By determining the 13C isotope effect on V/K with both a deuterated and an unlabeled substrate, and the deuterium isotope effect on V/K, it is possible to tell whether the 13C-sensitive and deuterium-sensitive steps are the same or not and, if they are different, to determine which comes first in the mechanism. If the two isotope-sensitive steps are the same, (1) deuteration increases the size of the observed 13C isotope effect, (2) narrow limits can be calculated for the intrinsic deuterium and 13C isotope effects, and (3) wider limits can be placed on the size of the commitments in the system. If an accurate determination of the tritium isotope effect on V/K is available, or if an a-secondary deuterium isotope effect which originates from the same step as the primary deuterium one and the corresponding 13C isotope effect with a-secondary deuterated substrate can be measured, an exact solution for the intrinsic isotope effects and the commitments is possible. With glucose-6-phosphate dehydrogenase, 13K, for label at C-1 of glucose is 0.9920, and 13C isotope effects are 1.0165, 1.03 16, and 1.01 76 with glucose 6-phosphate, glucose-I -d 6-phosphate, and glucose 6-phosphate (with TPN-4-4, respectively. The primary deuterium isotope effect on V/K of %e multistep nature of enzyme-catalyzed reactions usually decreases the magnitudes of observed isotope effects from the intrinsic isotope effects on the bond-breaking steps to somewhat lower values. Though this less than full expression can be a hindrance when trying to correlate isotope effects with transition-state structure, it can be quite useful in determining the relative rates of various steps and the sequence of these steps in a reaction mechanism. Often an isotopic substitution can be made which will affect the rate of only one particular step in a mechanism (typically via a primary deuterium isotope effect). By thus selectively changing the rate of this one step in the reaction mechanism and observing another isotope effect (either a deuterium or a heavy atom isotope effect) which is also expressed on a particular step of a mechanism, one can tell which isotope-sensitive step comes first in the mechanism or whether both isotope effects are on the same step. The concerted vs. stepwise controversy long associated with various enzymatic mechanisms can thus be unambiguously settled in many cases by application of the techniques which we will describe. We will show that the malic enzyme catalyzed oxidative decarboxylation of malate by triphosphopyridine nucleotide (TPN)' is a stepwise reaction with hydride transfer 2.97 and the a-secondary deuterium isotope effect of 1.00 allow calculation of intrinsic isotope effects and commitments in this system: Dk = 5.27, 13k = 1.0408, a-Dk = 1.054, cf = 0.75, and c, = 0.49. When deuterium-and 13C-sensitive steps are different, deuteration decreases the size of the observed I3C isotope effect. The data fit the equation [l3(V/K)H -I]/ [I3( V/K)D -11 = D(V/K)/DK, when the deuterium-sensitive step comes first but fit the equation...
The proteolytic enzyme stromelysin-1 is a member of the family of matrix metalloproteinases and is believed to play a role in pathological conditions such as arthritis and tumor invasion. Stromelysin-1 is synthesized as a proenzyme that is activated by removal of an N-terminal prodomain. The active enzyme contains a catalytic domain and a C-terminal hemopexin domain believed to participate in macromolecular substrate recognition. We have determined the three-dimensional structures of both a C-truncated form of the proenzyme and an inhibited complex of the catalytic domain by X-ray diffraction analysis. The catalytic core is very similar in the two forms and is similar to the homologous domain in fibroblast and neutrophil collagenases, as well as to the stromelysin structure determined by NMR. The prodomain is a separate folding unit containing three a-helices and an extended peptide that lies in the active site of the enzyme. Surprisingly, the amino-to-carboxyl direction of this peptide chain is opposite to that adopted by the inhibitor and by previously reported inhibitors of collagenase. Comparison of the active site of stromelysin with that of thermolysin reveals that most of the residues proposed to play significant roles in the enzymatic mechanism of thermolysin have equivalents in stromelysin, but that three residues implicated in the catalytic mechanism of thermolysin are not represented in stromelysin.
Stability constants for the Mg2+ and Cd2+ complexes of ATP, ADP, ATP alpha S, ATP beta S, and ADP alpha S have been determined at 30 degrees C and mu = 0.1 M by 31P NMR. Besides being of the utmost importance for determining species distributions for enzymatic studies, these constants allow an estimation of the preference of Cd2+ for sulfur vs. oxygen coordination in phosphorothioate complexes. Stability constants for Mg2+ complexes decreases when sulfur replaces oxygen (log K: ADP, 4.11; ADP alpha S, 3.66; ATP, 4.70; ATP alpha S, 4.47; ATP beta S, 4.04) because of (a) a statistical factor resulting from the loss of one potential phosphate oxygen ligand and (b) either an alteration in the charge distribution between oxygen and sulfur or destabilization of the chelate ring structure by loss of an internal hydrogen bond between an oxygen of coordinated phosphate and metal-bound water. Cd2+ complexes with sulfur-substituted nucleotides are more stable than those without sulfur (log K: ADP, 3.58; ADP alpha S, 4.95; ATP, 4.36; ATP alpha S, 4.42; ATP beta S, 5.44) because of the preferential binding of Cd2+ to sulfur rather than oxygen, which we estimate to be approximately 60 in CdADP alpha S and CdATP beta S. The proportion of tridentate coordination is estimated to be 50-60% in MgATP and MgATP beta S, approximately 27% in MgATP alpha S, approximately 16% in CdATP or CdATP beta S, but approximately 75% in CdATP alpha S. By analysis of the data of Jaffe and Cohn [Jaffe, E. K., & Cohn, M. (1979) J. Biol. Chem. 254, 10839], we conclude that the preference for oxygen over sulfur coordination to ATP beta S is 31 000 for Mg2+, 3100-3900 for Ca2+, and 158-193 for Mn2+. Proton NMR demonstrates that bidentate Cd2+ complexes form intramolecular chelates with the N-7 of adenine while Mg2+ nucleotides and the tridenate CdATP alpha S do not. An analysis of the 31P NMR line widths shows that the rate constants for dissociation of MgADP and MgATP are both 7000 s-1 while the association rate constants are 7 X 10(7) and 4 X 10(8) M-1 s-1, respectively. The observed dependence of the line width on nucleotide concentration is best explained by a base-stacking model at nucleotide concentrations above 5 mM.
Phenylalanine ammonia-lyase has been shown to catalyze the elimination of ammonia from the slow alternate substrate 3-(1,4-cyclohexadienyl)alanine by an E1 cb mechanism with a carbanion intermediate. This conclusion resulted from comparison of 15N isotope effects with deuterated (0.9921) and unlabeled substrates (1.0047), and a deuterium isotope effect of 2.0 from dideuteration at C-3, with the equations for concerted, carbanion, and carbonium ion mechanisms. The 15N equilibrium isotope effect on the addition of the substrate to the dehydroalanine prosthetic group on the enzyme is 0.979, while the kinetic 15N isotope effect on the reverse of this step is 1.03-1.04 and the intrinsic deuterium isotope effect on proton removal is in the range 4-6. Isotope effects with phenylalanine itself are small (15N ones of 1.0021 and 1.0010 when unlabeled or 3-dideuterated and a deuterium isotope effect of 1.15) but are consistent with the same mechanism with drastically increased commitments, including a sizable external one (i.e., phenylalanine is sticky). pH profiles show that the amino group of the substrate must be unprotonated to react but that a group on the enzyme with a pK of 9 must be protonated, possibly to catalyze addition of the substrate to dehydroalanine. Incorrectly protonated enzyme-substrate complexes do not form. Equilibrium 15N isotope effects are 1.016 for the deprotonation of phenylalanine or its cyclohexadienyl analogue, 1.0192 for deprotonation of NH4+, 1.0163 for the conversion of the monoanion of phenylalanine to NH3, and 1.0138 for the conversion of the monoanion of aspartate to NH4+.(ABSTRACT TRUNCATED AT 250 WORDS)
Clinical studies indicate that partial agonists of the G-protein-coupled, free fatty acid receptor 1 GPR40 enhance glucose-dependent insulin secretion and represent a potential mechanism for the treatment of type 2 diabetes mellitus. Full allosteric agonists (AgoPAMs) of GPR40 bind to a site distinct from partial agonists and can provide additional efficacy. We report the 3.2-Å crystal structure of human GPR40 (hGPR40) in complex with both the partial agonist MK-8666 and an AgoPAM, which exposes a novel lipid-facing AgoPAM-binding pocket outside the transmembrane helical bundle. Comparison with an additional 2.2-Å structure of the hGPR40-MK-8666 binary complex reveals an induced-fit conformational coupling between the partial agonist and AgoPAM binding sites, involving rearrangements of the transmembrane helices 4 and 5 (TM4 and TM5) and transition of the intracellular loop 2 (ICL2) into a short helix. These conformational changes likely prime GPR40 to a more active-like state and explain the binding cooperativity between these ligands.
The primary virulence factor of Bacillus anthracis is a secreted zinc-dependent metalloprotease toxin known as lethal factor (LF) that is lethal to the host through disruption of signaling pathways, cell destruction, and circulatory shock. Inhibition of this proteolytic-based LF toxemia could be expected to provide therapeutic value in combination with an antibiotic during and immediately after an active anthrax infection. Herein is shown the crystal structure of an intimate complex between a hydroxamate, (2R)-2-[(4-fluoro-3-methylphenyl)sulfonylamino]-N-hydroxy-2-(tetrahydro-2H-pyran-4-yl)acetamide, and LF at the LF-active site. Most importantly, this molecular interaction between the hydroxamate and the LF active site resulted in (i) inhibited LF protease activity in an enzyme assay and protected macrophages against recombinant LF and protective antigen in a cell-based assay, (ii) 100% protection in a lethal mouse toxemia model against recombinant LF and protective antigen, (iii) Ϸ50% survival advantage to mice given a lethal challenge of B. anthracis Sterne vegetative cells and to rabbits given a lethal challenge of B. anthracis Ames spores and doubled the mean time to death in those that died in both species, and (iv) 100% protection against B. anthracis spore challenge when used in combination therapy with ciprofloxacin in a rabbit ''point of no return'' model for which ciprofloxacin alone provided 50% protection. These results indicate that a small molecule, hydroxamate LF inhibitor, as revealed herein, can ameliorate the toxemia characteristic of an active B. anthracis infection and could be a vital adjunct to our ability to combat anthrax. Bacillus anthracis ͉ hydroxamate
The three-dimensional structure of the catalytic domain of stromelysin-1 complexed with an N-carboxyl alkyl inhibitor has been determined by NMR methods. The global fold consists of three helices, a five stranded beta-sheet and a methionine located in a turn near the catalytic histidines, classifying stromelysin-1 as a metzincin. Stromelysin-1 is unique in having two independent zinc binding sites: a catalytic site and a structural site. The inhibitor binds in an extended conformation. The S1' subsite is a deep hydrophobic pocket, whereas S2' appears shallow and S3' open.
Since hydride transfer is completely rate limiting for yeast formate dehydrogenase [Blanchard, J.S., & Cleland, W. W. (1980) Biochemistry 19, 3543], the intrinsic isotope effects on this reaction are fully expressed. Primary deuterium, 13C, and 18O isotope effects in formate and the alpha-secondary deuterium isotope effect at C-4 of the nucleotide have been measured for nucleotide substrates with redox potentials varying from -0.320 (NAD) to -0.258 V (acetylpyridine-NAD). As the redox potential gets more positive, the primary deuterium isotope effect increases from 2.2 to 3.1, the primary 13C isotope effect decreases from 1.042 to 1.036, the alpha-secondary deuterium isotope effect drops from 1.23 to 1.06, and Vmax decreases. The 18O isotope effects increase from 1.005 to 1.008 per single 18O substitution in formate (these values are dominated by the normal isotope effect on the dehydration of formate during binding; pyridinealdehyde-NAD gives an inverse value, possibly because it is not fully dehydrated during binding). These isotope effects suggest a progression toward earlier transition states as the redox potential of the nucleotide becomes more positive, with NAD having a late and acetyl-pyridine-NAD a nearly symmetrical transition state. By contrast, the I2 oxidation of formate in dimethyl sulfoxide has a very early transition state (13k = 1.0154; Dk = 2.2; 18k = 0.9938), which becomes later as the proportion of water in the solvent increases (13k = 1.0265 in 40% dimethyl sulfoxide and 1.0362 in water). alpha-secondary deuterium isotope effects with formate dehydrogenase are decreased halfway to the equilibrium isotope effect when deuterated formate is the substrate, showing that the bending motion of the secondary hydrogen is coupled to hydride transfer in the transition state and that tunneling of the two hydrogens is involved. The 15N isotope effect of 1.07 for NAD labeled at N-1 of the nicotinamide ring suggests that N-1 becomes pyramidal during the reaction. 18O fractionation factors for formate ion relative to aqueous solution are 1.0016 in sodium formate crystal, 1.0042 bound to Dowex-1, and 1.0040 as an ion pair (probably hydrated) in CHCl3. The CO2 analogue azide binds about 10(4) times better than the formate analogue nitrate to enzyme-nucleotide complexes (even though the Ki values for both and the affinity for formate vary by 2 orders of magnitude among the various nucleotides), but the ratio is not sensitive to the redox potential of the nucleotide. Thus, not the nature of the transition state but rather the shape of the initial binding pocket for formate is determining the relative affinity.(ABSTRACT TRUNCATED AT 400 WORDS)
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.