Ligand binding to heme proteins: II. Transitions in the heme pocket of myoglobin.

Phenomena occurring in the heme pocket after photolysis of carbonmonoxymyoglobin (MbCO) below about 100 K are investigated using temperature-derivative spectroscopy of the infrared absorption bands of CO. MbCO exists in three conformations (A substrates) that are distinguished by the stretch bands of the bound CO. We establish connections among the A substates and the substates of the photoproduct (B substates) using Fourier-transform infrared spectroscopy together with kinetic experiments on MbCO solution samples at different pH and on orthorhombic crystals. There is no one-to-one mapping between the A and B substates; in some cases, more than one B substate corresponds to a particular A substate. Rebinding is not simply a reversal of dissociation; transitions between B substates occur before rebinding. We measure the nonequilibrium populations of the B substates after photolysis below 25 K and determine the kinetics of B substate transitions leading to equilibrium. Transitions between B substates occur even at 4 K, whereas those between A substates have only been observed above about 160 K. The transitions between the B substates are nonexponential in time, providing evidence for a distribution of substates. The temperature dependence of the B substate transitions implies that they occur mainly by quantum-mechanical tunneling below 10 K. Taken together, the observations suggest that the transitions between the B substates within the same A substate reflect motions of the CO in the heme pocket and not conformational changes. Geminate rebinding of CO to Mb, monitored in the Soret band, depends on pH. Observation of geminate rebinding to the A substates in the infrared indicates that the pH dependence results from a population shift among the substates and not from a change of the rebinding to an individual A substate.     

Binding modes of L35 to alpha- and beta-semihemoglobins: structural insights into the inequivalence of alpha- and beta-subunits of hemoglobin

It has been thought for several years that the greatly lowered oxygen affinity, high cooperativity, and heterotropic modulation displayed by tetrameric human hemoglobin (Hb) was an exclusive result of the assembly of high affinity alpha(1)beta(1) dimers into alpha(2)beta(2) tetramers. However, in recent times, it has been shown that alpha- and beta-semihemoglobins, namely alpha(heme)beta(apo) and alpha(apo)beta(heme), which are dimers of Hb characterized by a high affinity for oxygen and lack of cooperativity do respond to effectors such as 2-[4-(3,5-dichlorophenylureido) phenoxy]-2-methylpropionic acid (L35), a bezafibrate (BZF) related compound, by decreasing the ligand affinity to a considerable extent (between 60- and 130-fold). In order to shed some light on the structural basis of this phenomenon, we have developed a binding mode of L35 to semihemoglobins through docking analysis using the program GRID. Molecular modelling studies did identify sites on semihemoglobins where favourable interactions with L35 can occur. We found that the effector binds differently to the two semihemoglobins exhibiting high affinity only for the alpha chain heme pocket. The proposed binding models are consistent with the experimental findings and may be rationalized in terms of different hydrophobic and hydrophilic characteristics between alpha- and beta-heme pockets of Hb.     

Pressure effects on the proximal heme pocket in myoglobin probed by Raman and near-infrared absorption spectroscopy.

The influence of high pressure on the heme protein conformation of myoglobin in different ligation states is studied using Raman spectroscopy over the temperature range from 30 to 295 K. Photostationary experiments monitoring the oxidation state marker bands demonstrate the change of rebinding rate with pressure. While frequency changes of vibrational modes associated with rigid bonds of the porphyrin ring are <1 cm(-1), we investigate a significant shift of the iron-histidine mode to higher frequency with increasing pressure (approximately 3 cm(-1) for deltaP = 190 MPa in Mb). The observed frequency shift is interpreted structurally as a conformational change affecting the tilt angle between the heme plane and the proximal histidine and the out-of-plane iron position. Independent evidence for iron motion comes from measurements of the redshift of band III in the near-infrared with pressure. This suggests that at high pressure the proximal heme pocket and the protein are altered toward the bound state conformation, which contributes to the rate increase for CO binding. Raman spectra of Mb and photodissociated MbCO measured at low temperature and variable pressure further support changes in protein conformation and are consistent with glasslike properties of myoglobin below 160 K.     

Restricting the ligand-linked heme movement in Scapharca dimeric hemoglobin reveals tight coupling between distal and proximal contributions to cooperativity.

Cooperative ligand binding in the dimeric hemoglobin from the blood clam Scapharca inaequivalvis results primarily from tertiary, rather than quaternary, structural changes. Ligand binding is coupled with conformational changes of key residues, including Phe 97, which is extruded from the proximal heme pocket, and the heme group, which moves deeper into the heme pocket. We have tested the role of the heme movement in cooperative function by mutating Ile 114, at the base of the heme pocket. Replacement of this residue with a Met did not disturb the hemoglobin structure or significantly alter equilibrium ligand binding properties. In contrast, substitution with a Phe at position 114 inhibits the ligand-linked movement of the heme group, and substantially reduces oxygen affinity and cooperativity. As the extent of heme movement to the normal position of the ligated state is diminished, Phe 97 is inhibited from its movement into the interface upon ligand binding. These results indicate a tight coupling between these two key cooperative transitions and suggest that the heme movement may be an obligatory trigger for expulsion of Phe 97 from the heme pocket.     

Laser kinetic spectroscopy studies of the bimolecular oxygenation of alpha- and beta-subunits within the R-state of human hemoglobin

Bimolecular oxygenation of tri-liganded R-state human hemoglobin (HbA) is described by bi-exponential kinetics with association rate constants k = 27.2 ± 1.3 (M·sec)^-1 and k = 62.9 ± 1.6 (M·sec)^-1. Both the observed processes have been assigned to the bimolecular oxygenation of - and -subunits of the native tetrameric protein by molecular oxygen. The quantum yields of photodissociation within the completely oxygenated R-state HbA are = 0.0120 ± 0.0017 and = 0.044 ± 0.005 for - and -subunits, respectively. The oxygenation reactions of isolated ^PCMB- and ^PCMB-hemoglobin chains are described by mono-exponential kinetics with the association rate constants k = 44 ± 2 (M·sec)^-1 and k = 51 ± 1 (M·sec)^-1, respectively. The quantum yields of photodissociation of isolated ^PCMB- and ^PCMB-chains (0.056 ± 0.006 and 0.065 ± 0.006, respectively) are greater than that observed for appropriate subunits within the R-state of oxygenated HbA.     

Coordination structure of the ferric heme iron in engineered distal histidine myoglobin mutants.

Recombinant human myoglobin mutants with the distal His residue (E7, His64) replaced by Leu, Val, or Gln residues were prepared by site-directed mutagenesis and expression in Escherichia coli. Electronic and coordination structures of the ferric heme iron in the recombinant myoglobin proteins were examined by optical absorption, EPR, 1H NMR, magnetic circular dichroism, and x-ray spectroscopy. Mutations, His-->Val and His-->Leu, remove the heme-bound water molecule resulting in a five-coordinate heme iron at neutral pH, while the heme-bound water molecule appears to be retained in the engineered myoglobin with His-->Gln substitution as in the wild-type protein. The distal Val and distal Leu ferric myoglobin mutants at neutral pH exhibited EPR spectra with g perpendicular values smaller than 6, which could be interpreted as an admixture of intermediate (S = 3/2) and high (S = 5/2) spin states. At alkaline pH, the distal Gln mutant is in the same so-called "hydroxy low spin" form as the wild-type protein, while the distal Leu and distal Val mutants are in high spin states. The ligand binding properties of these recombinant myoglobin proteins were studied by measurements of azide equilibrium and cyanide binding. The distal Leu and distal Val mutants exhibited diminished azide affinity and extremely slow cyanide binding, while the distal Gln mutant showed azide affinity and cyanide association rate constants similar to those of the wild-type protein.     

Pyrophosphate-dependent phosphofructokinase. Conservation of protein sequence between the alpha- and beta-subunits and with the ATP-dependent phosphofructokinase

Full-length cDNA clones for the alpha- and beta-subunits of pyrophosphate-fructose 6-phosphate 1-phosphotransferase have been isolated from a cDNA expression library derived from potato tuber poly(A)+ RNA. The nucleotide sequences indicate that the alpha- and beta-subunits are related with about 40% of amino acid residues being identical. A comparison of the deduced amino acid sequences of both subunits of this enzyme with that of the major ATP-dependent fructose 6-phosphate 1-phosphotransferase from Escherichia coli (Shirakihara, Y., and Evans, P. R. (1988) J. Mol. Biol. 204, 973-994) showed little homology between the proteins except for regions involved in the binding of fructose 6-phosphate/fructose, 1,6-bisphosphate and possibly between regions binding pyrophosphate and the beta- and gamma-phosphates of ADP/ATP. A comparison of the derived secondary structures of the two subunits of the PPi-dependent enzyme with the known secondary structure of the E. coli ATP-dependent enzyme indicated that the overall structure of these enzymes is similar. These data suggest that catalytic activity resides on the beta-subunit of the pyrophosphate-dependent enzyme.     

Identification of the geometric requirements for allosteric communication between the alpha- and beta-subunits of tryptophan synthase

The pyridoxal 5'-phosphate-dependent tryptophan synthase alpha2beta2 complex is a paradigmatic protein for substrate channeling and allosteric regulation. The enzymatic activity is modulated by a ligand-mediated equilibrium between open (inactive) and closed (active) conformations of the alpha- and beta-subunit, predominantly involving the mobile alpha loop 6 and the beta-COMM domain that contains beta helix 6. The alpha ligand-triggered intersubunit communication seems to rely on a single hydrogen bond formed between the carbonyl oxygen of betaSer-178 of beta helix 6 and the NH group of alphaGly-181 of alpha loop 6. We investigated whether and to what extent mutations of alphaGly-181 and betaSer-178 affect allosteric regulation by the replacement of betaSer-178 with Pro or Ala and of alphaGly-181 with either Pro to remove the amidic proton that forms the hydrogen bond or Ala, Val, and Phe to analyze the dependence on steric hindrance of the open-closed conformational transition. The alpha and beta activity assays and the equilibrium distribution of beta-subunit catalytic intermediates indicate that mutations do not significantly influence the intersubunit catalytic activation but completely abolish ligand-induced alpha-to beta-subunit signaling, demonstrating distinct pathways for alpha-beta-site communication. Limited proteolysis experiments indicate that the removal of the interaction between betaSer-178 and alphaGly-181 strongly favors the more trypsin-accessible open conformation of the alpha-active site. When the hydrogen bond cannot be formed, the alpha-subunit is unable to attain the closed conformation, and consequently, the allosteric signal is aborted at the subunit interface.     

Glucoamylase-like domains in the alpha- and beta-subunits of phosphorylase kinase

Phosphorylase kinase is a four-subunit enzyme involved in the regulation of glycogen breakdown. The traditional textbook view is that only the gamma subunit has enzymatic activity, whereas the other three subunits have a regulatory role. Evidence from homology searches and sequence alignments, however, shows that the alpha- and beta-subunits possess amino-terminal glucoamylase-like domains and suggests that they might possess a previously overlooked amylase activity. If true, this would have important implications for the understanding, diagnosis, and management of glycogen storage diseases. There is thus a clear need to test this hypothesis through enzymatic assays and structural studies.     

Modification of the heme distal side in myoglobin by cyanogen bromide. Heme environmental structures and ligand binding properties of the modified myoglobin

Met, deoxy, and CO forms of myoglobin (Mb) react with a stoichiometric amount of cyanogen bromide (BrCN) to cause substantial changes in the 1H NMR, optical absorption, and infrared spectra. These spectral changes were interpreted as arising from the substantial alterations in the heme environments, most probably due to the modification of the histidine residue at the heme distal side. It is also revealed that the modified Mb does not combine with some exogenous ligands such as CN-, CH3NH2, and O2, although it does with N-3 or CO. These unique ligand binding properties are also discussed with relevance to a role of the distal histidine in stabilizing the coordinated ligand through a hydrogen bond and to a steric constraint.     

Cysteine 647 in the insulin receptor is required for normal covalent interaction between alpha- and beta-subunits and signal transduction.

We have investigated the structural and functional properties of two mutant insulin receptors in which Cys647 and Cys682,683,685 have been replaced with Ser (IRS647 and IRS682,683,685, respectively). Compared with the wild-type receptor (IRWT), both mutant receptors displayed altered sensitivities to dithiothreitol with respect to insulin binding and reduction of oligomeric forms. Subunit composition of the oligomeric forms of the receptors as determined by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis of 125I-labeled receptors indicated that Cys682,683,685 are required for normal heterotetrameric structure and that Cys647 plays a major role in the normal covalent association of the alpha- and beta-subunits. Under nonreducing conditions, the affinity-labeled IRS647 migrated, almost exclusively, as a 230-kDa species which appeared to represent an alpha 2 form of the receptor. Furthermore, Chinese hamster ovary cells expressing IRS647 did not exhibit basal or insulin-stimulated autophosphorylation, suggesting that Cys647 is also required for signal transduction.     

Thin-layer microcalorimetric studies of oxygen and carbon monoxide binding to hemoglobin and myoglobin.

A thin-layer gas-solution microcalorimeter has been developed to study the binding reactions of gaseous ligands with ligand binding macromolecules. We have measured the enthalpy of binding oxygen and carbon monoxide to horse myoglobin, human hemoglobin A0 and sperm whale myoglobin in phosphate buffer at pH 7.6, with the enzyme reducing system of Hayashi. Reactions of human hemoglobin were also done under various buffer conditions in order to elucidate the Bohr effect. These binding reactions were found not to exhibit a detectable enthalpy change over the temperature range of 10 degrees C to 25 degrees C. The enzyme reducing system was shown to react with oxygen in a manner that releases a substantial amount of heat. This problem was corrected by using a minimum amount and by placing the buffer and enzyme system in the reference cell effectively cancelling the oxygen enzyme reaction heat as well as the heat of gas dissolution. It was also demonstrated that glucose-6-phosphate, one of the reducing system components, in 50 mM concentrations can influence the heat of binding oxygen and carbon monoxide to hemoglobin. This effect was shown to be absent in the myoglobins and also with hemoglobin at glucose-6-phosphate concentrations less than 5 mM.     

Estimation of the frequency of amino acid substitutions causing instability of the spatial structure in an overall mutation spectrum of alpha- and beta-subunits of human hemoglobin

The influence of single amino acid substitutions on the stability of alpha- and beta-chains of human hemoglobin was investigated by the computer method. The method was based on characteristics of protein tertiary structure and physico-chemical properties of amino acids. Frequencies of unstable mutations in the total mutational spectra of alpha- and beta-subunits of human hemoglobin were analysed: instability was produced by 26% of mutations in the alpha-subunit and by 32% in the beta-subunit. These results support the idea that certain limitations exist for stability changes produced by amino acid substitutions.     

Effect of removal of a salt-bridge on the oxygen binding properties and the electronic structure of heme in cobalt-iron hybrid hemoglobin.

In order to clarify the role of salt-bridges in hemoglobin, the oxygen equilibrium curves and electron paramagnetic resonance (EPR) spectra of cobalt-iron hybrid hemoglobins were determined. The EPR spectra of deoxy alpha(Co)2 beta(Fe)2 could be interpreted as a mixture of two distinct paramagnetic species: one showed a maximum of the first derivative spectrum at g = 2.39 and the other at g = 2.33. The oxygen equilibrium curves of the hybrid indicated that the former is assignable to the T structure and the latter to the R structure. The cooperativity of oxygen binding of alpha(Co)2 beta(Fe)2 exhibited a maximum at g = 2.33, which is characteristic of the R structure, regardless of the pH. Addition of inositol hexaphosphate (IHP) to des-Arg alpha(Co)2 beta(Fe)2 restored the cooperativity of oxygen binding, which implies that the deoxygenated form of des-Arg alpha(Co)2 beta(Fe)2 is converted to the T structure upon addition of IHP. However, the EPR signal at g = 2.39 was not restored upon conversion to the T structure by addition of IHP. It is therefore concluded that the EPR spectrum of the deoxy alpha(Co) subunit depends both on the quaternary structure and on the localized strain at the heme.     

Modification of the distal histidyl imidazole in myoglobin to N-tetrazole-substituted imidazole and its effects on the heme environmental structure and ligand binding properties.

The mechanism of N-tetrazole ring formation at the distal histidyl imidazole of sperm whale myoglobin (Mb) has been studied by nitrogen-15 (15N) NMR spectroscopy by utilizing 15N-labeled cyanogen bromide (BrCN) and azide ion (N3-). The 15N-NMR spectrum of BrC15N-modified Mb + N3- afforded two hyperfine-shifted 15N resonances, both of which are identical with the resonance positions of two of the three 15N resonances for BrCN-modified Mb + 15NN2-. This unusual spectral feature is due to the formation of the N-tetrazole ring attached to the distal histidyl imidazole and the scrambling of the labeled nitrogen originated from N3- or BrCN over the tetrazole ring upon coordination to the ferric heme iron. The ferric iron-bound N-tetrazole ring comes off upon reduction to the ferrous state, and the stable CO complex of tetrazole-modified Mb (tetrazole-Mb) is formed. Electronic absorption and 1H-NMR spectra of deoxy and carbonmonoxy forms of tetrazole-Mb are slightly altered from those of native Mb by the modification, while the most significant effect is exerted on the C-O stretching frequency of iron-bound CO. The C-O stretching band for tetrazole-MbCO is observed at 1966 cm-1 in contrast to 1945 cm-1 for native MbCO, suggesting that the geometry of iron-bound CO in tetrazole-Mb is relatively upright which is characteristic of the "open" conformer. This result corresponds to the 15-fold increase of the CO association rate constant by the N-tetrazole modification of the distal His. The oxy form of tetrazole-Mb is readily autoxidized to its ferric state, indicating that hydrogen bonding between the distal His and iron-bound oxygen is essential for stable O2 binding to the heme iron.     

Waterproofing the heme pocket. Role of proximal amino acid side chains in preventing hemin loss from myoglobin

The ability of myoglobin to bind oxygen reversibly depends critically on retention of the heme prosthetic group. Globin side chains at the Leu(89)(F4), His(97)(FG3), Ile(99)(FG5), and Leu(104)(G5) positions on the proximal side of the heme pocket strongly influence heme affinity. The roles of these amino acids in preventing heme loss have been examined by determining high resolution structures of 14 different mutants at these positions using x-ray crystallography. Leu(89) and His(97) are important surface amino acids that interact either sterically or electrostatically with the edges of the porphyrin ring. Ile(99) and Leu(104) are located in the interior region of the proximal pocket beneath ring C of the heme prosthetic group. The apolar amino acids Leu(89), Ile(99), and Leu(104) "waterproof" the heme pocket by forming a barrier to solvent penetration, minimizing the size of the proximal cavity, and maintaining a hydrophobic environment. Substitutions with smaller or polar side chains at these positions result in exposure of the heme to solvent, the appearance of crystallographically defined water molecules in or near the proximal pocket, and large increases in the rate of hemin loss. Thus, the naturally occurring amino acid side chains at these positions serve to prevent hydration of the His(93)-Fe(III) bond and are highly conserved in all known myoglobins and hemoglobins.     

Trans-substitution of the proximal hydrogen bond in myoglobin: II. Energetics, functional consequences, and implications for hemoglobin allostery

The trans-substituted histidine to glycine mutant of sperm whale myoglobin (H93G Mb) is used to study energetics of proximal hydrogen bonding, proximal ligand-heme interactions, and coupling to distal ligand binding. Comparison of mono- and dimethylimidazole structural isomers shows that the hydrogen bond between the proximal ligand and the neighboring Ser92 hydroxyl (position F7) is stabilizing. The range of hydrogen bond stabilities measured here for different distal ligand complexes ranges from -0.7 kcal/mol (monomethylimidazole isomers to MbCO) to -4.1 kcal/mol (dimethylimidazole isomers to MbCN). This range of hydrogen bond stabilities, which is similar to that seen in protein mutagenesis unfolding studies, demonstrates the high sensitivity of the hydrogen bond to modest structural perturbations. The degree to which the 2-methyl group destabilizes proximal ligand binding is found to depend inversely on the total electronic spin. For monomethylimidazole proximal ligands, distal ligand binding weakens the proximal hydrogen bond compared to deoxyMb. Surprisingly, this trend is largely reversed for the dimethylimidazole proximal ligands. These results demonstrate strong coupling between the proximal protein matrix and distal ligand binding. These results provide an explanation for the strong avoidance of hydrogen bonding residues at position F7 in hemoglobin sequences.