The composition of the pyruvate dehydrogenase complex from Azotobacter vinelandii

Abstract

An improved purification procedure of the pyruvate dehydrogenase complex of Azotobacter vinelandii is described. This procedure minimizes losses of components and results in the isolation of the pure complex with a specific activity of 15–19 U/mg and an overall yield of 40%.The chain ratio of the three components was determined by covalent modification of the lysine residues with trinitrobenzene sulfonic acid, followed by separation of the components on sodium dodecyl sulfate gels. These determinations yielded an average chain ratio of 1.3:1:0.5 for E₁:E₂:E₃ respectively. Based on E₂ this corresponds with a minimum molecular mass of approximately 216 kDa. Because the molecular mass of the complex has been determined previously to be 800 ± 50 kDa, it is concluded that the complex as isolated from A. vinelandii is based on a tetramer of E₂ chains.The complex can be resolved into its individual components, which can be recombined to yield a fully active complex. Titration of E₂E₃ subcomplexes with E₁ resulted in maximum complex activity at an E₁/E₂ ratio of 1.5–1.6. Similar titrations of E₁E₂ subcomplexes with E₃ resulted in maximum activity at an E₃/E₂ ratio of 0.45–0.55. From these experiments it is concluded that the complex has maximum activity with a composition of three E₁ dimers, one E₂ tetramer and one E₃ dimer. With excess of either E₁ or E₃ a decrease in activity is observed which indicates competition between these components for binding sites on E₂.As shown before [Bosma, H. J., de Kok, A., Markwijk, B. W., and Veeger, C. (1984) Eur. J. Biochem. 140, 273–280], the isolated E₂ component is composed of 32 peptide chains of 66 kDa each. Upon addition of E₁ or E₃, E₂ dissociates into tetramers. Dissociation is complete upon the addition of four E₁ dimers of four E₃ dimers per E₂ tetramer. Addition of E₁ to saturated E₂E₃ subcomplex or E₃ to saturated E₁E₂ subcomplex did not result in extra binding but rather in displacement of bound E₃ or E₁ respectively. It is therefore concluded that the binding sites of E₁ and E₃ to the E₂ chains are either identical or so closely spaced that steric hindrance prevents simultaneous binding of both components.A model is presented based on the cubic structure of the isolated E₂ component. In this model the 32 E₂ peptide chains are arranged in tetramers in the corners of the cube. This model is discussed in connection with the existing model for the Escherichia coli complex.