Spectral evidence for sub-picosecond iron displacement after ligand detachment from hemoproteins by femtosecond light pulses.

We have measured spectral and kinetic differences in protoheme, sperm whale or horse heart myoglobin and human hemoglobin following photodissociation induced by optical pulses of 80 fs duration. Full ligation was performed with oxygen or carbon monoxide. Femtosecond kinetics and transient difference spectra revealed the appearance of a deoxy species with tau approximately equal to 250-300 fs. The transient deoxy species in myoglobin and hemoglobin evidenced a 3-4 nm red shift of their delta A spectra compared with the equilibrium delta A spectrum. This shift was not observed after photodissociation of the carbon monoxide liganded protoheme. We proposed that the 250 fs time constant corresponding to the appearance of the deoxy-like species is related to the displacement of the ferrous iron out of the heme plane. Consequently, the small red shift of the delta A spectra observed in photodissociated hemoproteins may be tentatively attributed to changes in the vibrational modes of either the proximal histidine-Fe2+ bond and/or of the N4 porph-Fe-N epsilon His (F8) bent.     

Kinetics of carbon monoxide binding to monomeric hemoproteins. Role of the proximal histidine

The effect of pH on (i) the second-order rate constant for CO binding and (ii) the spectral properties of the deoxygenated derivative of several monomeric hemoproteins has been investigated in the pH range between 2.3 and 9.0. As in the case of 3-[1-imidazolyl]-propylamide monomethyl ester mesoheme, the rate constant for CO binding to sperm whale, horse, Dermochelys coriacea, Coryphaena hippurus, and Aplysia limacina myoglobins (the latter only in the presence of acetate/acetic acid mixture) increases, as the pH is lowered, to a value at least 1 order of magnitude higher than at pH 7.0. Such an effect is not observed in A. limacina myoglobin (in the absence of the acetate/acetic acid mixture) and Chironomus thummi thummi erythrocruorin. Moreover, the absorption spectrum, in the visible region, of the deoxy derivative of all these monomeric hemoproteins (with the exception of A. limacina myoglobin in the absence of the acetate/acetic acid mixture) undergoes a transition as the pH is lowered, an effect observed previously with 3-[1-imidazolyl]-propylamide monomethyl ester protoheme. On the basis of analogous spectroscopic and kinetic properties of chelated heme model compounds we attribute this behavior to the protonation of the N epsilon of the proximal imidazole involved in the bond with the iron atom. On the basis of this model the movement of the iron atom to the heme plane appears as a crucial step for CO binding, the activation free energy of the process amounting to approximately 2 kcal/mol.     

Magnetic circular dichroism studies of myoglobin, hemoglobin and peroxidase at room and low temperatures. Ferrous high spin derivatives.

The magnetic circular dichroism spectra (MCD) recorded for the visible and near-UV regions of high-spin ferrous derivatives of myoglobin, hemoglobin, hemoglobin dimers and isolated chains as well as of horseradish peroxidase at pH 6.8 and 11.4 have been compared at the room and liquid nitrogen temperatures. The MCD of the Q00- and QV-bands have been shown to be sensitive to structural differences in the heme environment of these hemoproteins. The room temperature visible MCD of native hemoglobin differs from that of myoglobin, hemoglobin dimers and isolated chains as well as from that of model pentacoordinated complex. The MCD of hemoglobin is characterized by the greater value of the MCD intensity ratio of derivative shape A-term in the Q00-band to the A-term in the QV-band. The evidneces are presented for the existence of two pH-dependent forms of ferroperoxidase, the neutral peroxidase shows the "hemoglobin-like" MCD, while the alkaline ferroperoxidase is characterized by the "myoglobin-like" MCD spectrum in the visible region. The differences in the MCD of deoxyhemoglobin and neutral ferroperoxidase as compared with other high-spin ferrous hemoproteins are considered to result from the constraints on heme group imposed by quaternary and/or tertiary protein structure. The differences between hemoporteins which are seen at the room temperature become more pronounced at liquid nitrogen temperature. Except the peak at approximately 580 nm in the MCD of deoxymyoglobin and reduced peroxidase at pH 11.4 the visible MCD does not show appreciable temperature dependent C-terms. The nature of the temperature dependent effect at approximately 580 nm is not clear. The Soret MCD of all hemoproteins studied are similar and are predominantly composed of the derivative-shaped C-terms as revealed by the increase of the MCD peaks approximately in accordance with Boltzmann distribution. The interpretation of temperature-dependent MCD observed for the Soret band has been made in terms of porphyrin to Fe-iron charge-transfer electronic transition which may be assigned as b( pi) leads to 3d. This charge-transfer band is strongly overlapped with usual B(pi --pi*) band resulting in diffuse Soret band. Adopting that only two normal vibrations are sinphase with charge-transfer transition the extracted C-terms of the Soret MCD have been fitted by theoretical dispersion curves.     

Ligand-dependent Bohr effect of Chrionomus hemoglobins.

The O2 and CO Bohr effects of monomeric and dimeric hemoglobins of the insect Chironomus thummi thummi were determined as proton releases upon ligation. For the O2 Bohr effect of the monomeric hemoglobin III a maximum value of 0.20 H+/heme was obtained at pH 7.5. Upon ligation with CO, however, only 0.04 H+/heme were released at the same pH. In agreement with this finding isoelectric focusing experiments revealed different isoelectric points for O2-liganded and CO-liganded states of hemoglobin III. Analogous results were obtained in the cases of the monomeric hemoglobin IV and the dimeric hemoglobins of Chironomus thummi thummi; here O2 Bohr effects of 0.43 and 0.86 H+/heme were observed. For the corresponding CO Bohr effects values of 0.08 and 0.31 H+/heme were obtained respectively. On the basis of the available structural data the reduced CO Bohr effect in hemoglobin III is discussed as arising from a steric hindrance of the CO ligand by the side chain of isoleucine-E11, obstructing the movement of the heme-iron upon reaction with carbon monoxide. It should, however, be noted that ligands, according to their different electron donor and acceptor properties, may generally induce different conformational changes and thus different Bohr effects, in those hemoglobins in which distinct tertiary and/or quaternary constraints have not evolved. The general utilization of CO instead of O2 as allosteric effector is ruled out by the results reported here.     

Effect of steady illumination on the binding of carbon monoxide by carboxymethylated cytochrome c (Short Communication)

The quantum yield, [unk], is reported for the photodissociation of CO from reduced carboxymethylated cytochrome c. The values of [unk] obtained are low relative to that for myoglobin and are pH-independent, being 0.23 at pH6.1 and 0.27 at pH9.7.     

CO binding to hemoglobin and myoglobin in equilibrium with a gas phase of low PO2 value

The aim of this paper was to measure the binding of CO to myoglobin and hemoglobin at various PO2 values. For this purpose we have studied an "in vitro" system made up of solutions of hemoglobin and myoglobin equilibrated in two connected tonometers with the same gas phase of various PO2 and PCO. The results indicate that a significant proportion of CO is released by hemoglobin and binds myoglobin at low PO2 values (approximately 2-3 Torr), in qualitative agreement with the predictions of a previous computer simulation of the "in vivo" system.     

Ligand binding and protein relaxation in heme proteins: a room temperature analysis of NO geminate recombination

Ultrafast absorption spectroscopy is used to study heme-NO recombination at room temperature in aqueous buffer on time scales where the ligand cannot leave its cage environment. While a single barrier is observed for the cage recombination of NO with heme in the absence of globin, recombination in hemoglobin and myoglobin is nonexponential. Examination of hemoglobin with and without inositol hexaphosphate points to proximal constraints as important determinants of the geminate rebinding kinetics. Molecular dynamics simulations of myoglobin and heme-imidazole subsequent to ligand dissociation were used to investigate the transient behavior of the Fe-proximal histidine coordinate and its possible involvement in geminate recombination. The calculations, in the context of the absorption measurements, are used to formulate a distinction between nonexponential rebinding that results from multiple protein conformations (substates) present at equilibrium or from nonequilibrium relaxation of the protein triggered by a perturbation such as ligand dissociation. The importance of these two processes is expected to depend on the time scale of rebinding relative to equilibrium fluctuations and nonequilibrium relaxation. Since NO rebinding occurs on the picosecond time scale of the calculated myoglobin relaxation, a time-dependent barrier is likely to be an important factor in the observed nonexponential kinetics. The general implications of the present results for ligand binding in heme proteins and its time and temperature dependence are discussed. It appears likely that, at low temperatures, inhomogeneous protein populations play an important role and that as the temperature is raised, relaxation effects become significant as well.     

A comparison of the heme electronic states in equilibrium and nonequilibrium protein conformations of high-spin ferrous hemoproteins. Low temperature magnetic circular dichroism studies

The visible and near infrared magnetic circular dichroism (MCD) spectra of equilibrium high-spin ferrous derivatives of myoglobin, hemoglobin, horseradish peroxidase and mitochondrial cytochrome c oxidase at 15 K are compared with those of the corresponding proteins in nonequilibrium conformations produced by low-temperature photodissociation of CO-complexes of these proteins as well as of O2-complexes of myoglobin and hemoglobin. Over all the spectral region (450-800 nm) the intensities of MCD bands of hemoproteins studied in equilibrium conformation are shown to be strongly temperature-dependent, including a negative band at ca. 630 nm and positive bands at ca. 690 nm and at ca. 760 nm. In contrast to the absorption spectra, the low-temperature MCD spectra of high-spin ferrous hemoproteins differ significantly, reflecting the peculiarities in the heme iron coordination sphere which are created by a protein conformation. The MCD spectra reveal clearly the structural changes in the heme environment which occur on ligand binding. On the basis of assignment of d leads to d and charge-transfer transitions in the near infrared region the correlation is suggested between the wavelength position of the MCD band at approx. 690 nm and the value of iron out-of-plane displacement as well as between the location of the band at approx. 760 nm and the Fe-N epsilon (proximal histidine) bond strength (length) in equilibrium and nonequilibrium conformations of the hemoproteins studied. The high sensitivity of low-temperature MCD spectra to geometry at heme iron is discussed.     

Some binding properties of the envelope of Porphyromonas gingivalis to hemoglobin

Abstract Porphyromonas gingivalis was found to bind to hemoproteins (hemoglobin, myoglobin, catalase, cytochrome c ) and the binding properties of the envelope of P. gingivalis to hemoglobin were investigated. Maximum amount of hemoglobin bound to 1 mg of the envelope was 58 μg. No significant binding was observed at 4°C and the binding was inhibited strongly by tosyl- l -lysine chloromethyl ketone, Leupeptin, EDTA and partially by meta-periodate. Heating of the envelope at 70°C for 15 min resulted in complete loss of the binding activity. The binding activity of the envelope was not influenced by the treatment with the endogenous proteases. The envelope saturated with hemoglobin could no longer bind to other hemoproteins tested, indicating that binding site for these hemoproteins are common.     

Comparison of the heme electron state of reduced cytochrome P450 and P420 in equilibrium and non-equilibrium protein conformations. The nature of the protein heme ligand

Magnetic circular dichroism (MCD) spectra of reduced cytochromes P450 and P420 in equilibrium and non-equilibrium protein conformations are compared at 4.2 K for the 350-800 spectral region. Non-equilibrium forms have been produced by photolysis of CO-complexes at 4.2 K. The differences between MCD spectra of proteins in equilibrium and non-equilibrium conformations, in particular for the visible region, show clearly the structural changes in the heme iron coordination sphere to occur on ligand binding. The comparison of the Soret MCD spectra of reduced proteins in their equilibrium and non-equilibrium forms with those of other high-spin ferrous hemoproteins suggest that mercaptide (RS-) is the protein ligand of the heme iron in reduced P450, as well as in its CO-complex, and that imidazole of histidine is the fifth ligand of the iron both in reduced P420 and its CO-complex. The thermal recombination of the photoproducts with CO have been studied. When temperature rises from 4.2 to 77 K for two hours both proteins have similar temperature characteristics during the recombination processes. The recombination begins at T approximately equal to 10 K and is completed at approximately equal to 50 K. The temperature at which half of the total photolyzed molecules are restored to the CO-form is equal to 25 K. For products of photolysis of CO-complexes of myoglobin and hemoglobin under the same heating conditions these temperatures are equal to 35 and 23 K respectively. Thus, the photoproducts of P450, P420 and hemoglobin have similar parameters of low-temperature recombination and the kinetics of this process is faster than for photodissociated myoglobin.     

Ligand migration and binding in the dimeric hemoglobin of Scapharca inaequivalvis

Using Fourier transform infrared (FTIR) spectroscopy combined with temperature derivative spectroscopy (TDS) at cryogenic temperatures, we have studied CO binding to the heme and CO migration among cavities in the interior of the dimeric hemoglobin of Scapharca inaequivalvis (HbI) after photodissociation. By combining these studies with X-ray crystallography, three transient ligand docking sites were identified: a primary docking site B in close vicinity to the heme iron, and two secondary docking sites C and D corresponding to the Xe4 and Xe2 cavities of myoglobin. To assess the relevance of these findings for physiological binding, we also performed flash photolysis experiments on HbICO at room temperature and equilibrium binding studies with dioxygen. Our results show that the Xe4 and Xe2 cavities serve as transient docking sites for unbound ligands in the protein, but not as way stations on the entry/exit pathway. For HbI, the so-called histidine gate mechanism proposed for other globins appears as a plausible entry/exit route as well.     

Kinetics and temperature dependence of carboxymyoglobin ligand photodissociation

We have observed the rate of oxymyoglobin (MbO2) photodissociation at room temperature and carboxymyoglobin (MbCO) photodissociation as a function of temperature (260-10 K) by means of picosecond spectroscopy. The Mb + O2 and Mb + CO photodissociated states have also been characterized. Based on the picosecond experimental data, we postulate that the photodissociation of ligated myoglobin is a nonactivitated process, and the mechanism involves either a small enthalpy barrier or none at all.     

Effect of the distal histidine modification (Cyanation) of myoglobin on the ligand binding kinetics and the heme environmental structures

The kinetics of carbon monoxide (CO) binding to myoglobin (Mb) modified at the distal histidine (His) by cyanogen bromide (BrCN) has been studied. The CO association and dissociation rates of BrCN-modified Mb were obtained as 1.8 x 10(3) M-1 s-1 and 0.13 s-1, respectively (20 degrees C and pH 7.0). Thermodynamic parameters were obtained as well. These values are notable, compared with those for other hemoproteins, the slowest association and the fastest dissociation rates among various hemoproteins examined so far. On the basis of the available structural data obtained from the absorption, 1H NMR, and IR spectral measurements, these unique kinetic and thermodynamic properties were reasonably explained in terms of the steric restriction at the modified distal side.     

Proton nuclear magnetic resonance study of the solution distal histidine orientation in monomeric Chironomus thummi thummi cyanomet hemoglobins. Dynamic stability of the heme pocket as monitored by labile proton exchange.

The 1H nuclear magnetic resonance spectral characteristics of the cyano-Met form of Chironomus thummi thummi monomeric hemoglobins I, III and IV in 1H2O solvent are reported. A set of four exchangeable hyperfine-shifted resonances is found for each of the two heme-insertion isomers in the hyperfine-shifted region downfield of ten parts per million. An analysis of relaxation, exchange rates and nuclear Overhauser effects leads to assignments for all these resonances to histidine F8 and the side-chains of histidine E7 and arginine FG3. It is evident that in aqueous solution, the side-chain from histidine E7 does not occupy two orientations, as found for the solid state, rather the histidine E7 side-chain adopts a conformation similar to that of sperm whale myoglobin or hemoglobin A, oriented into the heme pocket and in contact with the bound ligand. Evidence is presented to show that the allosteric transition in the Chironomus thummi thummi hemoglobins arises from the "trans effect". An analysis of the exchange with bulk solvent of the assigned histidine E7 labile proton confirms that the group is completely buried within the heme pocket in a manner similar to that found for sperm whale cyano-Met myoglobin, and that the transient exposure to solvent is no more likely than in mammalian myoglobins with the "normal" distal histidine orientation. Finally, a comparison of solvent access to the heme pocket of the three monomeric C. thummi thummi hemoglobins, as measured from proton exchange rates of heme pocket protons, is made and correlated to binding studies with the diffusible small molecules such as O2.     

15N magnetic resonance studies of the binding of 15N-labeled cyanide to various hemoproteins.

The ¹⁵N paramagnetic shifts of iron-bound C¹⁵N^? were studied for myoglobin, hemoglobin, cytochrome c and other modified hemoproteins. Two characteristic ¹⁵N resonances at 977 and 1045 ppm (with respect to ¹⁵NO₃^? as an internal standard) were found for human adult hemoglobin cyanide, while only single resonances were observed for other cyano hemoproteins. These two resonances are assigned to iron-bound C¹⁵N of α and β subunits of hemoglobin. The substantial difference in the C¹⁵N isotropic shifts in various hemoproteins is discussed in relation to iron-proximal histidine binding and heme-apoprotein interactions.     

Alteration of the proximal bond energy in the unliganded form of the homodimeric myoglobin from Nassa mutabilis. Kinetic and spectroscopic evidence.

CO binding kinetics to the homodimeric myoglobin (Mb) from Nassa mutabilis has been investigated between pH 1.9 and 7.0. Protonation of the proximal imidazole at low pH (less than or equal to 3.0) and the consequent cleavage of the HisF8NE2-Fe proximal bond brings about a approximately 20-fold increase of the second-order rate constant for CO binding. This process displays a pKa = 4.0 +/- 0.2, significantly higher than that observed in all other deoxygenated hemoproteins investigated up to now. Such a feature underlies a decreased energy for the HisF8NE2-Fe proximal bond in the unliganded form and it also appears supported by resonance Raman spectroscopy in the low frequency region of the Fe(II) deoxygenated hemoprotein. Further, the pH-rate profile of N. mutabilis Mb, like that of the homodimeric hemoglobin (Hb) from Scapharca inaequivalvis (Coletta, M., Boffi, A., Ascenzi, P., Brunori, M. and Chiancone, E. (1990) J. Biol. Chem. 265, 4828-4830), can be described only by assuming a concerted proton-linked transition with n = 1.8 +/- 0.1. Such a characteristic suggests, also on the basis of the amino acid sequence homology between N. mutabilis Mb and S. inaequivalvis Hb in the region forming the subunit interface, that the interaction mechanism is similar for the two homodimeric proteins, and drastically different Hb in the region forming the subunit interface, that the interaction mechanism is similar for the two homodimeric proteins, and drastically different from that operative in other hemoproteins.     

Mechanism of detergent interaction with hemoproteins in aqueous media

The interactions of myoglobin, cytochrome c, and cytochrome P-450 LM-2 isolated from rabbit liver microsomes with detergents of type A (TM 3-12, Tween 20, Triton N-101) and detergent of B type (sodium cholate) in aqueous media were studied. These interactions are accompanied by a decrease in the Soret band intensity for all three hemoproteins. The rate of this process depends on the nature and concentration of the detergent as well as on temperature. The rate of the Soret band decrease is maximal for the zwitter-ionic surfactant TM 3-12. The rate constants of hemoprotein transformation depend on the detergent concentration. The detergent effects on the conformation and structure of the protein were demonstrated, using CD spectra and second derivatives of the absorption spectra of the hemoproteins in the presence of the detergents. The activation energies for myoglobin transformation in the presence of various detergents are equal to 17-23 kcal/mol and possibly reflect the cleavage of the coordinative heme-apoprotein bonds. A model of detergent interaction with hemoproteins is discussed. According to this model, the bimolecular interaction of the proteins with surfactants is observed at the detergent concentrations that are much lower than those for critical micelle formation values.     

Kinetic modulation in carbonmonoxy derivatives of truncated hemoglobins: the role of distal heme pocket residues and extended apolar tunnel

Truncated hemoglobins (trHbs), are a distinct and newly characterized class of small myoglobin-like proteins that are widely distributed in bacteria, unicellular eukaryotes, and higher plants. Notable and distinctive features associated with trHbs include a hydrogen-bonding network within the distal heme pocket and a long apolar tunnel linking the external solvent to the distal heme pocket. The present work compares the geminate and solvent phase rebinding kinetics from two trHbs, one from the ciliated protozoan Paramecium caudatum (P-trHb) and the other from the green alga Chlamydomonas eugametos (C-trHb). Unusual kinetic patterns are observed including indications of ultrafast (picosecond) geminate rebinding of CO to C-trHb, very fast solvent phase rebinding of CO for both trHbs, time-dependent biphasic CO rebinding kinetics for P-trHb at low CO partial pressures, and for P-trHb, an increase in the geminate yield from a few percent to nearly 100% under high viscosity conditions. Species-specific differences in both the 8-ns photodissociation quantum yield and the rebinding kinetics, point to a pivotal functional role for the E11 residue. The response of the rebinding kinetics to temperature, ligand concentration, and viscosity (glycerol, trehalose) and the viscosity-dependent changes in the resonance Raman spectrum of the liganded photoproduct, together implicate both the apolar tunnel and the static and dynamic properties of the hydrogen-bonding network within the distal heme pocket in generating the unusual kinetic patterns observed for these trHbs.     

Simulation of carboxymyoglobin photodissociation

Computer-generated models of the structures of deoxymyoglobin and CO-bound myoglobin show that the CO molecule is not packed so tightly by the amino acid residues of the distal pocket to prevent its motion away from the iron atom upon photodissociation. A simulation of low temperature photodissociation by energy minimization techniques shows that the CO moves to a position approximately 4 A away from the iron atom due to the van der Waals forces. The final position of the CO molecule requires far larger motion of the carbon atom than the oxygen atom and thereby suggests that the isotope dependence of the molecular tunneling is a consequence of the orientation of the photodissociated CO.