THE EQUILIBRIUM BETWEEN CYTOCHROME OXIDASE AND CARBON MONOXIDE

doi:10.1085/jgp.40.4.593

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ARTICLE

THE EQUILIBRIUM BETWEEN CYTOCHROME OXIDASE AND CARBON MONOXIDE

George Wald ¹ and David W. Allen ¹

¹ From the Biological Laboratories, Harvard University, Cambridge

An evolution argument which attempted to trace the developmentof hemoglobins from such respiratory pigments as cytochromeoxidase presupposed that the latter possesses, in addition toits high affinity for oxygen, an approximately hyperbolic equilibriumfunction, and little if any Bohr effect (decline in affinityfor oxygen with rise in acidity). Since cytochrome oxidase,unlike hemoglobin, is irreversibly oxidized by oxygen, the presentexperiments examine its combination with carbon monoxide, withwhich, like hemoglobin, it yields a true equilibrium. In allknown hemoglobins the form of the equilibrium function and thevigor of the Bohr effect are similar with carbon monoxide andwith oxygen, so that observations involving the former gas arerelevant to the relations of the latter.

The equilibrium functionof cytochrome oxidase with carbon monoxide—percentage saturationvs. partial pressure of CO—is slightly inflected (in theHill equation n = 1.26; for a hyperbola, n = 1). No Bohr effectis present in the range of pH 7–8. The pressure of carbonmonoxide at which half-saturation occurs (p₅₀) is about 0.17mm. at 10–13°C. The affinity for carbon monoxide istherefore higher than commonly supposed.

These properties areconsistent with the evolution argument. They are important alsofor the physiological functioning of cytochrome oxidase, thenearly hyperbolic equilibrium function facilitating a high degreeof saturation, and the lack of Bohr effect making this enzymeimpervious to hyperacidity.

The slight inflection of the equilibriumfunction shows that the Fe-porphyrin units of cytochrome oxidaseinteract to a degree, hence that the enzyme must contain morethan one such unit per molecule. It is suggested that in cytochromeoxidase two Fe-porphyrin groups may unite with one oxygen inthe manner Fe⁺⁺-O₂-Fe⁺⁺; and that the evolution of hemoglobinsproceeded over a first stage in which the hemes were separatedso that each combines with only one molecule of oxygen, so tendingto remain reduced; to a further stage in which the separatedhemes interact through the protein to facilitate one anotherin combining with oxygen.

Submitted on August 3, 1956

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