Probing the role of dynamics in hydride transfer catalyzed by lactate dehydrogenase.

The dynamic nature of the interconversion of pyruvate to lactate as catalyzed by lactate dehydrogenase (LDH) is characterized by laser-induced temperature jump relaxation spectroscopy with a resolution of 20 ns. An equilibrium system of LDH.NADH plus pyruvate and LDH.NAD+ plus lactate is perturbed by a sudden T-jump, and the relaxation of the system is monitored by NADH emission and absorption changes. The substrate binding pathway is observed to be similar, although not identical, to previous work on substrate mimics: an encounter complex is formed between LDH.NADH and pyruvate, which collapses to the active Michaelis complex. The previously unresolved hydride transfer event is characterized and separated from other unimolecular isomerizations of the protein important for the catalytic mechanism, such as loop closure, a slower step, and faster events on the nanosecond-microsecond timescales whose structural basis is not understood. The results of this study show that this approach can be applied quite generally to enzyme systems and report on the dynamic nature of proteins over a very wide time range.

Effects of cell volume regulating osmolytes on glycerol 3-phosphate binding to triosephosphate isomerase.

During cell volume regulation, intracellular concentration changes occur in both inorganic and organic osmolytes in order to balance the extracellular osmotic stress and maintain cell volume homeostasis. Generally, salt and urea increase the Km's of enzymes and trimethylamine N-oxide (TMAO) counteracts these effects by decreasing Km's. The hypothesis to account for these effects is that urea and salt shift the native state ensemble of the enzyme toward conformers that are substrate-binding incompetent (BI), while TMAO shifts the ensemble toward binding competent (BC) species. Km's are often complex assemblies of rate constants involving several elementary steps in catalysis, so to better understand osmolyte effects we have focused on a single elementary event, substrate binding. We test the conformational shift hypothesis by evaluating the effects of salt, urea, and TMAO on the mechanism of binding glycerol 3-phosphate, a substrate analogue, to yeast triosephosphate isomerase. Temperature-jump kinetic measurements promote a mechanism consistent with osmolyte-induced shifts in the [BI]/[BC] ratio of enzyme conformers. Importantly, salt significantly affects the binding constant through its effect on the activity coefficients of substrate, enzyme, and enzyme-substrate complex, and it is likely that TMAO and urea affect activity coefficients as well. Results indicate that the conformational shift hypothesis alone does not account for the effects of osmolytes on Km's.

Lactate dehydrogenase undergoes a substantial structural change to bind its substrate.

Employing temperature-jump relaxation spectroscopy, we investigate the kinetics and thermodynamics of the formation of a very early ternary binding intermediate formed when lactate dehydrogenase (LDH) binds a substrate mimic on its way to forming the productive LDH/NADH.substrate Michaelis complex. Temperature-jump scans show two distinct submillisecond processes are involved in the formation of this ternary binding intermediate, called the encounter complex here. The on-rate of the formation of the encounter complex from LDH/NADH with oxamate (a substrate mimic) is determined as a function of temperature and in the presence of small concentrations of a protein destabilizer (urea) and protein stabilizer (TMAO). It shows a strong temperature dependence with inverse Arrhenius behavior and a temperature-dependent enthalpy (heat capacity of 610 +/- 84 cal/Mol K), is slowed in the presence of TMAO and speeded up in the presence of urea. These results suggest that LDH/NADH occupies a range of conformations, some competent to bind substrate (open structure; a minority population) and others noncompetent (closed), in fast equilibrium with each other in accord with a select fit model of binding. From the thermodynamic results, the two species differ in the rearrangement of low energy hydrogen bonds as would arise from changes in internal hydrogen bonding and/or increases in the solvation of the protein structure. The binding-competent species can bind ligand at or very near diffusion-limited speeds, suggesting that the binding pocket is substantially exposed to solvent in these species. This would be in contrast to the putative closed structure where the binding pocket resides deep within the protein interior.

Primary folding dynamics of sperm whale apomyoglobin: core formation.

The structure, thermodynamics, and kinetics of heat-induced unfolding of sperm whale apomyoglobin core formation have been studied. The most rudimentary core is formed at pH(*) 3.0 and up to 60 mM NaCl. Steady state for ultraviolet circular dichroism and fluorescence melting studies indicate that the core in this acid-destabilized state consists of a heterogeneous composition of structures of approximately 26 residues, two-thirds of the number involved for horse heart apomyoglobin under these conditions. Fluorescence temperature-jump relaxation studies show that there is only one process involved in Trp burial. This occurs in 20 micro s for a 7 degrees jump to 52 degrees C, which is close to the limits placed by diffusion on folding reactions. However, infrared temperature jump studies monitoring native helix burial are biexponential with times of 5 micro s and 56 micro s for a similar temperature jump. Both fluorescence and infrared fast phases are energetically favorable but the slow infrared absorbance phase is highly temperature-dependent, indicating a substantial enthalpic barrier for this process. The kinetics are best understood by a multiple-pathway kinetics model. The rapid phases likely represent direct burial of one or both of the Trp residues and parts of the G- and H-helices. We attribute the slow phase to burial and subsequent rearrangement of a misformed core or to a collapse having a high energy barrier wherein both Trps are solvent-exposed.

Toward an understanding of the role of dynamics on enzymatic catalysis in lactate dehydrogenase.

The motions of key residues at the substrate binding site of lactate dehydrogenase (LDH) were probed on the 10 ns to 10 ms time scale using laser-induced temperature-jump relaxation spectroscopy employing both UV fluorescence and isotope-edited IR absorption spectroscopy as structural probes. The dynamics of the mobile loop, which closes over the active site and is important for catalysis and binding, were characterized by studies of the inhibitor oxamate binding to the LDH/NADH binary complex monitoring the changes in emission of bound NADH. The bound NAD-pyruvate adduct, whose pyruvate moiety likely interacts with the same residues that interact with pyruvate in its ternary complex with LDH, served as a probe for any relative motions of active site residues against the substrate. The frequencies of its C=O stretch and -COO(-) antisymmetric stretch shift substantially should any relative motion of the polar moieties at the active site (His-195, Asp-168, Arg-109, and Arg-171) occur. The dynamics associated with loop closure are observed to involve several steps with motions from 1 to 300 microms. Apart from the "melting" of a few residues on the protein's surface, no kinetics were observed on any time scale in experiments of the bound NAD-pyr adduct although the measurements were made with a high degree of accuracy, even for final temperatures close to the unfolding transition of the protein. This is contrary to simple physical considerations and models. These results show that, once a productive protein/substrate complex is formed, the binding pocket is very rigid with very little, if any, motion apart from the mobile loop. The results also show that loop opening involves concomitant movement of the substrate out of the binding pocket.