Dissecting Dynamic Allosteric Pathways Using Chemically Related Small-Molecule Activators.

The allosteric mechanism of the heterodimeric enzyme imidazole glycerol phosphate synthase was studied in detail with solution nuclear magnetic resonance spectroscopy and molecular dynamics simulations. We studied IGPS in complex with a series of allosteric activators corresponding to a large range of catalytic rate enhancements (26- to 4,900-fold), in which ligand binding is entropically driven. Conformational flexibility on the millisecond timescale plays a crucial role in intersubunit communication. Carr-Purcell-Meiboom-Gill relaxation dispersion experiments probing Ile, Leu, and Val methyl groups reveal that the apo- and glutamine-mimicked complexes are static on the millisecond timescale. Domain-wide motions are stimulated in the presence of the allosteric activators. These studies, in conjunction with ligand titrations, demonstrate that the allosteric network is widely dispersed and varies with the identity of the effector. Furthermore, we find that stronger allosteric ligands create more conformational flexibility on the millisecond timescale throughout HisF. This domain-wide loosening leads to maximum catalytic activity.

What's in your buffer? Solute altered millisecond motions detected by solution NMR.

To date, little work has been conducted on the relationship between solute and buffer molecules and conformational exchange motion in enzymes. This study uses solution NMR to examine the effects of phosphate, sulfate, and acetate in comparison to MES- and HEPES-buffered references on the chemical shift perturbation and millisecond, chemical, or conformational exchange motions in the enzyme ribonuclease A (RNase A), triosephosphate isomerase (TIM) and HisF. The results indicate that addition of these solutes has a small effect on (1)H and (15)N chemical shifts for RNase A and TIM but a significant effect for HisF. For RNase A and TIM, Carr-Purcell-Meiboom-Gill relaxation dispersion experiments, however, show significant solute-dependent changes in conformational exchange motions. Some residues show loss of millisecond motions relative to the reference sample upon addition of solute, whereas others experience an enhancement. Comparison of exchange parameters obtained from fits of dispersion data indicates changes in either or both equilibrium populations and chemical shifts between conformations. Furthermore, the exchange kinetics are altered in many cases. The results demonstrate that common solute molecules can alter observed enzyme millisecond motions and play a more active role than what is routinely believed.

Comparison of cyanide-degrading nitrilases.

Recombinant forms of three cyanide-degrading nitrilases, CynD from Bacillus pumilus C1, CynD from Pseudomonas stutzeri, and CHT from Gloeocercospora sorghi, were prepared after their genes were cloned with C-terminal hexahistidine purification tags and expressed in Escherichia coli, and the enzymes purified using nickel-chelate affinity chromatography. The enzymes were compared with respect to their pH stability, thermostability, metal tolerance, and kinetic constants. The two bacterial genes, both cyanide dihydratases, were similar with respect to pH range, retaining greater than 50% activity between pH 5.2 and pH 8 and kinetic properties, having similar K(m) (6-7 mM) and V(max) (0.1 mmol min(-1) mg(-1)). They also exhibited similar metal tolerances. However, the fungal CHT enzyme had notably higher K(m) (90 mM) and V(max) (4 mmol min(-1) mg(-1)) values. Its pH range was slightly more alkaline (retaining nearly full activity above 8.5), but exhibited a lower thermal tolerance. CHT was less sensitive to Hg(2+) and more sensitive to Pb(2+) than the CynD enzymes. These data describe, in part, the current limits that exist for using nitrilases as agents in the bioremediation of cyanide-containing waste effluent, and may help serve to determine where and under what conditions these nitrilases may be applied.

Methenyltetrahydrofolate cyclohydrolase is rate limiting for the enzymatic conversion of 10-formyltetrahydrofolate to 5,10-methylenetetrahydrofolate in bifunctional dehydrogenase-cyclohydrolase enzymes.

The kinetic properties of three methylenetetrahydrofolate dehydrogenase-cyclohydrolase (D/C) enzymes (the NADP-dependent bifunctional domain of the human cytoplasmic trifunctional enzyme, the human mitochondrial NAD-dependent bifunctional enzyme, and the NAD(P)-dependent bifunctional enzyme from Photobacterium phosphoreum) were determined in both forward and reverse directions. In the forward direction, the enzymes possess widely different ratios of kcat C/Kcat D, but all channel methenylH4folate produced by the D activity to the C activity with approximately the same efficiency. A deuterium isotope effect is observed with the human NADP-dependent enzyme in both forward and reverse dehydrogenase assays, consistent with hydride transfer being rate limiting for the interconversion of methenyl- and methyleneH4folate. However, no kinetic isotope effect is observed for the overall reverse reaction (formylH4folate to methyleneH4folate). We devised an assay to measure the reverse cyclohydrolase activity independent of the dehydrogenase, and determined that the Kcat (overall reverse) for each enzyme is approximately equal to the Kcat for its reverse cyclohydrolase activity. Therefore, the rate-limiting step in the overall reverse reaction is not hydride transfer by the dehydrogenase, but the production of methenylH4folate catalyzed by the cyclohydrolase. The reverse cyclohydrolase activities of the NADP-dependent D/C and the P. phosphoreum enzymes, but not the mitochondrial NAD-dependent enzyme, can be stimulated 2-fold by the addition of 2',5'-ADP. The results suggest that the cyclohydrolases of the human NADP dependent and P. phosphoreum enzymes are optimized to catalyze the reverse reaction in the presence of bound coenzyme. These results imply that essentially all of the methenylH4folate produced by the cyclohydrolase in the reverse reaction is channeled to the dehydrogenase.

Adenine deaminase and adenine utilization in Saccharomyces cerevisiae.

Compared with other purine salvage and nitrogen catabolism enzymatic activities, adenine deaminase (adenine aminohydrolase [AAH]; EC 3.5.4.2) activity in Saccharomyces cerevisiae is uniquely regulated. AAH specific activity is not induced by adenine and is reduced sevenfold when cells are cultivated in medium containing proline in place of ammonium as the sole nitrogen source. Exogenous adenine enters metabolic pathways primarily via the function of either AAH or adenine phosphoribosyltransferase (APRT; EC 2.4.2.7). Exogenous adenosine cannot normally be utilized as a purine source. Strains efficiently utilized adenosine or inosine when grown in pH 4.5 medium containing Triton X-100. A recessive mutation permitting utilization of adenosine or inosine in standard media was isolated. In both situations, growth of purine auxotrophs required either AAH or APRT activity. With medium containing either ammonium or proline as a nitrogen source, minimum doubling times of purine auxotrophs deficient in either APRT or AAH were measured. In proline-based medium, AAH and APRT permitted equal utilization of exogenous adenine. In ammonium-based medium, the absence of APRT increased the minimum doubling time by 50%. Similar experiments using sufficient exogenous histidine to feedback inhibit histidine biosynthesis failed to affect the growth rates of adenine auxotrophs blocked in AAH or APRT, indicating that the histidine-biosynthetic pathway does not play a significant role in adenine utilization. The gene that encodes AAH in S. cerevisiae was isolated by complementation using yeast strain XD1-1, which is deficient in AAH, APRT, and purine synthesis. A 1.36-kb EcoRI-SphI fragment was demonstrated to contain the structural gene for AAH by expressing this DNA in Escherichia coli under control of the trp promoter-operator. Northern (RNA) studies using the AAH-, APRT-, and CDC3-coding regions indicated that AAH regulation was not mediated at the level of transcription or mRNA degradation.