Limited proteolysis of a disulfide-linked apoA-I dimer in reconstituted HDL.

The apolipoprotein A-I(Milano) (apoA-I(M)) is a molecular variant of apoA-I characterized by the Arg(173)-->Cys substitution, leading to the formation of homodimers A-I(M)/A-I(M). Upon interaction with palmitoyloleoylphosphatidylcholine, A-I(M)/A-I(M) forms only two species of reconstituted HDL (rHDL) particles, with diameters of 7.8 and 12.5 nm. We used limited proteolysis to analyze the conformation of A-I(M)/A-I(M) in the two rHDL particles, in comparison with that of apoA-I in rHDL of similar size. ApoA-I in the small, 7.8-nm rHDL is degraded to a greater extent (50% after 6 h) than in the large rHDL (<10% degraded after 6 h). The protease susceptibility of A-I(M)/A-I(M) in small and large rHDL is instead remarkably the same, with A-I(M)/A-I(M) being much more sensitive to proteolytic digestion (50% degraded after 10 min) than apoA-I. The identification of the proteolytic fragments by immunoblotting, N-terminal sequencing, and molecular mass determination, shows that the N-terminus of both proteins is resistant to proteolysis, with six cleavage sites located in the central and carboxy-terminal portions of the molecules. Cleavage in the middle of apoA-I occurs at distinct sites in 7.8-nm (Lys(118)) and 12.7-nm (Arg(123)) rHDL, indicating a different conformation in small and large rHDL particles. The A-I(M)/A-I(M) instead adopts a unique and identical conformation in small and large rHDL, with the carboxy-terminal portion of the molecule being remarkably more accessible to the proteases than in apoA-I. This suggests the presence of a novel carboxy-terminal domain in A-I(M)/A-I(M), not organized in a compact structure and not shared by wild-type apoA-I, which may account for the unique functional properties of A-I(M)/A-I(M).

Probing the active site of L-aspartate oxidase by site-directed mutagenesis: role of basic residues in fumarate reduction.

L-Aspartate oxidase is a very particular oxidase which behaves as a fumarate reductase in anaerobic conditions. Its primary and tertiary structures present remarkable similarity with the soluble fumarate reductase (FRD) from Shewanella frigidimarina and the flavin subunit of the membrane-bound fumarate reductase from Escherichia coli and Wolinella succinogenes. This and other extensive similarities are consistent with the idea that a common catalytic mechanism for the reduction of fumarate operates for all members of this enzyme group and that the key residues involved in the substrate binding and catalysis are conserved. This manuscript reports information about the role of these basic residues in L-aspartate oxidase: R290, R386, H244, and H351. By means of site-directed mutagenesis, R290 and R386 are mutated to Leu and H351 and H244 are mutated both to Ala and Ser. H351, H244, and R386 mutants bind substrate analogues with higher dissociation constants and present lower k(cat)/K(m) values in the reduction of fumarate. Therefore, the results indicate that R386, H244, and H351 are important for the binding of the substrate fumarate and may play an important but not essential role in catalysis. R290, on the contrary, is mainly involved in catalysis and not in substrate binding since its mutation abolishes the catalytic activity without lowering the affinity of the enzyme for the substrate. The redox properties of all the mutants are identical to the wild-type. The findings are consistent with a model of L-aspartate oxidase active site based on the hypothesis proposed for the soluble FRD from S. fridimarina.

Covalent flavinylation of L-aspartate oxidase from Escherichia coli using N6-(6-carboxyhexyl)-FAD succinimidoester.

L-Aspartate oxidase is a flavoprotein catalyzing the first step in the de novo biosynthesis of pyridine nucleotides in E. coli. Binding of FAD to L-aspartate oxidase is relatively weak (K(d) 6.7 x 10(-7) M), resulting in partial loss of the coenzyme under many experimental conditions. Only the three-dimensional structure of the apo-enzyme has been obtained so far. In order to probe the flavin-binding site of the enzyme, apo-L-aspartate oxidase has been reacted with N6-(6-carboxyhexyl)-FAD succinimidoester. The structural characterization of the resulting N6-(6-carbamoylxyhexyl)FAD-L-aspartate oxidase shows the covalent incorporation of 1 FAD-analog/monomer. Residue Lys38 was identified as the target of the covalent modification. N6-(6-carbamoylxyhexyl)-FAD-L-aspartate oxidase shows only 2% catalytic activity as compared to the native enzyme. Comparison of some properties of the flavinylated and native enzymes suggests that, although the flavin is covalently bound to the former in the region predicted from molecular modeling studies, the microenvironment around the isoallossazine is different in the two forms.