pH dependence of carbon monoxide binding to ferrous horseradish peroxidase

Pathological Impact of the Interaction of NO and CO with Mitochondria in Critical Care Diseases

The outcome of patients with critical care diseases (CCD) such as sepsis, hemorrhagic shock, or trauma is often associated with mitochondrial dysfunction. In turn, mitochondrial dysfunction is frequently induced upon interaction with nitric oxide (NO) and carbon monoxide (CO), two gaseous messengers formed in the body by NO synthase (NOS) and heme oxygenase (HO), respectively. Both, NOS and HO are upregulated in the majority of CCD. A multitude of factors that are associated with the pathology of CCD exert a potential to interfere with mitochondrial function or the effects of the gaseous messengers. From these, four major factors can be identified that directly influence the effects of NO and CO on mitochondria and which are defined by (i) local concentration of NO and/or CO, (ii) tissue oxygenation, (iii) redox status of cells in terms of facilitating or inhibiting reactive oxygen species formation, and (iv) the degree of tissue acidosis. The combination of these four factors in specific pathological situations defines whether effects of NO and CO are beneficial or deleterious.

Cardiolipin-cytochrome c complex: Switching cytochrome c from an electron-transfer shuttle to a myoglobin- and a peroxidase-like heme-protein

Cytochrome c (cytc) is a small heme-protein located in the space between the inner and the outer membrane of the mitochondrion that transfers electrons from cytc-reductase to cytc-oxidase. The hexa-coordinated heme-Fe atom of cytc displays a very low reactivity toward ligands and does not exhibit significant catalytic properties. However, upon cardiolipin (CL) binding, cytc achieves ligand binding and catalytic properties reminiscent of those of myoglobin and peroxidase. In particular, the peroxidase activity of the cardiolipin-cytochrome c complex (CL-cytc) is critical for the redistribution of CL from the inner to the outer mitochondrial membranes and is essential for the execution and completion of the apoptotic program. On the other hand, the capability of CL-cytc to bind NO and CO and the heme-Fe-based scavenging of reactive nitrogen and oxygen species may affect apoptosis. Here, the ligand binding and catalytic properties of CL-cytc are analyzed in parallel with those of CL-free cytc, myoglobin, and peroxidase to dissect the potential mechanisms of CL in modulating the pro- and anti-apoptotic actions of cytc.

Investigations of ferric heme cyanide photodissociation in myoglobin and horseradish peroxidase

The photodissociation of cyanide from ferric myoglobin (MbCN) and horseradish peroxidase (HRPCN) has definitively been observed. This has implications for the interpretation of ultrafast IR (Helbing et al. Biophys. J. 2004, 87, 1881-1891) and optical (Gruia et al. Biophys. J. 2008, 94, 2252-2268) studies that had previously suggested the Fe-CN bond was photostable in MbCN. The photolysis of ferric MbCN takes place with a quantum yield of ~75%, and the resonance Raman spectrum of the photoproduct observed in steady-state experiments as a function of laser power and sample spinning rate is identical to that of ferric Mb (metMb). The data are quantitatively analyzed using a simple model where cyanide is photodissociated and, although geminate rebinding with a rate of kBA ≈ (3.6 ps)(-1) is the dominant process, some CN(-) exits from the distal heme pocket and is replaced by water. Using independently determined values for the CN(-) association rate, we find that the CN(-) escape rate from the ferric myoglobin pocket to the solution at 293 K is kout ≈ (1-2) × 10(7) s(-1). This value is very similar to, but slightly larger than, the histidine gated escape rate of CO from Mb (1.1 × 10(7) s(-1)) under the same conditions. The analysis leads to an escape probability kout/(kout + kBA) ~ 10(-4), which is unobservable in most time domain kinetic measurements. However, the photolysis is surprisingly easy to detect in Mb using cw resonance Raman measurements. This is due to the anomalously slow CN(-) bimolecular association rate (170 M(-1) s(-1)), which arises from the need for water to exchange at the ferric heme binding site of Mb. In contrast, ferric HRP does not have a heme bound water molecule and its CN(-) bimolecular association rate is larger by ~10(3), making the CN(-) photolysis more difficult to observe.

A "sliding scale rule" for selectivity among NO, CO, and O₂ by heme protein sensors

Selectivity among NO, CO, and O₂ is crucial for the physiological function of most heme proteins. Although there is a million-fold variation in equilibrium dissociation constants (K(D)), the ratios for NO:CO:O₂ binding stay roughly the same, 1:~10(3):~10(6), when the proximal ligand is a histidine and the distal site is apolar. For these proteins, there is a "sliding scale rule" for plots of log(K(D)) versus ligand type that allows predictions of K(D) values if one or two are missing. The predicted K(D) for binding of O₂to Ns H-NOX coincides with the value determined experimentally at high pressures. Active site hydrogen bond donors break the rule and selectively increase O₂ affinity with little effect on CO and NO binding. Strong field proximal ligands such as thiolate, tyrosinate, and imidazolate exert a "leveling" effect on ligand binding affinity. The reported picomolar K(D) for binding of NO to sGC deviates even more dramatically from the sliding scale rule, showing a NO:CO K(D) ratio of 1:~10(8). This deviation is explained by a complex, multistep process, in which an initial low-affinity hexacoordinate NO complex with a measured K(D) of ≈54 nM, matching that predicted from the sliding scale rule, is formed initially and then is converted to a high-affinity pentacoordinate complex. This multistep six-coordinate to five-coordinate mechanism appears to be common to all NO sensors that exclude O₂ binding to capture a lower level of cellular NO and prevent its consumption by dioxygenation.

CO binding and ligand discrimination in human myeloperoxidase

Despite the fact that ferrous myeloperoxidase (MPO) can bind both O(2) and NO, its ability to bind CO has been questioned. UV/visible spectroscopy was used to confirm that CO induces small spectral shifts in ferrous MPO, and Fourier transform infrared difference spectroscopy showed definitively that these arose from formation of a heme ferrous-CO compound. Recombination rates after CO photolysis were monitored at 618 and 645 nm as a function of CO concentration and pH. At pH 6.3, k(on) and k(off) were 0.14 mM(-1) x s(-1) and 0.23 s(-1), respectively, yielding an unusually high K(D) of 1.6 mM. This affinity of MPO for CO is 10 times weaker than its affinity for O(2). The observed rate constant for CO binding increased with increasing pH and was governed by a single protonatable group with a pK(a) of 7.8. Fourier transform infrared spectroscopy revealed two different conformations of bound CO with frequencies at 1927 and 1942 cm(-1). Their recombination rate constants were identical, indicative of two forms of bound CO that are in rapid thermal equilibrium rather than two distinct protein populations with different binding sites. The ratio of bound states was pH-dependent (pK(a) approximately 7.4) with the 1927 cm(-1) form favored at high pH. Structural factors that account for the ligand-binding properties of MPO are identified by comparisons with published data on a range of other ligand-binding heme proteins, and support is given to the recent suggestion that the proximal His336 in MPO is in a true imidazolate state.

Time-resolved FTIR study of CO recombination with horseradish peroxidase

Vibrational changes associated with CO recombination to ferrous horseradish peroxidase were investigated by rapid-scan FTIR (Fourier-transform IR) spectroscopy in the 1200-2200 cm(-1) range. At pH 6.0, two conformers of bound CO are present that appear as negative bands at 1905 and 1934 cm(-1) in photolysis spectra. Their recombination rate constants are identical, confirming that they arise from two substates of bound CO that are in rapid thermal equilibrium, rather than from heterogeneous protein sites. A smaller positive band at 2134 cm(-1) also appears on photolysis and decays with the same rate constant, indicative of an intraprotein geminate site involved in recombination or, possibly, a weak-affinity surface CO-binding site. Other signals arising from protein and haem in the 1700-1200 cm(-1) range can also be time-resolved with similar kinetics.

Interaction of bd-type quinol oxidase from Escherichia coli and carbon monoxide: heme d binds CO with high affinity

Comparative studies on the interaction of the membrane-bound and detergent-solubilized forms of the enzyme in the fully reduced state with carbon monoxide at room temperature have been carried out. CO brings about a bathochromic shift of the heme d band with a maximum at 644 nm and a minimum at 624 nm, and a peak at 540 nm. In the Soret band, CO binding to cytochrome bd results in absorption decrease and minima at 430 and 445 nm. Absorption perturbations in the Soret band and at 540 nm occur in parallel with the changes at 630 nm and reach saturation at 3-5 microM CO. The peak at 540 nm is probably either beta-band of the heme d-CO complex or part of its split alpha-band. In both forms of cytochrome bd, CO reacts predominantly with heme d. Addition of high CO concentrations to the solubilized cytochrome bd results in additional spectral changes in the gamma-band attributable to the reaction of the ligand with 10-15% of low-spin heme b558. High-spin heme b595 does not bind CO even at high concentrations of the ligand. The apparent dissociation constant values for the heme d-CO complex of the membrane-bound and detergent-solubilized forms of the fully reduced enzyme are about 70 and 80 nM, respectively.

Peroxynitrite-mediated oxidation of ferrous carbonylated myoglobin is limited by carbon monoxide dissociation

Peroxynitrite-mediated oxidation of ferrous nitrosylated myoglobin (Mb(II)-NO) involves the transient ferric nitrosylated species (Mb(III)-NO), followed by ()NO dissociation and formation of ferric myoglobin (Mb(III)). In contrast, peroxynitrite-mediated oxidation of ferrous oxygenated myoglobin (Mb(II)-O2) involves the transient ferrous deoxygenated and ferryl derivatives (Mb(II) and Mb(IV)O, respectively), followed by Mb(III) formation. Here, kinetics of peroxynitrite-mediated oxidation of ferrous carbonylated horse heart myoglobin (Mb(II)-CO) is reported. Values of the first-order rate constant for peroxynitrite-mediated oxidation of Mb(II)-CO (i.e., for Mb(III) formation) and of the first-order rate constant for CO dissociation from Mb(II)-CO (i.e., for Mb(II) formation) are h=(1.2+/-0.2)x10(-2)s(-1) and k(off(CO))=(1.4+/-0.2)x10(-2)s(-1), respectively, at pH 7.2 and 20.0 degrees C. The coincidence of values of h and k(off(CO)) indicates that CO dissociation represents the rate limiting step of peroxynitrite-mediated oxidation of Mb(II)-CO.

Dynamics of nitric oxide rebinding and escape in horseradish peroxidase

Ultrafast kinetic measurements of NO rebinding to horseradish peroxidase (HRP) are reported for the first time. The geminate kinetics are found to be exponential for all HRP samples studied. The ferric forms of HRP have NO geminate recombination time constants in the range of 15-30 ps, while the ferrous form has a time constant of approximately 7 ps. The simple exponential NO geminate kinetics found for HRP demonstrate that heme relaxation is not the underlying source of the nonexponential NO rebinding in myoglobin (Mb). The NO ligand escape rates from HRP are also determined, and they are found to depend dramatically on the presence or absence of the competitive inhibitor benzohydroxamic acid (BHA). The kinetic results indicate that, in contrast to Mb, there is direct solvent access to the distal heme pocket of HRP.

Proton linkage for CO binding and redox properties of bovine lactoperoxidase

The pH-dependence of redox properties and of CO binding to bovine lactoperoxidase has been investigated over the range between 2 and 11. The pH-dependence of redox potentials shows a biphasic behavior, suggesting the existence of (at least) two redox-linked groups, which change their pKa values upon reduction. These values are in close agreement with those observed to play a relevant role in the modulation of CO binding to ferrous bovine lactoperoxidase. They have been tentatively attributed to Arg-372 and His-226, which are located on the distal side of the heme pocket of lactoperoxidase. A complete and unequivocal description of the proton-linked behavior of bovine lactoperoxidase requires, however, three residues, which are redox linked and relevant for the modulation of CO binding. The rate constant for CO binding to bovine lactoperoxidase is slower than what is reported for most hemoproteins, suggesting that these two residues, Arg-372 and His-226, are representing a severe barrier for the access of exogenous ligands to the heme. This aspect has been further investigated by fast kinetics following laser photolysis, trying to obtain information on the ligand binding pathway and on the energy barriers.

Fine-tuning of the binding and dissociation of CO by the amino acids of the heme pocket of Coprinus cinereus peroxidase

Resonance Raman and infrared spectra and the CO dissociation rates (k(off)) were measured in Coprinus cinereus peroxidase (CIP) and several mutants in the heme binding pocket. These mutants included the Asp245Asn, Arg51Leu, Arg51Gln, Arg51Asn, Arg51Lys, Phe54Trp, and Phe54Val mutants. Binding of CO to CIP produced different CO adducts at pH 6 and 10. At pH 6, the bound CO is H-bonded to the protonated distal His55 residue, whereas at alkaline pH, the vibrational signatures and the rate of CO dissociation indicate a distal side which is more open or flexible than in other plant peroxidases. The distal Arg51 residue is important in determining the rate of dissociation in the acid form, increasing by 8-17-fold in the Arg51 mutants compared to that for the wild-type protein. Replacement of the distal Phe with Trp created a new acid form characterized by vibrational frequencies and k(off) values very similar to those of cytochrome c peroxidase.

Anion- and pH-linked conformational transition in horseradish peroxidase

In a previous study we have shown that bringing horseradish peroxidase to pH 3.0 induces a spectroscopic transition (G. Smulevich et al., Biochemistry 36 (1997) 640). We have extended the investigation on this pH-linked conformational change to different experimental conditions, such as (i) in phosphate alone, (ii) in HCl alone and (iii) in phosphate + NaCl. The data obtained allow a number of conclusions to be drawn, namely: (a) the exposure to pH 3.0 under all conditions brings about an alteration of the distal portion of the heme pocket, leading to the rapid formation of a hexa-coordinated species; (b) only in the presence of phosphate is the hexa-coordination followed by a slow cleavage (or severe weakening) of the proximal Fe-His bond, and (c) the rate of this second process is speeded up in the presence of Cl- ions. Such observations underline the presence of a communication pathway between the two opposite sides of the heme pocket, such that any alteration of the structural arrangement on one side of the heme cavity is transmitted to the other, inducing a corresponding conformational change.

The distal cavity structure of carbonyl horseradish peroxidase as probed by the resonance Raman spectra of His 42 Leu and Arg 38 Leu mutants

CO ligation to horseradish peroxidase C (HRPC) was studied by means of site-directed mutagenesis and resonance Raman spectroscopy. The CO complexes of HRPC His 42 --> Leu and Arg 38 --> Leu mutants were characterized at pH values ranging from 3.6 to 9.5. The vibrational frequencies of the Fe-C stretching and Fe-C-O bending modes have been identified by isotopic substitution. Both His 42 --> Leu and Arg 38 --> Leu adducts with CO displayed a single Fe-C stretching band, whereas both recombinant and wild-type HRPC-CO have two bands, corresponding to different conformers. This comparison suggests that CO is H-bonded either to the distal Arg or to the distal His in the two conformers. An acid transition, common to the wild-type protein, was observed for both mutants. This indicates that these distal amino acids do not influence the acid transition. On the contrary, an alkaline transition was only observed for the Arg 38 --> Leu mutant, which suggests that distal His is involved in the alkaline transition of HRPC-CO complex. The spectroscopic information is found to be consistent with the X-ray structure of ferric HRPC. A comparison with the CO complexes of cytochrome c peroxidase and myoglobin is performed, which displays the functional significance of the structural differences between peroxidase classes I and III and between peroxidases and globins, respectively.

Spectroscopic evidence for a conformational transition in horseradish peroxidase at very low pH

Resonance Raman (RR), electronic absorption, and circular dichroism (CD) spectroscopies of the ferric, ferrous, and ferrous-CO forms of horseradish peroxidase (HRP-C) at pH 3.1 are reported. The CD spectra in the UV region show only a small decrease in the alpha-helical content upon pH lowering, whereas dramatic changes are observed in the Soret region. The final form of ferric HRP-C is 5-coordinate high-spin heme whose histidine ligand is replaced by a water ligand with a polar character. The electronic and CD spectra show the presence of an intermediate form with a 6-coordinate heme. Therefore, the cleavage of the proximal Fe-imidazole bond is preceded by the binding of a distal water molecule. For the ferrous form of HRP-C, the pH-dependence of the absorption spectra revealed only the native form in the range pH 5-7 and an unfolded form with a Soret maximum at 383 nm at pH 3.1. An intermediate state, characterized by a Soret maximum at 424 nm, was observed only in a transient way, within a few milliseconds. A metastable and a final species are observed also for the ferrous-CO complex at pH 3.1, as proved by isosbestic points in the electronic absorption spectra. The two forms show different RR nu(Fe-C) and IR nu(CO) modes. The metastable form corresponds to a heme where histidine is replaced by water. The final form is due to the displacement of the water ligand by the proximal histidine. We propose a kinetic model to account for our results at pH 3.1 for the ferric, ferrous, and ferrous-CO forms.

FTIR study of the thermal denaturation of horseradish and cytochrome c peroxidases in D2O

Fourier transform infrared (FTIR) spectroscopy was employed to examine the thermal denaturation of the Fe(III), Fe(II), and Fe(II)-CO forms of cytochrome c peroxidase and horseradish peroxidase in phosphate buffer at pD 7.0. The amide I' regions of the deconvolved spectra are consistent with predominantly alpha-helical secondary structure around room temperature, but the alpha-helical absorption of the two peroxidases differs significantly; bands assigned to alpha-helical components occur at 1659 and 1649 cm-1 in horseradish peroxidase and at 1652 and 1637 cm-1 in cytochrome c peroxidase. The thermal denaturation mechanisms of the peroxidases also vary. All three forms of cytochrome c peroxidase retain their secondary structure up to 50 degrees C, when bands characteristic of aggregation (1616 and 1684 cm-1) appear in the amide I' region, and above 55 degrees C rapid loss of secondary structure is accompanied by enhanced aggregation. In horseradish peroxidase, on the other hand, the Fe(III) and Fe(II) states exhibit dissimilar denaturation mechanisms. Slow, gradual alteration of secondary structure is observed for Fe(III) horseradish peroxidase on heating, and polypeptide unfolding appears to be complete around 90 degrees C, without aggregation. In Fe(II) and Fe(II)-CO horseradish peroxidase, aggregation bands appear at approximately 55 degrees C, signaling the onset of denaturation. Frequency shifts in the v(CO) bands above room temperature reveal the conformational changes in the heme cavity precede global conformational changes in cytochrome c peroxidase but not in horseradish peroxidase. The reduction in amide II intensities, due to peptide H-D exchange on heating the peroxidases in D2O, indicates the formation above room temperature of partially unfolded states with increased solvent accessibility but intact secondary structures.

Evidence for a slow tertiary relaxation in the reaction of tert-butyl isocyanide with horseradish peroxidase

The kinetics of tert-butyl isocyanide binding to the heme protein horseradish peroxidase (HRP) at 22 degrees C was examined on all time scales, from minutes to picoseconds, in aqueous borate buffer at pH 9.08. Unlike myoglobin (Mb) or hemoglobin, HRP shows two bimolecular ligand binding processes. For comparison, binding of the same ligand with Mb was measured under identical conditions. Ligand entry into the protein from the solvent in a mixing experiment is extremely slow in HRP: the bimolecular association constant is 0.04 M-1 s-1, while in Mb it is 4 x 10(3) M-1 s-1. Surprisingly, in view of that difference, picosecond and nanosecond photolyses reveal that once the ligand has reached the iron(II) site there is no difference in cage return or escape from the protein. The rate for the fastest cage return (from the contact pair) is close to 6 x 10(10) s-1 in both proteins. The rates of escape from the contact pair to form a secondary protein-caged pair are also similar: for Mb, 10 x 10(10) s-1, and for HRP, 8.5 x 10(10) s-1. The rate of rebinding from the protein-separated cage is near 4 x 10(6) s-1 in both proteins, and the rate of escape from protein to solvent is close to 3.7 x 10(6) s-1 in both. The difference between the two proteins lies in the low-millisecond time domain. After flash photolysis of HRP, there is a concentration-dependent recombination not seen in mixing experiments. This bimolecular rate constant varies slightly for different HRP preparations, being 2.6 x 10(4) or 4.0 x 10(4) M-1 s-1 in two cases, both of which are much faster than is observed in mixing experiments, namely, 0.04 M-1 s-1. In Mb, photolysis and mixing experiments consistently give the same combination rate, which is somewhat slower than the faster part of the HRP recombination. Similar measurements for the smaller ligand methyl isocyanide revealed no anomalous behavior. The interpretation proposed involves tertiary relaxation after ligand escape, which is significant in blocking the return of the large t-BuNC, but has no apparent effect on smaller ligands. Thus, HRP-t-BuNC reveals in dramatic fashion a phenomenon merely hinted at in earlier work involving the T-state binding kinetics of hemoglobin.

CO recombination in cytochrome c peroxidase: effect of the local heme environment on CO binding explored through site-directed mutagenesis

CO recombination to the cloned cytochrome c peroxidase [CCP(MI)] and mutants of CCP(MI) prepared by site-directed mutagenesis was examined as a function of pH by flash photolysis. The mutants examined included distal Arg 48----Leu, Lys; proximal Asp 235----Asn; and His 181----Gly. At alkaline pH, ferrous CCP(MI) was converted to a hexacoordinate form by a cooperative two-proton ionization, apparent pK(a) = 8.0. This change was observed in all of the mutants, although in the His 181----Gly mutant, the conversion to the hexacoordinate form was the result of a single-proton ionization, implicating His 181 as one of the two residues deprotonated in this isomerization. The pH-dependent conversion of CO ferrous CCP(MI) from acidic to alkaline forms was also observed and was similar to that reported for cytochrome c peroxidase from bakers' yeast [Iizuka, T., Makino, R., Ishimura, Y., & Yonetani, T. (1985) J. Biol. Chem. 260, 1407-1412]. Photolysis of the acidic form of the CO complex of CCP(MI) produces a kinetic form of the ferrous enzyme (form A) which exhibits the slow rate of CO recombination (l1' approximately 10(3) M-1 s-1) characteristic of peroxidases, while photolysis of the alkaline form of the CO complex produces a second kinetic form (form B), which exhibits a much faster rate of recombination (l2' approximately 10(5) M-1 s-1). Kinetic forms analogous to forms A and B were observed in all of the mutants examined. A third kinetic form (form B*) with a bimolecular rate constant l3' approximately 10(6) M-1 s-1 was also observed in the mutants at alkaline pH. Although the pH dependence for the conversion of form A to form B with increasing pH was altered by changes in the local heme environment, the rate of CO recombination by the respective forms was not dramatically altered in the mutants. Transient spectra of the reaction of CO with ferrous CCP(MI) after photolysis show that equilibrium between penta- and hexacoordinate ferrous enzyme is rapid relative to CO recombination. The presence of the internal sixth ligand has no discernible effect on the observed rate of recombination, however. The results presented indicate that in CCP(MI) the rate of ligand binding is determined primarily by isomerization of the protein from a closed conformation at acidic pH to an open conformation at alkaline pH and that polar effects of proximal Asp 235 and distal Arg 48 are of minor significance in the rate of CO recombination in both conformations.

Recombination of carbon monoxide to ferrous horseradish peroxidase types A and C

The recombination of carbon monoxide to isoenzymes A2 and C of horseradish peroxidase (HRP) was studied as a function of temperature (2 to 320 K) and pH (5 to 8.3) with flash photolysis and infrared difference absorption. At low temperatures three geminate recombination processes are observed. One of these internal processes, denoted by I*, is exponential in time with a rate coefficient that deviates strongly from an Arrhenius behavior below 100 K, implying phonon-assisted tunneling. The two other processes, denoted by I, are non-exponential in time and related to different carbonyl isomers, as shown by the infrared difference spectra. The existence of three internal processes indicates that HRP differs considerably from myoglobin where only one internal process, I, is seen. Moreover, the internal processes in HRP are faster than process I in myoglobin. At 300 K, only one recombination process from the solvent is observed and it is very slow (lambda s approximately 1 s-1 at 1 atm CO (1 atm = 101,325 Pa)), much slower than the corresponding association process in myoglobin. Since process I is fast, but binding from the solvent is slow, the barrier at the heme cannot be responsible for the small association rate. The infrared absorption difference spectra of the amide I/II bands indicate that photolysis and recombination trigger a two-step structural change. The slow recombination rate at 300 K can thus be explained by the large Gibbs energy of the conformational transition that is necessary to let CO move into the heme pocket. The partition coefficient for the CO in the heme pocket and the solvent is extremely small, while bond formation with the heme iron occurs in less than 100 nanoseconds.