Enzymology. How enzymes work - mechanisms. Bruno Sopko

A thermodynamic model of catalysis

A thermodynamic model of catalysis The rate of a chemical reaction is related to the activation energy of the reaction by the following equation: Therefore, the rate acceleration provided by the catalysis can simply be calculated:: If, for example, a catalyst can provide 10 kJ/mol1 of transition stabilisation energy for a reaction at 25º C a 55-fold rate acceleration will result, whereas a 20 kJ/mol stabilisation will give a 3000-fold acceleration and a 40 kJ/mol stabilisation a 107-fold acceleration!

A thermodynamic model of catalysis

The steps in enzyme-catalyzed reaction

The important effects of enzyme catalysis proximity effect transition state stabilisation acid/base catalysis electrostatic effects nucleophilic or electrophilic catalysis by functional groups of enzyme structural flexibility

Proximity effect

Transition state stabilisation

Acid/base catalysis this catalysis avoids the need of extremely low or high pH principle is to make a potentially reactive group more reactive by increasing their nucleophilic or electrophilic character by adding or removing a proton

Acid/base catalysis

Mechanism for ketosteroid isomerase. Example of acid/base catalysis

Acid/base catalysis

Metal Ion catalysis 1. Metalloenzymes Tighly bound metal ions (Fe2+, Fe3+, Cu2+, Zn2+,Mn2+, Co3+) Metal-activated enzymes (Na+, K+, Mg+, Ca2+) Role of metal ions in catalysis 1) Binding of substrate and their properly orientation to reaction 2) Mediating of oxidation-reduction reactions through reversible changes in the metal ion oxidation state 3) Charge stabilization, shielding negative charges

Metal Ion catalysis Lactatedehydrogenase Mediating of oxidation-reduction reactions Lactatedehydrogenase 1) Fast bond of NAD+ in enyzmatic domain, isomerization and deprotonisation (H bonds Ser 48 and His 51) 2) Alcoholic substrate changes OH- coupled with Zn2+ reorganisation of bonds and E-NADH- aldehyd complex formations

Metal Ion catalysis Mediating of oxidation-reduction reactions 3. Release of product and reduced NADH coenzyme, rearrangement

Metal Ion catalysis Metal Ion Enzyme Iron Cytochromes Aconitase Catalase Zinc Carbonate dehydrogenase Superoxide dismutase Manganese Pyruvate Carboxylase Molybdenum Xanthine oxidase Copper Cytochrome oxidase

Electrostatic effects stabilization of electric charge distribution in transition states during enzymatic reactions the changing atom charges of substrate in a transition state interacts with atom charges of the surrounding enzyme and also neighbour water molecules

Nucleophilic or electrophilic catalysis enzymatic functional groups provide nucleophilic and electrophilic catalysts typical nucleophilic groups are amino, hydroxyl and thiol groups of AA residues but imidazol group of His or carboxyl group of Asp, Glu can serve as well electrophilic group of enzymes is usually complex of metal cofactor with substrate nucleophilic catalysis involves the formation of an intermediate state in which substrate is covalently bound to a nucleophilic group

Nucleophilic catalysis

Electrophilic catalysis

Nucleophilic catalysis - acetoacetic decarboxylase

Serine proteases - examples of nucleophilic catalysis serine proteases belong to large family of proteolytic enzymes using this mechanism the best known serine endoproteases are trypsin, chymotrypsin and elastase of pancreatic juice

Characteristics of the substrate-binding sites in chymotrypsin, trypsin and elastase

The mechanism of chymotrypsin action

Hexokinase - example of structural flexibility increasing the specifity of enzymes Hexokinase catalyzes the transfer of phosphate group from ATP to glucose: ATP + Glc → ADP + Glc-6-phosphate

Enzyme flexibility – the use of strain energy

Isoenzymes Isoenzymes are enzymes that catalyse the same reaction, but differ in their primary structure and/or subunit composition Amounts of some tissue-specific enzymes are determined in serum for diagnostic purposes Typical examples of diagnostically important serum isoenzymes are CK (myocardial infarction), GGT (hepatitis) or LDH (myocardial infarction, hepatitis)

LDH isoenzymes LDH catalyzes the interconversion of pyruvate and lactate with accompanying conversion of NADH and NAD+ tetrameric enzyme made of two different subunits (H and M)

Classifying enzymes (1972 International Union of Biochemistry) Oxidoreductases Transferases Hydrolases Lyases Isomerases Ligases (synthetases)

Oxidoreductases (EC 1.) catalyze transfer of electrons from one molecule (reductant, electron donor) to another (oxidant, electron acceptor) dehydrogenases catalyze oxidation reaction which involves removing hydrogen from the reductant typical coenzymes are nicotine nucleotides (NADH, NADPH), flavin nucleotides (FMN, FAD), hemins, coenzyme Q (ubichinone) and lipoic acid typical representants are alcohol dehydrogenase, glucosooxidase etc.

Transferases (EC 2.) catalyze the transfer of a functional group (e.g. methyl, acyl, phospho, glycosyl etc.) from one molecule (donor) to another (acceptor) donor molecule is often a coenzyme typical coenzymes of transferases are ATP, pyridixalphosphate (amino group), tetrafolic acid (formyl group), adenysylmethionine (methyl), coenzyme A (acetyl)

Hydrolases (EC 3.) catalyzes the hydrolysis of a chemical bond: A–B + H2O → A–OH + B–H cleave, for instance, ester bonds (esterases, nucleases, phosphodiesterases, lipases, phosphatases), glycosidic bonds (glycosidases), peptide bonds (proteases and peptidases)

Lyases (EC 4.) cleave C-C, C-O, C-N and other bonds by other means than by hydrolysis or oxidation require only one substrate for the reaction in one direction, but two substrates for the reverse reaction (e.g. adenyl cyclase catalyzes ATP → cAMP + PPi ) decarboxylases (EC 4.1.1) are lyases cleaving C-C bond and liberates carbon dioxide from carboxyl group

Isomerases (EC 5.) catalyze reactions involving a structural rearrangement of a molecule e.g. alanine racemase catalyzes the conversion of L-alanine into its isomeric (mirror-image) form, D-alanine isomerase called mutarotase catalyzes the conversion of a-D-glucose into b-D-glucose. UDP-Glc-epimerase : UDP-Glc ⇌ UDP-Gal

Ligases (synthetases) (EC 6.) catalyze synthesis of a new bond between two molecules reaction is usually accompanied by hydrolysis of ATP or another similar triphosphate biotin is a cofactor for enzymes catalyzing carboxylation binding carbon dioxide to molecule) called carboxylases (e.g. pyruvate carboxylase)

Literature Baynes, J.W.,Dominiczak, M.H.: Medical Biochemistry, Elsevier 2004 Bugg, T.:Introduction to Enzyme and Coenzyme Chemistry, Blackwell Publishing, 2004