Positive cooperativity in binding carbon monoxide to hemocyanin

The binding of carbon monoxide to hemocyanin from the crab $\text{Scylla serrata}$ has been studied by thin layer optical absorption and front face fluorescence techniques. The binding to the monomeric form is completely noncooperative whereas the binding to the native oligomeric form is found to be weakly but definitely cooperative. An analysis based on the MWC model of the oxygen and carbon monoxide binding curves indicates that the allosteric constant, L, describing the equilibrium between the 2 unligated forms is different for each ligand. This implies that at least 3 allosteric forms are needed to characterize the binding of oxygen and carbon monoxide to this hemocyanin.     

Heterogeneous binding of oxygen and carbon monoxide to dissociated molluscan hemocyanin

Functional heterogeneity in O2 or CO binding of sites of dissociated molluscan hemocyanin polypeptide chains (Helix pomatia and Octopus vulgaris) has been estimated by an analysis of accurate noncooperative binding curves. Three types of experiments were performed: pure O2 or CO binding, competitive displacement of one ligand by the other, and simultaneous removal of both gases from protein partially saturated with O2 and CO. The data were analyzed in terms of a model which has two fractions of sites with different properties for O2 and CO. The relative proportion of the different binding sites and their affinity constant values were found by the combined use of the three different procedures. All species show a marked functional heterogeneity of sites for O2 binding, while for CO binding it has been observed only in the case of H. pomatia beta-hemocyanin. Moreover, in all three molluscan hemocyanins examined, the two classes of O2-binding sites, although present in different proportions within the polypeptide chains, display similar affinity constant values. The data reported show a good consistency with results obtained using digested and isolated domains, providing confidence in the analytical procedure used. From comparison of the O2/CO affinity ratios (KO2, KCO) of each class it may be suggested that the difference in O2 affinity of two kinds of binding sites is related to a different local structure of the active sites. The results, moreover, unequivocally confirm that binding and displacement of two gaseous ligands to hemocyanin occur by a simple competitive mechanism, although the binding site is structurally complex and the two ligands are bound with different geometries.     

Identical linkage and cooperativity of oxygen and carbon monoxide binding to Octopus dofleini hemocyanin

Employment of high-precision thin-layer methods has enabled detailed functional characterization of oxygen and carbon monoxide binding for (1) the fully assembled form with 70 binding sites and (2) the isolated chains with 7 binding sites of Octopus dofleini hemocyanin. The striking difference in the cooperativities of the two ligands for the assembled decamer is revealed through an examination of the binding capacities and the partition coefficient, determined as functions of the activities of both ligands. A global analysis of the data sets supported a two-state allosteric model assuming an allosteric unit of 7. Higher level allosteric interactions were not indicated. This contrasts to results obtained for arthropod hemocyanins. Oxygen and carbon monoxide experiments performed on the isolated subunit chain confirmed the presence of functional heterogeneity reported previously [Miller, K. (1985) Biochemistry 24, 4582-4586]. The analysis shows two types of binding sites in the ratio of 4:3.     

Is the oxygen atom of carbon monoxide coordinated to the copper of hemocyanin?

The carbon monoxide binding site of hemocyanins was studied by comparing the isotope shift of the CO-stretching frequencies in CO-hemocyanins with that of carbon monoxide diethylenetriaminecopper(I)tetraphenylboron in which the carbon atom of CO is coordinated to the copper. Coordination by the carbon atom of CO in CO-hemocyanin is suggested.     

Nested allosteric interaction in tarantula hemocyanin revealed through the binding of oxygen and carbon monoxide

We have examined the competitive binding of oxygen and carbon monoxide to the multisubunit hemocyanin of the tarantula Eurypelma californicum. Employment of high-precision thin-layer methods has enabled detailed characterization of the pure oxygen and pure carbon monoxide binding curves, as well as binding curves performed under mixed-gas conditions. The pure oxygen binding curve and the displacement of oxygen by carbon monoxide at full ligand saturation are highly cooperative, but in the absence of oxygen, carbon monoxide binds noncooperatively. The results were analyzed globally within the framework of a nested allosteric model [Robert, C.H., Decker, H., Richey, B., Gill, S.J., & Wyman, J. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 1891-1895] which takes into account the hierarchy of subunit structure present in the macromolecule. The use of two ligands enables one to recognize two distinct levels of allosteric interaction functioning in the protein assembly. The binding characteristics of the allosteric states demonstrated for Eurypelma follow a similar pattern as those found earlier for Homarus americanus.     

Kinetics of carbon monoxide binding to fully and partially reduced human hemoglobin valency hybrids.

The kinetics of carbon monoxide binding following fast reduction of the valency hybrids alpha2+betaCO2 and alphaCO2beta+2 by hydrated electrons have been studied at different degrees of reduction. The results show that at pH 6.0 and 7.0 reduction of one heme group yields a species which reacts fast with carbon monoxide (rate constant of the order of 10(6) M-1S-1). At pH 6.0 the intermediates alphaCO2beta2 and alpha2betaCO2 bind carbon monoxide with a rate characteristic of the T state. At pH 7.0 alphaCO2beta2 is for the greater part in the T state, while in the case of alpha2betaCO2 the R and the T state are about equally populated.     

Binding of oxygen and carbon monoxide to the hemocyanin from the spiny lobster

A high precision, two-dimensional study of oxygen and carbon monoxide binding to Panulirus interruptus hemocyanin has been carried out. Global data analysis of three types of experiments, probing the molecule in its various states of CO and O2 ligation, revealed the entire hexamer to be the basic allosteric unit involved in a two-state mechanism. The co-operativity and linkage of the two ligands are presented in terms of derivative Hill plot surfaces extended along co-ordinates of CO and O2 activities giving a detailed and comprehensive view of the binding behavior. Among the findings is an apparent high co-operativity of carbon monoxide binding at high oxygen activity. The results are discussed in view of a general mechanism for co-operative behavior found in larger hemocyanin aggregates concerning "nested" allosteric interactions.     

Binding of oxygen and carbon monoxide to arthropod hemocyanin: an allosteric analysis

The binding of oxygen and carbon monoxide to hemocyanin from the mangrove crab Scylla serrata and the lobster Homarus americanus has been studied by thin-layer optical absorption and front face fluorescence techniques. Three types of experiments were performed on subunit and oligomeric preparations of each hemocyanin: oxygen binding, carbon monoxide binding, and oxygen-carbon monoxide competition studies. The results obtained from the subunit preparations of dissociated oligomers from both hemocyanins show that the binding site can be ligated by either one oxygen or one carbon monoxide. The binding results obtained with the oligomeric samples of hemocyanin from both species cannot be described by the two-state MWC model [Monod, J., Wyman, J., & Changeux, J. P. (1965) J. Mol. Biol. 12, 88-118] since the data from the three types of binding experiments cannot be fit with a single set of binding constants. The MWC model has been extended by including a third allosteric form, and an analysis based on the three-state model is able to fit the data from the three types of experiments with the same set of binding constants. The comparison of the oxygen to carbon monoxide affinity ratios (kO2/kCO) indicates that the structure around the binding site of subunits in the T form oligomer is similar to that of the free subunits. The oligomeric forms of both these hemocyanins bind carbon monoxide with a weak but definite positive cooperativity. An analysis of the affinity ratios for the T, S, and R forms suggests that the high affinity of the R form results from a specific interaction between oxygen and binding site.     

Reaction of carbon monoxide with hemocyanin: Stereochemical effects of a non-bridging ligand

The carbon monoxide binding equilibria and kinetics of a number of molluscan and arthropodal hemocyanins have been investigated employing the visible luminescence of the carbon monoxide-copper complex.Proteins from both phyla, in oligomeric and monomeric form, bind carbon monoxide non-co-operatively; the reaction is largely enthalpy driven is associated with a small unfavourable entropy change.Molluscan hemocyanins display a carbon monoxide affinity (p₅₀ = 1 to 10mm Hg) higher than that of arthropodal hemocyanins (p₅₀ = 100 to 700mm Hg), and only Panulirus interruptus hemocyanin, among those studied here, exhibits a small Bohr effect. The observed differences in equilibrium constant are kinetically reflected in differences in the carbon monoxide dissociation rate constant, which ranges from 20 to 70 s^?1 for molluscan hemocyanins and from 200 to 9000 s^?1 for arthropodal hemocyanins; on the other hand the differences in the combination rate constants between the two phyla are considerably smaller. A comparison of the equilibrium and kinetic results shows some discrepancies between the two sets of data, suggesting that carbon monoxide binding may be governed by a complex mechanism.The correlation between the ligand binding properties and the stereochemistry of the active site is discussed in the light of the knowledge that, while oxygen is bound to both copper atoms in a site, carbon monoxide is a “non-bridging” ligand, being bound to only one of the metals.     

Stereochemistry of carbon monoxide binding to myoglobin and hemoglobin

The binding of carbon monoxide to myoglobin and hemoglobin is examined to determine the origin of the deviation of the FeCO geometry from that found in model systems. Possible distortions due to protein-ligand interactions are analyzed with special attention to protein relaxation. It is estimated that the protein can support a strain of less than 10 kcal per mole; this may be sufficient to produce a displacement of a linear FeCO unit from the heme normal.     

Influence of carbon monoxide on hemoglobin-oxygen binding.

The oxygen dissociation curve and Bohr effect were measured in normal whole blood as a function of carboxyhemoglobin concentration [HbCO]. pH was changed by varying CO2 concentration (CO2 Bohr effect) or by addition of isotonic NaOH or HCl at constant PCO2 (fixed acid Bohr effect). As [HbCO] varied through the range of 2, 25, 50, and 75%, P50 was 26.3, 18.0, 11.6, and 6.5 mmHg, respectively. CO2 Bohr effect was highest at low oxygen saturations. This effect did not change as [HbCO] was increased. However, as [HbCO] was increased from 2 to 75%, the fixed acid Bohr factor increased in magnitude from -0.20 to -0.80 at very low oxygen saturations. The effect of molecular CO2 binding (carbamino) on oxygen affinity was eliminated at high [HbCO]. These results are consistent with the initial binding of O2 or CO to the alpha-chain of hemoglobin. The results also suggest that heme-heme interaction is different for oxygen than for carbon monoxide.     

Dynamics of carbon monoxide binding to cystathionine beta-synthase

Cystathionine beta-synthase (CBS) condenses homocysteine, a toxic metabolite, with serine in a pyridoxal phosphate-dependent reaction. It also contains a heme cofactor to which carbon monoxide (CO) or nitric oxide can bind, resulting in enzyme inhibition. To understand the mechanism of this regulation, we have investigated the equilibria and kinetics of CO binding to the highly active catalytic core of CBS, which is dimeric. CBS exhibits strong anticooperativity in CO binding with successive association constants of 0.24 and 0.02 microm(-1). Stopped flow measurements reveal slow CO association (0.0166 s(-1)) limited by dissociation of the endogenous ligand, Cys-52. Rebinding of CO and of Cys-52 following CO photodissociation were independently monitored via time-resolved resonance Raman spectroscopy. The Cys-52 rebinding rate, 4000 s(-1), is essentially unchanged between pH 7.6 and 10.5, indicating that the pK(a) of Cys-52 is shifted below pH 7.6. This effect is attributed to the nearby Arg-266 residue, which is proposed to form a salt bridge with the dissociated Cys-52, thereby inhibiting its protonation and slowing rebinding to the Fe. This salt bridge suggests a pathway for enzyme inactivation upon CO binding, because Arg-266 is located on a helix that connects the heme and pyridoxal phosphate cofactor domains.     

Infrared studies of carbon monoxide binding to carbon monoxide dehydrogenase/acetyl-CoA synthase from Moorella thermoacetica

Carbon monoxide dehydrogenase/acetyl-CoA synthase (CODH/ACS) is a bifunctional enzyme that catalyzes the reversible reduction of carbon dioxide into carbon monoxide and the coupled synthesis of acetyl-CoA from the carbon monoxide produced. Exposure of CODH/ACS from Moorella thermoacetica to carbon monoxide gives rise to several infrared bands in the 2100-1900 cm(-1) spectral region that are attributed to the formation of metal-coordinated carbon monoxide species. Infrared bands attributable to M-CO are not detected in the as-isolated enzyme, suggesting that the enzyme does not contain intrinsic metal-coordinated CO ligands. A band detected at 1996 cm(-1) in the CO-flushed enzyme is assigned as arising from CO binding to a metal center in cluster A of the ACS subunit. The frequency of this band is most consistent with it arising from a terminally coordinated Ni(I) carbonyl. Multiple infrared bands at 2078, 2044, 1970, 1959, and 1901 cm(-1) are attributed to CO binding at cluster C of the CODH subunit. All infrared bands attributed to metal carbonyls decay in a time-dependent fashion as CO(2) appears in the solution. These observations are consistent with the enzyme-catalyzed oxidation of carbon monoxide until it is completely depleted from solution during the course of the experiments.