Conformational dynamics of the active site loop of S-adenosylmethionine synthetase illuminated by site-directed spin labeling

S-adenosylmethionine synthetase (ATP: l-methionine S-adenosyltransferase, methionine adenosyltransferase, a.k.a. MAT) is one of numerous enzymes that have a flexible polypeptide loop that moves to gate access to the active site in a motion that is closely coupled to catalysis. Crystallographic studies of this tetrameric enzyme have shown that the loop is closed in the absence of bound substrates. However, the loop must open to allow substrate binding and a variety of data indicate that the loop is closed during the catalytic steps. Previous kinetic studies indicate that during turnover loop motion occurs on a time scale of 10−2 s, ca. 10-fold faster than chemical transformations and turnover. Site-directed spin labeling has been used to introduce nitroxide groups at two positions in the loop to illuminate how the motion of the loop is affected by substrate binding. The two loop mutants constructed, G105C and D107C, retain wild type levels of MAT activity; attachment of a methanethiosulfonate spin label to convert the cysteine to the “R1” residue reduced the kcat only for the labeled D107R1 form (7-fold). The Km value for methionine increased 2- to 4-fold for the cysteine mutants and 2- to 7-fold for the labeled proteins, whereas the Km for ATP was changed by at most 2-fold. EPR spectra for both labeled proteins are nearly identical and show the presence of two major spin label environments with rotational diffusion rates differing by ∼10-fold; the slower rate is ca. 4-fold faster than the estimated protein rotational rate. The spectra are not altered by addition of substrates or products. At both positions the less mobile conformation constitutes ca. 65% of the total species, indicating an equilibrium that only slightly favors one form, that in which the label is more immobilized. The equilibrium constant that relates the two forms is comparable to the equilibrium constant of 1.5 for a conformational change that was previously deduced from the viscosity dependence of the rate of AdoMet formation. The results suggest that the motion of the loop may be an intrinsic property of the protein and not be strictly ligand modulated.