Structural Modifications of the Active Site in Teicoplanin and Related Glycopeptides. 1. Reductive Hydrolysis of the 1,2- and 2,3-Peptide Bonds

Adriano Malabarba; Romeo Ciabatti; Jürgen Kettenring; Pietro Ferrari; Károly Vékey; Elvio Bellasio; Maurizio Denaro

doi:10.1021/jo941809v

TESTS FOR HYDROLYSIS OF PEPTIDE BONDS BY ULTRAVIOLET LIGHT

Journal of Biological Chemistry ◽

10.1016/s0021-9258(18)56198-6 ◽

1950 ◽

Vol 187 (2) ◽

pp. 543-545

Author(s):

Dorothy J. McLean ◽

Arthur C. Giese

Keyword(s):

Ultraviolet Light ◽

Peptide Bonds ◽

Hydrolysis Of

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“Newton’s cradle” proton relay with amide–imidic acid tautomerization in inverting cellulase visualized by neutron crystallography

Science Advances ◽

10.1126/sciadv.1500263 ◽

2015 ◽

Vol 1 (7) ◽

pp. e1500263 ◽

Cited By ~ 53

Author(s):

Akihiko Nakamura ◽

Takuya Ishida ◽

Katsuhiro Kusaka ◽

Taro Yamada ◽

Shinya Fushinobu ◽

...

Keyword(s):

Glycoside Hydrolases ◽

Side Chain ◽

Enzymatic Reactions ◽

X Ray Diffraction ◽

Peptide Bonds ◽

Proton Relay ◽

Newton’S Cradle ◽

Dynamics Simulations ◽

Hydrolysis Of

Hydrolysis of carbohydrates is a major bioreaction in nature, catalyzed by glycoside hydrolases (GHs). We used neutron diffraction and high-resolution x-ray diffraction analyses to investigate the hydrogen bond network in inverting cellulase PcCel45A, which is an endoglucanase belonging to subfamily C of GH family 45, isolated from the basidiomycete Phanerochaete chrysosporium. Examination of the enzyme and enzyme-ligand structures indicates a key role of multiple tautomerizations of asparagine residues and peptide bonds, which are finally connected to the other catalytic residue via typical side-chain hydrogen bonds, in forming the “Newton’s cradle”–like proton relay pathway of the catalytic cycle. Amide–imidic acid tautomerization of asparagine has not been taken into account in recent molecular dynamics simulations of not only cellulases but also general enzyme catalysis, and it may be necessary to reconsider our interpretation of many enzymatic reactions.

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Effect of Modifiers on the Hydrolysis of Basic and Neutral Peptides by Carboxypeptidase B

Canadian Journal of Biochemistry ◽

10.1139/o75-102 ◽

1975 ◽

Vol 53 (7) ◽

pp. 747-757 ◽

Cited By ~ 3

Author(s):

Graham J. Moore ◽

N. Leo Benoiton

Keyword(s):

Active Site ◽

Active Sites ◽

Kinetic Behavior ◽

Carboxypeptidase A ◽

Phenyllactic Acid ◽

Carboxypeptidase B ◽

Substrate Complex ◽

Enzyme Substrate ◽

Basic Peptides ◽

Hydrolysis Of

The initial rates of hydrolysis of Bz-Gly-Lys and Bz-Gly-Phe by carboxypeptidase B (CPB) are increased in the presence of the modifiers β-phenylpropionic acid, cyclohexanol, Bz-Gly, and Bz-Gly-Gly. The hydrolysis of the tripeptide Bz-Gly-Gly-Phe is also activated by Bz-Gly and Bz-Gly-Gly, but none of these modifiers activate the hydrolysis of Bz-Gly-Gly-Lys, Z-Leu-Ala-Phe, or Bz-Gly-phenyllactic acid by CPB. All modifiers except cyclohexanol display inhibitory modes of binding when present in high concentration.Examination of Lineweaver–Burk plots in the presence of fixed concentrations of Bz-Gly has shown that activation of the hydrolysis of neutral and basic peptides by CPB, as reflected in the values of the extrapolated parameters, Km(app) and keat, occurs by different mechanisms. For Bz-Gly-Gly-Phe, activation occurs because the enzyme–modifier complex has a higher affinity than the free enzyme for the substrate, whereas activation of the hydrolysis of Bz-Gly-Lys derives from an increase in the rate of breakdown of the enzyme–substrate complex to give products.Cyclohexanol differs from Bz-Gly and Bz-Gly-Gly in that it displays no inhibitory mode of binding with any of the substrates examined, activates only the hydrolysis of dipeptides by CPB, and has a greater effect on the hydrolysis of the basic dipeptide than on the neutral dipeptide. Moreover, when Bz-Gly-Lys is the substrate, cyclohexanol activates its hydrolysis by CPB by increasing both the enzyme–substrate binding affinity and the rate of the catalytic step, an effect different from that observed when Bz-Gly is the modifier.The anomalous kinetic behavior of CPB is remarkably similar to that of carboxypeptidase A, and is a good indication that both enzymes have very similar structures in and around their respective active sites. A binding site for activator molecules down the cleft of the active site is proposed for CPB to explain the observed kinetic behavior.

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The crystal structure of human mitochondrial 3-ketoacyl-CoA thiolase (T1): insight into the reaction mechanism of its thiolase and thioesterase activities

Acta Crystallographica Section D Biological Crystallography ◽

10.1107/s1399004714023827 ◽

2014 ◽

Vol 70 (12) ◽

pp. 3212-3225 ◽

Cited By ~ 16

Author(s):

Tiila-Riikka Kiema ◽

Rajesh K. Harijan ◽

Malgorzata Strozyk ◽

Toshiyuki Fukao ◽

Stefan E. H. Alexson ◽

...

Keyword(s):

Crystal Structure ◽

Reaction Mechanism ◽

Active Site ◽

Quaternary Structure ◽

Fatty Acyl ◽

Physiological Importance ◽

Loop Domain ◽

Solution Studies ◽

Hydrolysis Of ◽

Insight Into

Crystal structures of human mitochondrial 3-ketoacyl-CoA thiolase (hT1) in the apo form and in complex with CoA have been determined at 2.0 Å resolution. The structures confirm the tetrameric quaternary structure of this degradative thiolase. The active site is surprisingly similar to the active site of theZoogloea ramigerabiosynthetic tetrameric thiolase (PDB entries 1dm3 and 1m1o) and different from the active site of the peroxisomal dimeric degradative thiolase (PDB entries 1afw and 2iik). A cavity analysis suggests a mode of binding for the fatty-acyl tail in a tunnel lined by the Nβ2–Nα2 loop of the adjacent subunit and the Lα1 helix of the loop domain. Soaking of the apo hT1 crystals with octanoyl-CoA resulted in a crystal structure in complex with CoA owing to the intrinsic acyl-CoA thioesterase activity of hT1. Solution studies confirm that hT1 has low acyl-CoA thioesterase activity for fatty acyl-CoA substrates. The fastest rate is observed for the hydrolysis of butyryl-CoA. It is also shown that T1 has significant biosynthetic thiolase activity, which is predicted to be of physiological importance.

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Isolation, purification and structure of exochelin MS, the extracellular siderophore from Mycobacterium smegmatis

Biochemical Journal ◽

10.1042/bj3050187 ◽

1995 ◽

Vol 305 (1) ◽

pp. 187-196 ◽

Cited By ~ 62

Author(s):

G J Sharman ◽

D H Williams ◽

D F Ewing ◽

C Ratledge

Keyword(s):

Amino Acids ◽

Mycobacterium Smegmatis ◽

Methyl Esters ◽

Three Dimensional ◽

Iron Chelation ◽

Peptide Bond ◽

Exchange Chromatography ◽

Peptide Bonds ◽

Hydrolysis Of ◽

Gallium Complex

The extracellular siderophore from Mycobacterium smegmatis, exochelin MS, was isolated from iron-deficiently grown cultures and purified to > 98% by a combination of ion-exchange chromatography and h.p.l.c. The material is unextractable into organic solvents, is basic (pI = 9.3-9.5), has a lambda max at 420 nm and a probable Ks for Fe3+ of between 10(25) and 10(30). Its structure has been determined by examination of desferri- and ferri-exochelin and its gallium complex. The methods used were electrospray-m.s. and one- and two-dimensional (NOESY, DQF-COSY and TOCSY) 1H n.m.r. The constituent amino acids were examined by chiral g.l.c analysis of N-trifluoroacetyl isopropyl and N-pentafluoropropionyl methyl esters after hydrolysis, and reductive HI hydrolysis, of the siderophore. The exochelin is a formylated pentapeptide: N-(delta-N-formyl,delta N-hydroxy-R-ornithyl) -beta-alaninyl-delta N-hydroxy-R-ornithinyl-R-allo-threoninyl-delta N-hydroxy-S-ornithine. The linkages involving the three ornithine residues are via their delta N(OH) and alpha-CO groups leaving three free alpha-NH2 groups. Although there are two peptide bonds, these involve the three R (D)-amino acids. Thus the molecule has no conventional peptide bond, and this suggests that it will be resistant to peptidase hydrolysis. The co-ordination centre with Fe3+ is hexadenate in an octahedral structure involving the three hydroxamic acid groups. Molecular modelling shows it to have similar features to other ferric trihydroxamate siderophores whose three-dimensional structures have been established. The molecule is shown to have little flexibility around the iron chelation centre, although the terminal (Orn-3) residue, which is not involved in iron binding except at its delta N atom, has more motional freedom.

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Molecular mechanism of uncompetitive inhibition of human placental and germ-cell alkaline phosphatase

Biochemical Journal ◽

10.1042/bj2860023 ◽

1992 ◽

Vol 286 (1) ◽

pp. 23-30 ◽

Cited By ~ 55

Author(s):

M F Hoylaerts ◽

T Manes ◽

J L Millán

Keyword(s):

Germ Cell ◽

Active Site ◽

Molecular Model ◽

Inhibition Mechanism ◽

Side Group ◽

Alkaline Phosphatases ◽

Uncompetitive Inhibition ◽

Guanidinium Group ◽

Hydrolysis Of ◽

Site Binding

Placental (PLAP) and germ-cell (GCAP) alkaline phosphatases are inhibited uncompetitively by L-Leu and L-Phe. Whereas L-Phe inhibits PLAP and GCAP to the same extent, L-Leu inhibits GCAP 17-fold more strongly than it does PLAP. This difference has been attributed [Hummer & Millán (1991) Biochem. J 274, 91-95] to a Glu----Gly substitution at position 429 in GCAP. The D-Phe and D-Leu enantiomorphs are also inhibitory through an uncompetitive mechanism but with greatly decreased efficiencies. Replacement of the active-site residue Arg-166 by Ala-166 changes the inhibition mechanism of the resulting PLAP mutant to a more complex mixed-type inhibition, with decreased affinities for L-Leu and L-Phe. The uncompetitive mechanism is restored on the simultaneous introduction of Gly-429 in the Ala-166 mutant, but the inhibitions of [Ala166,Gly429]PLAP and even [Lys166,Gly429]PLAP by L-Leu and L-Phe are considerably decreased compared with that of [Gly429]PLAP. These findings point to the importance of Arg-166 during inhibition. Active-site binding of L-Leu requires the presence of covalently bound phosphate in the active-site pocket, and the inhibition of PLAP by L-Leu is pH-sensitive, gradually disappearing when the pH is decreased from 10.5 to 7.5. Our data are compatible with the following molecular model for the uncompetitive inhibition of PLAP and GCAP by L-Phe and L-Leu: after binding of a phosphorylated substrate to the active site, the guanidinium group of Arg-166 (normally involved in positioning phosphate) is redirected to the carboxy group of L-Leu (or L-Phe), thus stabilizing the inhibitor in the active site. Therefore leucinamide and leucinol are weaker inhibitors of [Gly429]PLAP than is L-Leu. During this Arg-166-regulated event, the amino acid side group is positioned in the loop containing Glu-429 or Gly-429, leading to further stabilization. Replacement of Glu-429 by Gly-429 eliminates steric constraints experienced by the bulky L-Leu side group during its positioning and also increases the active-site accessibility for the inhibitor, providing the basis for the 17-fold difference in inhibition efficiency between PLAP and GCAP. Finally, the inhibitor's unprotonated amino group co-ordinates with the active-site Zn2+ ion 1, interfering with the hydrolysis of the phosphoenzyme intermediate, a phenomenon that determines the uncompetitive nature of the inhibition.

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Mechanism of IPPase shown by high resolution Neutron and X-ray crystallography

Acta Crystallographica Section A Foundations and Advances ◽

10.1107/s2053273314087889 ◽

2014 ◽

Vol 70 (a1) ◽

pp. C1211-C1211

Author(s):

Joseph Ng ◽

Ronny Hughes ◽

Michelle Morris ◽

Leighton Coates ◽

Matthew Blakeley ◽

...

Keyword(s):

High Resolution ◽

Active Site ◽

Inorganic Pyrophosphatase ◽

Inorganic Pyrophosphate ◽

X Ray ◽

X Ray Crystallography ◽

Cellular Processes ◽

Crystallographic Structures ◽

Hydrolysis Of ◽

Low Energy Conformations

Soluble inorganic pyrophosphatase (IPPase) catalyzes the hydrolysis of inorganic pyrophosphate (PPi) to form orthophosphate (Pi). The action of this enzyme shifts the overall equilibrium in favor of synthesis during a number of ATP-dependent cellular processes such as in the polymerization of nucleic acids, production of coenzymes and proteins and sulfate assimilation pathways. Two Neutron crystallographic (2.10-2.50Å) and five high-resolution X-ray (0.99Å-1.92Å) structures of the archaeal IPPase from Thermococcus thioreducens have been determined under both cryo and room temperatures. The structures determined include the recombinant IPPase bound to Mg+2, Ca+2, Br-, SO2-2 or PO4-2 involving those with non-hydrolyzed and hydrolyzed pyrophosphate complexes. All the crystallographic structures provide snapshots of the active site corresponding to different stages of the hydrolysis of inorganic pyrophosphate. As a result, a structure-based model of IPPase catalysis is devised showing the enzyme's low-energy conformations, hydration states, movements and nucleophile generation within the active site.

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Mechanistic and active-site studies on d(–)-mandelate dehydrogenase from Rhodotorula graminis

Biochemical Journal ◽

10.1042/bj2810211 ◽

1992 ◽

Vol 281 (1) ◽

pp. 211-218 ◽

Cited By ~ 6

Author(s):

D P Baker ◽

C Kleanthous ◽

J N Keen ◽

E Weinhold ◽

C A Fewson

Keyword(s):

Active Site ◽

Complete Sequence ◽

Histidine Residue ◽

Extended Version ◽

Order Process ◽

First Order ◽

Tryptic Digest ◽

Complete Inactivation ◽

Hydrolysis Of ◽

High Voltage Electrophoresis

D(–)-Mandelate dehydrogenase, the first enzyme of the mandelate pathway in the yeast Rhodotorula graminis, catalyses the NAD(+)-dependent oxidation of D(–)-mandelate to phenylglyoxylate. D(–)-2-(Bromoethanoyloxy)-2-phenylethanoic acid [‘D(–)-bromoacetylmandelic acid’], an analogue of the natural substrate, was synthesized as a probe for reactive and accessible nucleophilic groups within the active site of the enzyme. D(–)-Mandelate dehydrogenase was inactivated by D(–)-bromoacetylmandelate in a psuedo-first-order process. D(–)-Mandelate protected against inactivation, suggesting that the residue that reacts with the inhibitor is located at or near the active site. Complete inactivation of the enzyme resulted in the incorporation of approx. 1 mol of label/mol of enzyme subunit. D(–)-Mandelate dehydrogenase that had been inactivated with 14C-labelled D(–)-bromoacetylmandelate was digested with trypsin; there was substantial incorporation of 14C into two tryptic-digest peptides, and this was lowered in the presence of substrate. One of the tryptic peptides had the sequence Val-Xaa-Leu-Glu-Ile-Gly-Lys, with the residue at the second position being the site of radiolabel incorporation. The complete sequence of the second peptide was not determined, but it was probably an N-terminally extended version of the first peptide. High-voltage electrophoresis of the products of hydrolysis of modified protein showed that the major peak of radioactivity co-migrated with N tau-carboxymethylhistidine, indicating that a histidine residue at the active site of the enzyme is the most likely nucleophile with which D(–)-bromoacetylmandelate reacts. D(–)-Mandelate dehydrogenase was incubated with phenylglyoxylate and either (4S)-[4-3H]NADH or (4R)-[4-3H]NADH and then the resulting D(–)-mandelate and NAD+ were isolated. The enzyme transferred the pro-R-hydrogen atom from NADH during the reduction of phenylglyoxylate. The results are discussed with particular reference to the possibility that this enzyme evolved by the recruitment of a 2-hydroxy acid dehydrogenase from another metabolic pathway.

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Kinetic probes for inter-domain co-operation in human somatic angiotensin-converting enzyme

Biochemical Journal ◽

10.1042/bj20050702 ◽

2005 ◽

Vol 391 (3) ◽

pp. 641-647 ◽

Cited By ~ 16

Author(s):

Olga E. Skirgello ◽

Peter V. Binevski ◽

Vladimir F. Pozdnev ◽

Olga A. Kost

Keyword(s):

Angiotensin Converting Enzyme ◽

Enzymatic Activity ◽

Active Site ◽

The Other ◽

Converting Enzyme ◽

Human Enzyme ◽

Independent Functions ◽

The Common ◽

The Individual ◽

Hydrolysis Of

s-ACE (the somatic form of angiotensin-converting enzyme) consists of two homologous domains (N- and C-domains), each bearing a catalytic site. Negative co-operativity between the two domains has been demonstrated for cow and pig ACEs. However, for the human enzyme there are conflicting reports in the literature: some suggest possible negative co-operativity between the domains, whereas others indicate independent functions of the domains within s-ACE. We demonstrate here that a 1:1 stoichiometry for the binding of the common ACE inhibitors, captopril and lisinopril, to human s-ACE is enough to abolish enzymatic activity towards FA {N-[3-(2-furyl)acryloyl]}-Phe-GlyGly, Cbz (benzyloxycarbonyl)-Phe-His-Leu or Hip (N-benzoylglycyl)-His-Leu. The kinetic parameters for the hydrolysis of seven tripeptide substrates by human s-ACE appeared to represent average values for parameters obtained for the individual N- and C-domains. Kinetic analysis of the simultaneous hydrolysis of two substrates, Hip-His-Leu (S1) and Cbz-Phe-His-Leu (S2), with a common product (His-Leu) by s-ACE at different values for the ratio of the initial concentrations of these substrates (i.e. σ=[S2]0/[S1]0) demonstrated competition of these substrates for binding to the s-ACE molecule, i.e. binding of a substrate at one active site makes the other site unavailable for either the same or a different substrate. Thus the two domains within human s-ACE exhibit strong negative co-operativity upon binding of common inhibitors and in the hydrolysis reactions of tripeptide substrates.

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Human cholinesterases

ORGANOPHOSPHORUS NEUROTOXINS ◽

10.29039/chapter_5e4132b5f22366.15634219 ◽

2020 ◽

pp. 63-120

Author(s):

Sergey Varfolomeev ◽

Bella Grigorenko ◽

Sofya Lushchekina ◽

Alexander Nemuchin

Keyword(s):

Active Site ◽

The Body ◽

Polymorphic Modification ◽

Substrate Complex ◽

Enzyme Substrate ◽

Mechanism Of Hydrolysis ◽

The Central Nervous System ◽

The Stability ◽

Hydrolysis Of ◽

Enzyme Reactivity

The work is devoted to modeling the elementary stages of the hydrolysis reaction in the active site of enzymes belonging to the class of cholinesterases — acetylcholinesterase (AChE) and butyrylcholinesterase (BChE). The study allowed to describe at the molecular level the effect of the polymorphic modification of BChE, causing serious physiolog ical consequences. Cholinesterase plays a crucial role in the human body. AChE is one of the key enzymes of the central nervous system, and BChE performs protective functions in the body. According to the results of calculations using the combined method of quantum and molecular mechanics (KM/MM), the mechanism of the hydrolysis of the native acetylcholine substrate in the AChE active center was detailed. For a series of ester substrates, a method for estimation of dependence of the enzyme reactivity on the structure of the substrate has been developed. The mechanism of hydrolysis of the muscle relaxant of succininylcholine BChE and the effect of the Asp70Gly polymorph on it were studied. Using various computer simulation methods, the stability of the enzyme-substrate complex of two enzyme variants with succinylcholine was studied.

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