Investigation of the Local Structure and Dynamics of the H Subunit of the Mitochondrial Glycine Decarboxylase Using Heteronuclear NMR Spectroscopy

Abstract

The lipoate-dependent H protein plays a pivotal role in the catalytic cycle of the glycine decarboxylase complex (GDC), undergoing reducing methylamination, methylene transfer, and oxidation. The local structure and backbone dynamics of the methylamine-loaded H (Hmet), oxidized H (Hox), and H apoprotein (Hapo) have been investigated in solution. Filtered NOESY experiments using a [¹³C]Hmet as well as comparison of the heteronuclear shifts between the Hox and Hmet proteins demonstrate that the methylamine group is located inside a cleft of the protein. Furthermore, this group appears to be locked in this configuration as indicated by the high value of the activation energy (37 kcal/mol) of the global unloading reaction and by its restricted mobility, deduced from ¹³C relaxation measurements. Comparisons of the ¹H and ¹⁵N chemical shifts and ¹⁵N relaxation in the three forms suggest that part of the lipoyl−lysine arm interacts with the protein polypeptide in the Hox and Hmet. The major change induced by the loading of the methylamine group concerns the C-terminal helix whose mobility becomes completely restricted compared to those of the Hox and Hapo. This C-terminal helix exhibits different reorientational characteristics in the three forms, which can be explained in the Hapo by a model consisting of a twisting motion about an axis passing through the helix. Our results indicate that the model of a freely swinging arm proposed for other lipoate-containing proteins is not acceptable in solution for the GDC. The implication of this observation in terms of the mechanism of the interaction of the H protein with the T protein, its physiological partner during the catalytic cycle, is discussed.