpha, alpha beta, and beta beta rabbit skeletal tropomyosin

The ability of 5,5'-dithiobis-2-nitrobenzoate (Nbs2) to form a disulfide crosslink between the Cys-190s of the alpha alpha and alpha beta molecular components of rabbit skeletal tropomyosin (Tm) and the Cys-36s and Cys-190s of purified beta beta was studied in separate experiments, as a function of urea concentration in 0.5 M NaCl, 20 mM 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid, pH 7.4, 15 degrees C. In the absence of urea, complete reaction of the Cys-190s of Tm with Nbs2 as well as with 2- and 4-pyridine disulfide quantitatively produced two crosslinked species, alpha-alpha and alpha-beta, in a 60/40 ratio, respectively, visualized as bands on sodium dodecyl sulfate-polyacrylamide gels; similar reactions of beta beta produced both doubly (at Cys-36 and Cys-190) and singly crosslinked species (at Cys-190 as identified by amino acid analysis of separated tryptic peptides). In the presence of 4 M urea where the chains were unfolded and separated, only Nbs-blocked uncrosslinked species were obtained after complete reaction with Nbs2. The loss of Nbs2-crosslinking at increasing [urea] showed that the relative stability of the Cys-containing regions of the three species of Tm, alpha alpha, alpha beta, and beta beta increases in the order Cys-36 of beta beta, Cys-190 of alpha beta, Cys-190 of alpha alpha.     

Ligand binding to symmetrical FeZn hybrids of variants of human HbA with modifications in the alpha1-beta2 interface

The equilibria of oxygen binding to and kinetics of CO combination with the symmetrical iron-zinc hybrids of a series of variants of human adult hemoglobin A have been measured at pH 7 in the presence of inositol hexaphosphate (IHP). In addition, the kinetics of CO combination have also been measured in the absence of IHP. The hybrids have the heme groups of either the alpha or the beta subunits replaced by zinc protoporphyrin IX, which is unable to bind a ligand and is a good model for permanently deoxygenated heme. The variants examined involve residues located in the alpha1beta2 interface of the hemoglobin tetramer. Alterations of residues located in the hinge region of the interface are found to affect the properties of both the alpha and the beta subunits of the protein. In contrast, alterations of residues in the switch region of the interface have substantial effects only on the mutant subunit and are poorly communicated to the normal partner subunit. When the logarithms of the rate constants for the combination of the first CO molecule with a single subunit in the presence of IHP are analyzed as functions of the logarithms of the dissociation equilibrium constants for the binding of the first oxygen under the same conditions, a linear relationship is found. The relationship is somewhat different for the alpha and beta subunits, consistent with the well-known differences in the geometries of their ligand binding sites.     

The effects of E7 and E11 mutations on the kinetics of ligand binding to R state human hemoglobin

Association and dissociation rate constants for O2, CO, and methyl isocyanide binding to native and distal pocket mutants of R state human hemoglobin were measured using ligand displacement and partial photolysis techniques. Individual rate constants for the alpha and beta subunits were resolved by comparisons between the kinetic behavior of the native and mutant proteins. His-E7 was replaced with Gly and Gln in both alpha and beta subunits and with Phe in beta subunits alone. In separate experiments Val-E11 was replaced with Ala, Leu, and Ile in each globin chain. The parameters describing ligand binding to R state alpha subunits are sensitive to the size and polarity of the amino acids at positions E7 and E11. The distal histidine in this subunit inhibits the bimolecular rate of binding of both O2 and CO, sterically hinders bound CO and methyl isocyanide, and stabilizes bound O2 by hydrogen bonding. The Val-E11 side chain in alpha chains also appears to be part of the kinetic barrier to O2 and CO binding since substitution with Ala causes approximately 10-fold increases in the association rate constants for the binding of these diatomic ligands. However, substitution of Val-E11 by Ile produces only small decreases in the rates of ligand binding to alpha subunits. For R state beta subunits, the bimolecular rates of O2 and CO binding are intrinsically large, approximately 2-5-fold greater than those for alpha subunits, and with the exception of Val-E11----Ile mutation, little affected by substitutions at either the E7 or E11 positions. For the beta Val-E11----Ile mutant the association rate and equilibrium constants for all three ligands decreased 10-50-fold. All of these results agree with Shaanan's conclusions that the distal pocket in liganded beta subunits is more open whereas in alpha subunits bound ligands are more sterically hindered by adjacent distal residues (Shaanan, B. (1983) J. Mol. Biol. 171, 31-59). In the case of O2 binding to alpha subunits, the unfavorable steric effects are compensated by the formation of a hydrogen bond between the nitrogen atom of His-E7 and bound dioxygen.     

Ligand recombination to the alpha and beta subunits of human hemoglobin

The rebinding of CO, O2, NO, methyl, ethyl, n-propyl, and n-butyl isocyanide to isolated alpha and beta chains and intact hemoglobin at pH 7, 20 degrees C was examined both during and after a 30-ns dye laser pulse. The resultant absorbance changes were analyzed in terms of a linear three-step reaction scheme: Hb + X in equilibrium with C in equilibrium with B in equilibrium with A or HbX, where A is the final bound state, and C and B are geminate states. Rate constants were assigned for each of the transitions in this mechanism using fitting procedures described previously for analyzing ligand rebinding to sperm whale myoglobin at room temperature (Gibson, Q. H., Olson, J. S., McKinnie, R. E., and Rohlfs, R. J. (1986) J. Biol. Chem. 261, 10228-10239). Five major conclusions were obtained. First, initial geminate recombination phases for the NO and O2 complexes of hemoglobin and its isolated subunits exhibit half-times equal to approximately 12 and approximately 440 ps, respectively. These values are in excellent agreement with more direct, picosecond measurements of the geminate recombination of HbNO (Cornelius, P. A., Hochstrasser, R. M., and Steele, A. W. (1983) J. Mol. Biol. 163, 119-128) and HbO2 (Friedman, J. M., Scott, T. W., Fisanick, G. J., Simon, S. R., Findsen, E. W., Ondrias, M. R., and MacDonald, V. W. (1985) Science 229, 187-229) following extremely short laser pulses. Second, the correspondence between our nanosecond measurements and the published picosecond data suggests strongly that the intrinsic photochemical yield of all ferrous, hexacoordinate heme complexes approaches one. Third, the major differences between the isolated alpha and beta chains involve the rate of ligand migration to the solvent, kC----X and the extent of recombination from the second geminate state, C, as measured by the ratio kC----B/kC----X. Fourth, for both isolated chains and intact hemoglobin, the rate and equilibrium constants for the formation of the initial O2 geminate state starting from ligand in the solvent (i.e. kX----B and KX----B) are 5-10 times greater than the corresponding parameters for the formation of the first CO geminate state. Fifth, the rate-limiting step for NO, O2, and isonitrile binding to hemoglobin and its isolated subunits is ligand migration up to the initial geminate state (i.e. kX----B). In the case of CO binding, both migration to state B and iron-ligand bond formation (kB----A) affect the overall, bimolecular association rate constant.     

The kinetics of chain exchange in two-chain coiled coils: alpha alpha- and beta beta-tropomyosin.

Measurements are presented on the time course of chain exchange among two-chain alpha-helical coiled coils of rabbit tropomyosin. All experiments are in a regime (temperature, protein concentration) in which coiled-coil dimers are the predominant species. Self-exchange in alpha alpha-tropomyosin was investigated by mixing alpha alpha species with alpha* alpha*, the asterisk designating an alpha-chain whose lone sulfhydryl (C190) has been blocked by carboxyamidomethylation. The overall process alpha alpha + alpha* alpha* in equilibrium with 2 alpha alpha* is followed by measurement of the fraction (h) of alpha alpha* species as a function of time. Similarly, self-exchange in beta beta-tropomyosin is examined by measurements of the overall process: beta beta + beta* beta* in equilibrium with 2 beta beta*, in which beta* signifies a beta-chain blocked at both sulfhydryls (C36 and C190). The observed time course for both chains is well fit by the first-order equation: h (t) = h (infinity) (1-e-k1t), with h (infinity) congruent to 0.5. This long-time limit is as expected for self-exchange, and agrees with experiments that attain equilibrium after slow cooling of thermally dissociated and unfolded chains. The simplest consonant mechanism is chain exchange by rate-limiting dissociation of dimers followed by random reassociation. Kinetic analysis shows k1 to be the rate constant for the chain dissociation step, a quantity not previously measured for any coiled coil. This rate constant for beta beta species is about an order of magnitude greater than for alpha alpha. In both, the activation enthalpy and entropy are very large, suggesting that activation to an extensively (greater than 50%) unfolded species necessarily precedes dissociation. Experiments are also reported for overall processes: alpha alpha + beta* beta* in equilibrium with 2 alpha beta* and alpha* alpha* + beta beta in equilibrium with 2 alpha* beta. Results are independent of which chain is blocked. Again h (infinity) congruent to 0.5, in agreement with equilibrium experiments, and the time course is first order. The rate constants and activation parameters are intermediate between those for self-exchange.     

Mutational effects at the subunit interfaces of human hemoglobin: evidence for a unique sensitivity of the T quaternary state to changes in the hinge region of the alpha 1 beta 2 interface

A set of variant human hemoglobins, each with an Ala or Gly substitution at a single residue, has been prepared, and the kinetics of their reactions with carbon monoxide have been measured. This reaction is rate-limited by the binding of the first CO to the deoxygenated T state of the protein. The magnitudes of the effects of the mutations on CO combination vary widely, and, with the exception of beta Y145, the residues with the most significant effects on these kinetics are found in the hinge region of the alpha 1 beta 2 interface. Mixed-metal hybrids, with zinc protoporphyrin IX in place of heme on both alpha or both beta subunits, were prepared for beta W37E, beta W37A, alpha Y140G, and alpha Y140A, hinge region variants causing large kinetic changes, and for beta Y145G. Such hybrids permit measurements of the kinetics of CO binding to only the heme-containing alpha or beta subunits within the unliganded hemoglobin tetramer. Mutations at beta 37 and alpha 140 have global effects on the T state, increasing the rates of CO binding to both types of subunits. Mutation of beta Y145 has a large effect on the beta subunits in the deoxygenated T state, but very little effect on the alpha subunits. Oxygen equilibria measurements on the crystalline T state of beta W37E also indicate large affinity increases in both subunits of this variant. The overall oxygen equilibria of the variant hemoglobins in solution are sensitive to numerous variables besides the properties of the deoxygenated T state. In contrast to CO combination kinetics, the residues whose alterations cause the largest changes in overall oxygen equilibria in solution are scattered seemingly randomly within the alpha 1 beta 2 interface.     

Site-directed mutations of human hemoglobin at residue 35beta: a residue at the intersection of the alpha1beta1, alpha1beta2, and alpha1alpha2 interfaces

Because Tyr35beta is located at the convergence of the alpha1beta1, alpha1beta2, and alpha1alpha2 interfaces in deoxyhemoglobin, it can be argued that mutations at this position may result in large changes in the functional properties of hemoglobin. However, only small mutation-induced changes in functional and structural properties are found for the recombinant hemoglobins betaY35F and betaY35A. Oxygen equilibrium-binding studies in solution, which measure the overall oxygen affinity (the p50) and the overall cooperativity (the Hill coefficient) of a hemoglobin solution, show that removing the phenolic hydroxyl group of Tyr35beta results in small decreases in oxygen affinity and cooperativity. In contrast, removing the entire phenolic ring results in a fourfold increase in oxygen affinity and no significant change in cooperativity. The kinetics of carbon monoxide (CO) combination in solution and the oxygen-binding properties of these variants in deoxy crystals, which measure the oxygen affinity and cooperativity of just the T quaternary structure, show that the ligand affinity of the T quaternary structure decreases in betaY35F and increases in betaY35A. The kinetics of CO rebinding following flash photolysis, which provides a measure of the dissociation of the liganded hemoglobin tetramer, indicates that the stability of the liganded hemoglobin tetramer is not altered in betaY35F or betaY35A. X-ray crystal structures of deoxy betaY35F and betaY35A are highly isomorphous with the structure of wild-type deoxyhemoglobin. The betaY35F mutation repositions the carboxyl group of Asp126alpha1 so that it may form a more favorable interaction with the guanidinium group of Arg141alpha2. The betaY35A mutation results in increased mobility of the Arg141alpha side chain, implying that the interactions between Asp126alpha1 and Arg141alpha2 are weakened. Therefore, the changes in the functional properties of these 35beta mutants appear to correlate with subtle structural differences at the C terminus of the alpha-subunit.     

Guanidine hydrochloride exerts dual effects on the tryptophan synthase alpha 2 beta 2 complex as a cation activator and as a modulator of the active site conformation.

To characterize the conformational transitions that regulate the activity and specificity of the tryptophan synthase alpha 2 beta 2 complex, we have determined some effects of low concentrations of guanidine hydrochloride (GuHCl) and of urea on functional properties. We report the novel finding that GuHCl at low concentrations (0. 02-0.08 M) is a cation activator of the tryptophan synthase alpha 2 beta 2 complex. Molecular modeling studies show that GuH+ could bind at a previously identified cation binding site in the tryptophan synthase beta subunit. Addition of increasing concentrations of GuHCl has strikingly different effects on the rates of different reactions with L-serine or beta-chloro-L-alanine in the presence or absence of indole. Spectroscopic studies demonstrate that GuHCl alters the equilibrium distribution of pyridoxal 5'-phosphate intermediates formed in reactions at the active site of the beta subunit. Data analysis shows that GuHCl binds preferentially with the conformer of the enzyme that predominates when the aldimine of L-serine is formed and shifts the equilibrium in favor of this conformer. These results provide evidence that GuHCl exerts dual effects on tryptophan synthase as a cation, stimulating activity, and as a chaotropic agent, altering the distribution of conformational states that exhibit different reaction specificities. Our finding that the nonionic urea stabilizes the aldimine of L-serine in the presence, but not in the absence, of NaCl shows that cation binding plays an important role in the conformational transitions that regulate activity and the transmission of allosteric signals between the alpha and beta sites.     

Geminate reactions of oxygen and nitric oxide with the alpha and beta subunits of Fe-Co hybrid hemoglobins

The alpha and beta subunits in Fe-Co hybrid hemoglobins differ in their rapid reactions with dioxygen and nitric oxide after dissociation by a 25-ns photoflash. The alpha subunits show little recombination on a scale of tens of nanoseconds, whereas the beta subunits show extensive recombination on this time sale. The alpha-beta difference is more marked with Fe than with Co and greater with dioxygen as ligand than with nitric oxide, but is clearly evident in all combinations of ligand and metal. Addition of inositol hexaphosphate slows ligand binding and reduces the proportion of rapid recombination of dioxygen and nitric oxide to beta-Fe subunits. The behavior of alpha-Fe subunits is unaffected by this compound. These results permit the beta subunit to be identified as the T-state species which equilibrates rapidly with oxygen in the T-state, i.e. the reverse of the identification suggested on structural grounds.     

Allosteric effects of chloride ions at the intradimeric alpha1beta1 and alpha2beta2 interfaces of human hemoglobin

The structural transition induced by ligand binding in human hemoglobin encompasses quaternary structure changes at the interfaces between the two alphabeta dimers. In contrast, the interfaces between alpha and beta subunits within the same dimer (i.e., alpha1beta1 and alpha2beta2 interfaces) are structurally invariant. Previous work from this laboratory using NMR spectroscopy has identified four sites at the intradimeric alpha1beta1 and alpha2beta2 interfaces that, although structurally invariant, experience significant changes in the rates of proton exchange upon ligand binding. These sites are Hisalpha103(G10) and Hisalpha122(H5) in each alpha subunit of the hemoglobin tetramer. In the present work, we show that the proton exchange at the Hisalpha103(G10) sites is affected by the interactions of hemoglobin with chloride ions. Increasing concentrations of chloride ions at pH 6.45 and at 37 degrees C enhance the exchange rate of the Hisalpha103(G10) N(epsilon 2) proton. The enhancement is greater in deoxygenated than in ligated hemoglobin. In the framework of the local unfolding model for proton exchange, these results suggest that the structural free energy and/or the proton transfer reactions at the Hisalpha103(G10) sites depend on the concentration of chloride ions. Therefore, the ligand-induced changes at the Hisalpha103(G10) sites are modulated by the allosteric effect of chloride ions on hemoglobin.     

Differences in changes of the alpha1-beta2 subunit contacts between ligand binding to the alpha and beta subunits of hemoglobin A: UV resonance raman analysis using Ni-Fe hybrid hemoglobin

The alpha1-beta2 subunit contacts in the half-ligated hemoglobin A (Hb A) have been explored with ultraviolet resonance Raman (UVRR) spectroscopy using the Ni-Fe hybrid Hb under various solution conditions. Our previous studies demonstrated that Trpbeta37, Tyralpha42, and Tyralpha140 are mainly responsible for UVRR spectral differences between the complete T (deoxyHb A) and R (COHb A) structures [Nagai, M., Wajcman, H., Lahary, A., Nakatsukasa, T., Nagatomo, S., and Kitagawa, T. (1999) Biochemistry, 38, 1243-1251]. On the basis of it, the UVRR spectra observed for the half-ligated alpha(Ni)beta(CO) and alpha(CO)beta(Ni) at pH 6.7 in the presence of IHP indicated the adoption of the complete T structure similar to alpha(Ni)beta(deoxy) and alpha(deoxy)beta(Ni). The extent of the quaternary structural changes upon ligand binding depends on pH and IHP, but their characters are qualitatively the same. For alpha(Ni)beta(Fe), it is not until pH 8.7 in the absence of IHP that the Tyr bands are changed by ligand binding. The change of Tyr residues is induced by binding of CO, but not of NO, to the alpha heme, while it was similarly induced by binding of CO and NO to the beta heme. The Trp bands are changed toward R-like similarly for alpha(Ni)beta(CO) and alpha(CO)beta(Ni), indicating that the structural changes of Trp residues are scarcely different between CO binding to either the alpha or beta heme. The ligand induced quaternary structural changes of Tyr and Trp residues did not take place in a concerted way and were different between alpha(Ni)beta(CO) and alpha(CO)beta(Ni). These observations directly indicate that the phenomenon occurring at the alpha1-beta2 interface is different between the ligand binding to the alpha and beta hemes and is greatly influenced by IHP. A plausible mechanism of the intersubunit communication upon binding of a ligand to the alpha or beta subunit to the other subunit and its difference between NO and CO as a ligand are discussed.     

G alpha i-G alpha s chimeras define the function of alpha chain domains in control of G protein activation and beta gamma subunit complex interactions

Gs and Gi2 are G proteins whose alpha subunits are 65% homologous. Within the 355 amino acid alpha i2 polypeptide, substitution of residues Ile213-Lys319 with the corresponding alpha s region (Ile235-Arg356) generated a chimera that activated adenylyl cyclase, indicating that the alpha s activation domain resides within this 122 amino acid alpha s sequence. Mutation within alpha s residues Glu15-Pro144 resulted in an alpha s polypeptide having an enhanced rate of GDP dissociation. Mutation within two regions of the N-terminus influenced the ability of pertussis toxin to ADP-ribosylate the alpha subunit polypeptide, a reaction controlled by the beta gamma subunit complex. The findings define the G protein alpha subunit N-terminus as a regulatory region controlling beta gamma subunit interactions and GDP dissociation independent of the GTPase and effector activation domains.     

Benzoic acid inhibition of the alpha, beta, and gamma isozymes of Agaricus bisporus tyrosinase

Inhibition of the catecholase and cresolase reactions of the alpha, beta, and gamma isozymes of Agaricus bisporus tyrosinase by benzoic acid was investigated at 25.0 and 8.0 degrees C at pH 5.60 in air-saturated solutions. Benzoic acid is a simple competitive inhibitor of the cresolase reaction of all three isozymes. In the catecholase reaction, however, benzoic acid is a partial uncompetitive inhibitor of the alpha and beta isozymes and a simple competitive inhibitor of gamma-tyrosinase. Equilibrium dialysis experiments, conducted under identical conditions to the kinetic studies, indicate that benzoic acid can bind to the alpha and gamma isozymes in the absence of organic substrate. The dissociation constants obtained by equilibrium dialysis are in good agreement with the kinetic Ki values determined from inhibition studies. Maximum binding of benzoic acid to alpha and gamma tyrosinase, however, is significantly less than one mole per mole of active sites. A scheme in which benzoic acid binds to the oxy-form of tyrosinase is proposed to account for the kinetic and equilibrium results.     

Ions binding to S100 proteins. II. Conformational studies and calcium-induced conformational changes in S100 alpha alpha protein: the effect of acidic pH and calcium incubation on subunit exchange in S100a (alpha beta) protein

A rapid separation method for bovine brain S100 alpha alpha, S100a, and S100b protein using fast protein liquid chromatography on a Mono Q column and its application in preparation of a large amount of S100 alpha alpha protein are described. The conformation of S100 alpha alpha in the metal-free forms as well as in the presence of calcium were studied by UV absorption, circular dichroism, intrinsic fluorescence, sulfhydryl reactivity, and interaction with a hydrophobic fluorescent probe. The alpha-subunit appears to have nearly identical conformation in S100 alpha alpha and S100a protein dimers. We also confirmed that only the alpha-subunit exposes hydrophobic domains to solvent in the presence of calcium and that cysteine residues exposed upon Ca2+ binding to S100 proteins correspond to Cys 85 alpha and Cys 84 beta. Incubation of S100a with calcium and KCl proved that calcium binding to the putative calcium-binding sites (site I alpha, I beta) triggers a time- and temperature-dependent conformational change in the protein structure which decreases the antagonistic effect of KCl on calcium binding to sites II alpha and II beta and provokes subunit exchanges between protein dimers and the emergence of S100 alpha alpha and S100b (beta beta) proteins. Dynamic fluorescence measurements showed that incubating calcium at high S100a protein concentrations (greater than 10(-5) M) induces an apparent slow dimer-monomer equilibrium which might result in total subunit dissociation at lower protein concentrations. The effect of acidic pH on subunit dissociation in S100a protein (Morero, R. D., and Weber, G. (1982) Biochim. Biophys. Acta 703, 231-240) arises from conformational changes in the protein structure that are similar to those induced by Ca2+ incubation.     

Kinetic resolution of ligand binding to the alpha and beta chains within human hemoglobin.

Nitric oxide has been used as a chain-specific, spin label of unliganded heme groups present in kinetic mixtures of human hemoglobin and n-butyl isocyanide. In these experiments, deoxyhemoglobin was reacted with n-butyl isocyanide for a controlled time and then mixed rapidly with a high concentration of nitric oxide to fill residual, unoccupied heme sites. The final mixture was frozen immediately after formation to prevent any displacement of bound isonitrile. The EPR spectrum of the frozen sample was resolved into alpha and beta nitric oxide components; these reflect the relative proportions of alpha- and beta-heme sites which were unoccupied by n-butyl isocyanide. Individual time courses for the alpha and beta subunits were obtained by varying the time between the formation of the isonitrile/hemoglobin mixture and its reaction with nitric oxide. At pH 7.0 only the beta chain time course exhibits an initial rapid phase; the alpha chain time course is monophasic, exhibiting almost, exponential behavior. This result shows unequivocally that the beta-hemes within deoxyhemoglobin react much more rapidly with n-butyl isocyanide than the alpha hemes.