Abstract
The oxaloacetate decarboxylase primary Na(+) pump (OAD) is an essential membrane protein complex that functions in the citrate fermentation pathway of some pathogenic bacteria under anaerobic conditions. OAD contains three different subunits: Oad-α, a biotinylated extrinsic protein that catalyzes the α-ketodecarboxylation of oxaloacetate; Oad-γ, a structural bitopic membrane protein whose cytosolic tail (named as Oad-γ') binds tightly to Oad-α; and Oad-β, a multispan transmembrane α-helical protein that constitutes the Na(+) channel. How OAD is organized structurally at the membrane and what the molecular determinants are that lead to an efficient energy coupling mechanism remain elusive. In the present work, we elucidate the stoichiometry of the native complex as well as the low resolution structure of the peripheral components of OAD (Oad-α and Oad-γ') by small angle x-ray scattering. Our results point to a quaternary assembly similar to the pyruvate carboxylase complex organization. Herein, we propose a model in which the association in pairs of Oad-α dimers, mediated by Oad-γ, results in the acquisition of a functional oligomeric state at the bacterial membrane. New structural insights for the conformational rearrangements associated with the carboxylbiotin transfer reaction within OAD are provided.
Highlights
The main conclusions derived from our study are: (i) binding of Oad-␥ seems to reduce the intrinsic flexibility of Oad-␣ around residues 480 – 520 by stabilizing the 4-stranded  sandwich with Oad-␥ likely acting as a hinge; (ii) Oad-␥ promotes the dimerization of Oad-␣ dimers in such a way that Oad-␣/␥Ј association and Oad-␣ tetramerization have a reciprocal dependence; (iii) Oad␣/␥Ј organization in solution resembles that of the pyruvate carboxylase (PC)
A swing mechanism has been considered for oxaloacetate decarboxylase primary Na؉ pump (OAD) in which the carboxyl group removed from oxaloacetate at the active site of the carboxyl transferase (CT) domain of Oad-␣ is transferred via the biotin prosthetic group of its own biotin carboxyl carrier (BCC) domain to the decarboxylation site of Oad- at the membrane [17]
Based on our recent experimental results, sequence comparisons and structural homology considerations as described above, we propose a new model of carboxylbiotin transfer from the CT domain to the decarboxylation site at the membrane for the OAD complex (Fig. 8)
Summary
Alytic reaction on OAD, the crystal structure of the CT domain demonstrated that Zn(II) is coordinated to Oad-␣ [9], which resembles the metal requirements for the catalytic activity of other members of the BC family [11]. As an essential point in understanding the mechanisms that govern the coordination of events within the OAD complex, we have explored the structural organization of Oad-␣ and its interaction with the soluble domain of Oad-␥ (Oad␥Ј) by means of biochemical analysis in combination with homology modeling and structural analyses by small angle x-ray solution scattering (SAXS). Our results strongly suggest that, within its native complex, Oad-␣ shares similarities with the tetrameric pyruvate carboxylase (PC) protein with respect to the intermolecular transfer of the BCC domain between active sites during the reaction cycle (for a review, see Ref. 16). New mechanistic insights into the conformational rearrangements associated with the carboxylbiotin transfer within the OAD complex are discussed
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