Mechanism of association of a specific aldehyde "transition-state analog" to the active site of .alpha.-chymotrypsin

Biochemistry ◽  
1979 ◽  
Vol 18 (2) ◽  
pp. 349-356 ◽  
Author(s):  
William P. Kennedy ◽  
Richard M. Schultz
Keyword(s):  
Transition State ◽  
Active Site ◽  
Transition State Analog

scholarly journals A crystallographic study of the Toho-1 β-lactamase acylation mechanism

2014 ◽  
Vol 70 (a1) ◽  
pp. C1207-C1207
Author(s):  
Leighton Coates
Keyword(s):  
Hydrogen Bonding ◽  
Transition State ◽  
Active Site ◽  
Catalytic Mechanism ◽  
Substrate Binding ◽  
Ligand Complex ◽  
Transition State Analog ◽  
Hydrogen Bonding Interactions ◽  
Active Site Region ◽  
Neutron Crystallography

β-lactam antibiotics have been used effectively over several decades against many types of highly virulent bacteria. The predominant cause of resistance to these antibiotics in Gram-negative bacterial pathogens is the production of serine β-lactamase enzymes. A key aspect of the class A serine β-lactamase mechanism that remains unresolved and controversial is the identity of the residue acting as the catalytic base during the acylation reaction. Multiple mechanisms have been proposed for the formation of the acyl-enzyme intermediate that are predicated on understanding the protonation states and hydrogen-bonding interactions among the important residues involved in substrate binding and catalysis of these enzymes. For resolving a controversy of this nature surrounding the catalytic mechanism, neutron crystallography is a powerful complement to X-ray crystallography that can explicitly determine the location of deuterium atoms in proteins, thereby directly revealing the hydrogen-bonding interactions of important amino acid residues. Neutron crystallography was used to unambiguously reveal the ground-state active site protonation states and the resulting hydrogen-bonding network in two ligand-free Toho-1 β-lactamase mutants which provided remarkably clear pictures of the active site region prior to substrate binding and subsequent acylation [1,2] and an acylation transition-state analog, benzothiophene-2-boronic acid (BZB), which was also isotopically enriched with 11B. The neutron structure revealed the locations of all deuterium atoms in the active site region and clearly indicated that Glu166 is protonated in the BZB transition-state analog complex. As a result, the complete hydrogen-bonding pathway throughout the active site region could then deduced for this protein-ligand complex that mimics the acylation tetrahedral intermediate [3].

An allolactose trapped at the lacZ β-galactosidase active site with its galactosyl moiety in a 4H3 conformation provides insights into the formation, conformation, and stabilization of the transition state

2015 ◽  
Vol 93 (6) ◽  
pp. 531-540 ◽  
Author(s):  
Robert W. Wheatley ◽  
Reuben E. Huber
Keyword(s):  
Transition State ◽  
Active Site ◽  
Axial Position ◽  
Transition State Analog ◽  
X Ray ◽  
Transition State Analogs ◽  
Leaving Group ◽  
Sugar Ring ◽  
Oxocarbenium Ion ◽  
Ring Distortion

When lactose was incubated with G794A-β-galactosidase (a variant with a “closed” active site loop that binds transition state analogs well) an allolactose was trapped with its Gal moiety in a 4H3 conformation, similar to the oxocarbenium ion-like conformation expected of the transition state. The numerous interactions formed between the 4H3 structure and β-galactosidase indicate that this structure is representative of the transition state. This conformation is also very similar to that of d-galactono-1,5-lactone, a good transition state analog. Evidence indicates that substrates take up the 4H3 conformation during migration from the shallow to the deep mode. Steric forces utilizing His418 and other residues are important for positioning the O1 leaving group into a quasi-axial position. An electrostatic interaction between the O5 of the distorted Gal and Tyr503 as well as C–H–π bonds with Trp568 are also significant. Computational studies of the energy of sugar ring distortion show that the β-galactosidase reaction itinerary is driven by energetic considerations in utilization of a 4H3 transition state with a novel 4C1-4H3-4C1 conformation itinerary. To our knowledge, this is the first X-ray crystallographic structural demonstration that the transition state of a natural substrate of a glycosidase has a 4H3 conformation.

Importance of Arg-599 of β-galactosidase (Escherichia coli) as an anchor for the open conformations of Phe-601 and the active-site loop

2010 ◽  
Vol 88 (6) ◽  
pp. 969-979 ◽  
Author(s):  
Megan L. Dugdale ◽  
Michael L. Vance ◽  
Robert W. Wheatley ◽  
Michael R. Driedger ◽  
Anjan Nibber ◽  
...  
Keyword(s):  
Energy Level ◽  
Transition State ◽  
Active Site ◽  
Native Enzyme ◽  
Transition State Analog ◽  
Substrate Analogs ◽  
Substrate Complex ◽  
Lower Energy Level ◽  
Extra Energy ◽  
Guanidinium Group

Structural and kinetic data show that Arg-599 of β-galactosidase plays an important role in anchoring the “open” conformations of both Phe-601 and an active-site loop (residues 794–803). When alanine was substituted for Arg-599, the conformations of Phe-601 and the loop shifted towards the “closed” positions because interactions with the guanidinium side chain were lost. Also, Phe-601, the loop, and Na+, which is ligated by the backbone carbonyl of Phe-601, lost structural order, as indicated by large B-factors. IPTG, a substrate analog, restored the conformations of Phe-601 and the loop of R599A-β-galactosidase to the open state found with IPTG-complexed native enzyme and partially reinstated order. d-Galactonolactone, a transition state analog, restored the closed conformations of R599A-β-galactosidase to those found with d-galactonolactone–complexed native enzyme and completely re-established the order. Substrates and substrate analogs bound R599A-β-galactosidase with less affinity because the closed conformation does not allow substrate binding and extra energy is required for Phe-601 and the loop to open. In contrast, transition state analog binding, which occurs best when the loop is closed, was several-fold better. The higher energy level of the enzyme•substrate complex and the lower energy level of the first transition state means that less activation energy is needed to form the first transition state and thus the rate of the first catalytic step (k2) increased substantially. The rate of the second catalytic step (k3) decreased, likely because the covalent form is more stabilized than the second transition state when Phe-601 and the loop are closed. The importance of the guanidinium group of Arg-599 was confirmed by restoration of conformation, order, and activity by guanidinium ions.

scholarly journals Structural Basis for Stereoselective Dehydration and Hydrogen-Bonding Catalysis by the SAM-Dependent Pericyclase LepI

2018 ◽  
Author(s):  
Yujuan Cai ◽  
Yang Hai ◽  
Masao Ohashi ◽  
Cooper S. Jamieson ◽  
Marc Garcia-Borras ◽  
...  
Keyword(s):  
Transition State ◽  
Active Site ◽  
Claisen Rearrangement ◽  
Biochemical Characterization ◽  
Mutational Analysis ◽  
Diels Alder ◽  
Quinone Methide ◽  
Structural Basis ◽  
Active Site Residues ◽  
Transition State Analog

ABSTRACTLepI is an S-adenosylmethionine (SAM)-dependent pericyclase that catalyzes the formation of 2-pyridone natural product leporin C. Biochemical characterization showed LepI can catalyze the stereoselective dehydration to yield a reactive (E)-quinone methide which can undergo a bifurcating intramolecular Diels-Alder (IMDA) and hetero-Diels-Alder (HDA) cyclization from an ambimodal transition state, and a [3,3]-retro-Claisen rearrangement to recycle the IMDA product into leporin C. Here we solved the X-ray crystal structures of SAM-bound LepI, and in complex with a substrate analog, the product leporin C, and a retro-Claisen reaction transition-state analog to understand the structural basis for the multitude of reactions. Structural and mutational analysis revealed how Nature evolves a classic methyltransferase active site into one that can serve as a dehydratase and a multifunctional pericyclase. Catalysis of both sets of reactions employ His133 and Arg295, two active site residues that are not found in canonical methyltransferases. An alternative role of SAM, which is not found to be in direct contact of the substrate, is also proposed.

scholarly journals Structural Comparisons of Cefotaximase (CTX-M-ase) Sub Family 1

2021 ◽  
Vol 12 ◽  
Author(s):  
Ben A. Shurina ◽  
Richard C. Page
Keyword(s):  
Transition State ◽  
Active Site ◽  
Boronic Acid ◽  
Structural Changes ◽  
Surface Patch ◽  
Active Site Residues ◽  
Transition State Analog ◽  
Drug Candidates ◽  
Existing Structures ◽  
New Antibiotics

The cefotaximase or CTX-M, family of serine-β-lactamases represents a significant clinical concern due to the ability for these enzymes to confer resistance to a broad array of β-lactam antibiotics an inhibitors. This behavior lends CTX-M-ases to be classified as extended spectrum β-lactamases (ESBL). Across the family of CTX-M-ases most closely related to CTX-M-1, the structures of CTX-M-15 with a library of different ligands have been solved and serve as the basis of comparison within this review. Herein we focus on the structural changes apparent in structures of CTX-M-15 in complex with diazabicyclooctane (DABCO) and boronic acid transition state analog inhibitors. Interactions between a positive surface patch near the active site and complementary functional groups of the bound inhibitor play key roles in the dictating the conformations of active site residues. The insights provided by analyzing structures of CTX-M-15 in complex with DABCO and boronic acid transition state analog inhibitors and analyzing existing structures of CTX-M-64 offer opportunities to move closer to making predictions as to how CTX-M-ases may interact with potential drug candidates, setting the stage for the further development of new antibiotics and β-lactamase inhibitors.

scholarly journals Inhibition of pancreatic lipase in vitro by the covalent inhibitor tetrahydrolipstatin

1988 ◽  
Vol 256 (2) ◽  
pp. 357-361 ◽  
Author(s):  
P Hadváry ◽  
H Lengsfeld ◽  
H Wolfer
Keyword(s):  
Transition State ◽  
Acid Derivative ◽  
Pancreatic Lipase ◽  
Active Site ◽  
Boronic Acid ◽  
Selective Inhibitor ◽  
Covalent Intermediate ◽  
State Form ◽  
Covalent Inhibitor

Tetrahydrolipstatin inhibits pancreatic lipase from several species, including man, with comparable potency. The lipase is progressively inactivated through the formation of a long-lived covalent intermediate, probably with a 1:1 stoichiometry. The lipase substrate triolein and also a boronic acid derivative, which is presumed to be a transition-state-form inhibitor, retard the rate of inactivation. Therefore, in all probability, tetrahydrolipstatin reacts with pancreatic lipase at, or near, the substrate binding or active site. Tetrahydrolipstatin is a selective inhibitor of lipase; other hydrolases tested were at least a thousand times less potently inhibited.

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