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Chapter 8 Enzymes: basic concepts and kinetics Light production by enzyme catalysis: energy conversion Outline: • enzymes are powerful and specific catalysts • free energy is a useful thermodynamic function for understanding enzyme catalyzed reactions • enzymes accelerates reactions by facilitating the formation of the transition state • the Michaelis-Menten model accounts for the kinetic properties of many enzymes • enzymes can be inhibited by specific molecules Enzymes are specific catalysts (8.1) The peptide bond is thermodynamically unfavorable but kinetically very stable (half-life 1000 years). Why? Reaction catalyzed by a proteolytic enzyme Specificity of enzyme catalysis Trypsin and thrombin are both proteases. Trypsin • Trypsin functions in the degradation of ingested proteins • Thrombin acts only on one protein: fibrinogen. Thrombin converts fibrinogen into fibrin and fibrin polymeri-zes and forms a blood clot. Thrombin Enzymes are powerful catalysts (8.1) Why is a reaction that occurs spontaneously catalyzed by an enzyme? HCO3- + H+ Reaction catalyzed by carbonic anhydrase Stimulates O2 release from Hb Fysiologische rol koolzuur anhydrase pH < 7 pH ~ 7.4 [Figuur 7.22] Rate enhancement by enzymes Carbonic anhydrase is one of the fastest enzymes known. One enzyme molecule can hydrate 106 molecules of CO2 per second. Many enzymes require cofactors for activity Apoenzyme + cofactor = holoenzyme Cofactors that are (small) organic molecules are called coenzymes. cofactor If coenzymes are tightly bound, they are called prosthetic groups. metalen If coenzymes are only bound during catalysis, they are called cosubstrates. prosthetische Metals like Zn, Ni are tightly bound. groep coenzym cosubstraat Animatie De covalent gebonden cofactor, pyridoxal Zink, een covalent gebonden cofactor aan het fosfaat, die een prosthetische enzym (coenzym) koolzuur anhydrase groep is van het enzym glycogeen fosforylase Enzymes can transform energy from one form into another Figuur 13-2 • Pomp heeft twee conformaties. • Een met de ion bindingsplaatsen open voor een kant van het membraan. • De andere conformatie is open voor de andere kant. • Een gekoppelde vrije energie leverende reactie verschuift het evenwicht tussen de twee conformaties. Enzymes can transform energy from one form into another Structuren van de calcium pomp Calciumbindingsplaatsen bereikbaar vanuit het cytoplasma [Fig 13-3] Calciumbindingsplaatsen niet meer aanwezig en open naar de ander kant van het membraan [Fig 13-4] Enzymes can transform energy from one form into another The Ca2+ ATPase uses the energy of ATP hydrolysis to transport Ca2+ across the membrane, generating a Ca2+ gradient. Figuur 13-5 Free energy is a useful thermodynamic function for understanding enzyme catalyzed reactions (8.2) The free energy difference of the products minus that of the substrates of a reaction determine the direction of the reaction (ΔG). The reaction: A + B C+D [C ].[ D] ΔG = ΔG + RT ln [ A].[ B] 0 Free energy is a useful thermodynamic function for understanding enzyme catalyzed reactions (8.2) Een reactie kent twee thermodynamische eigenschappen • Het vrije energieverschil tussen de producten en de reactanten bepaalt of een reactie spontaan kan verlopen (ΔG). • De vrije energie die nodig om de activeringsenergie te overwinnen bepaalt hoe snel een reactie verloopt (ΔGǂ). [C ].[ D] ΔG = ΔG + RT ln [ A].[ B ] '0 ' At pH 7 add ' [C ].[ D] ΔG = 0 = ΔG + RT ln [ A ].[ B ] 0' ' ' At equilibrium '0 ΔG = − RT ln K eq R = gas constant = 8.315 10-3 kJ. mol-1. K-1 T = temperature in K, 25 °C = 298 °K ln x = 2.303 log x Together RTlnx = 5.71logx ' 0' log K eq = ΔG / − 5.71 0 ' [ C ][ D ] ' − ΔG / 5.71 K eq = = 10 [ A][ B ] If Δ G0' = -5.71 kJ.mol-1, the equilibrium shifts a factor of 10 to the right!!! Hydrogen bonds have energies ranging from 4 to 20 kJ.mol-1 Calculate the free energy for the isomerization of DHAP to GAP At equilibrium the ratio GAP/ DHAP is 0.0475 at 25 °C and pH 7, calculate the standard free energy. • ΔG0' = -2.303 x R x T x log K'eq = -2.303 x 8.315 x 10-3 x 298 x log (0.0475) = 7.55 kJ mol-1 • The reaction is endergonic under the standard conditions. • What will happen when the concentration DHAP is 2 x 10-4 M and GAP is 3 x 10-6 M? • ΔG' = 7.55 + 2.303 x RTlog([GAP]/[DHAP]) = 7.55 – 10.42 = -2.87 kJ mol-1 • The reaction is exergonic. The criterion of spontaneity is determined by the ΔG and not by the ΔG0'. Enzymes accelerate reactions by facilitating the formation of the transition state (8.3) v = factor x [s] x ǂ/RT -ΔG e • The free energy difference of the products minus that of the substrates of a reaction determine the direction of the reaction (ΔG) • The free energy of activation of a reaction determines the rate of a reaction (ΔG‡) • The essence of catalysis is optimizing the structure for the interactions of the transition state. • If the transition state is stabilized by 5.71 kJ.mol-1, the rate increases 10 fold. Figuur 9.38 en 9.42 Bindingsenergie wordt gebruikt om de DNA dubbelhelix te buigen waardoor water de fosfodiesterbinding kan bereiken en hydrolyseren The formation of an enzyme-substrate complex is the first step in enzymatic catalysis k2 k1 E+S ES k-1 k-2 E+P The formation of an enzyme-substrate complex (ES) The three dimensional structure of the catalytic subunit of protein A kinase. The inhibitor contains a pseudosubstrate sequence Arg-Arg-X(Asn)-Ala(Ser,Thr)-Ile Properties of the active sites of enzymes • The active site is a three dimensional cleft or crevice • The amino acid residues involved in binding the substrate(s) are called the catalytic groups • The active site takes a relative small part of the total volume of an enzyme • Substrates are bound to enzymes by multiple weak interactions • The specificity of binding depends on the precisely defined arrangement of atoms in an active site • Enzymes are flexible and the active site can be formed by the binding of the substrate (induced fit), extra free energy when bound water is liberated Ribbon diagram (A) and a schematic representation of the primary structure of lysozyme (B) The active site can be formed by amino acid residues from different parts of the polypeptide chain Substrates are bound by multiple weak interactions: • electrostatic interactions • hydrogen bonds • van der Waals forces • hydrophobic interactions -CH3 group in thymine Hydrogen bonds between ribonuclease (enzyme) and the uridine component of its substrate induce a high degree of specificity Three hydrogen bonds ~ 3*-8.4 = - 25.11 kJ.mol-1. Change in equilibrium about 25000 times ' K eq = 10 0 ' − ΔG / 5.71 = 10 25.11 / 5.71 = 25808 Enzyme kinetics: the Michaelis-Menten model (8.4) • The study of the rates of chemical reactions is called kinetics. • The study of the rates of enzyme-catalyzed reactions is called enzyme kinetics. • A kinetic description of enzyme activity (v) will help understand how enzyme functions. Rate of a chemical reaction S k P rate (v) = - ΔS/Δ T = k x [S]; k = rate constant Rate of an enzyme catalyzed reaction The formation of an enzyme-substrate complex is followed by product formation k1 E+S k2 ES k-1 E+P k-2 The rate the reaction is the rate of product formation Determination of the rate as a function of the substrate concentration k2 k1 E+S ES k-1 E+P k-2 The initial velocity (V0) is determined under steady state conditions Enzyme catalysis with formula k1 E+S k2 ES k-1 v = Vmax [S]/([S] + KM) KM = (k2 + k-1)/k1 Vmax = k2 [ET] Vmax = kcat [ET] E+P v = k2[ES] The significance of KM (KM = (k2 + k-1)/k1) • KM values vary between 10-7 M en 10-1 M • KM value is the substrate concentration with half of the binding sites occupied (half maximal velocity) • The KM value is an indication of the substrate concentration in vivo The significance of kcat - kcat of an enzyme is the number of substrate molecules that is converted per second into product per enzyme molecule under saturating substrate concentrations - kcat is also called the turnover number. Vmax = kcat[ET] - kcat is a direct measure of the catalytic capacity of an enzyme under saturating substrate concentrations - 1/kcat is time of a complete catalytic cycle. Most biochemical reactions include multiple substrates • Sequential reactions Ternary complex Most biochemical reactions include multiple substrates • Double-displacement (Ping-Pong) reactions Allosteric enzymes do not obey Michaelis-Menten kinetics M-M kinetics Allosteric kinetics Enzymes can be inhibited by specific molecules (8.5) Distinction between competitive, uncompetitve and noncompetitive inhibition (reversible inhibition) Competitive, uncompetitive and noncompetitive inhibition are kinetically distinguishable Competitive Uncompetitive Noncompetitive Chapter 15 Metabolism: Basic Concepts and Design Outline of chapter 15 • Metabolism is composed of many coupled and interconnected reactions • ATP is the universal currency of free energy in biological systems • The oxidation of carbon fuels is an important source of cellular energy (redox reactions) • Metabolic pathways contain many recurring motifs (the unifying themes of biochemistry) Living organisms require a continual input of free energy for: • the performance of mechanical work in muscles and other cellular movements • active transport of molecules and ions • the synthesis of macromolecules The free energy is derived from: • Sunlight: phototrophs are trapping sunlight in photosynthesis (conversion of energy-poor molecules like CO2 into energy-rich molecules like fatty acids and sugars). • Oxidation of compounds (foodstuffs): chemotrophs oxidize (carbon) compounds. Foodstuffs are generated by phototrophs. Metabolism is composed of many coupled and interconnected reactions (15.1) An example of a metabolic pathway: glycolysis. The free energy of the overall process must be negative. All reactions are catalyzed by enzymes. The activity of the glycolysis is regulated. Glucose metabolism in humans •Glucose is metabolized to pyruvate in 10 linked reactions. •Under anaerobic conditions pyruvate is metabolized to lactate (2 ATP). •Under aerobic conditions pyruvate oxidized to CO2 and H20 via acetyl CoA and the TCA cycle and respiratory chain (30 ATP). Free energy of metabolites of glycolysis in red blood cells (138) = concentration in μM - - - - Metabolic pathways can be divided into: • Catabolic reactions: catabolism: fuels (carbohydrates, fats) CO2 + H2O + useful energy • Anabolic reactions: anabolism: useful energy + small molecules complex molecules • Some pathways can be either anabolic or catabolic, depending on the energy conditions of the cell. They are referred to as amphibolic pathways De citroenzuurcyclus als amfibole route De citroenzuurcyclus wordt gebruikt om acetyl-groepen af te breken (katabolisme), maar dient ook als bron voor biosynthese (anabolisme). De omzetting van pyruvaat naar oxaloacetaat is hiervoor vereist. Een anaplerotische reactie Een belangrijke reactie in de vorming van glucose uit aminoen ketozuren is de carboxylering van pyruvaat tot oxaloacetaat. Deze reactie is gekoppeld aan ATP hydrolyse en wordt gekatalyseerd door het biotine bevattende enzym pyruvaat carboxylase. De door pyruvaat carboxylase gekatalyseerde reactie verloopt in drie stappen: 1) HCO3- + ATP HOCO2-PO32- + ADP 2) Biotine-enzym + HOCO2-PO32- CO2-biotine-enzym + Pi 3) CO2-biotine-enzym + pyruvaat oxaloacetaat biotine-enzym + Somreactie: Pyruvaat + HCO3- + ATP oxaloacetaat + ADP + Pi + H+ • De overall reactie heeft een standaard vrije energie van 0.8 kJ. mol-1. • De hydrolyse van ATP tot ADP en Pi heeft een standaard vrije energie van -31.4 kJ. mol-1. • In de reactiecyclus wordt CO2 geactiveerd. De splitsing van CO2 van het CO2-biotine-enzym complex heeft een standaard vrije energie van -19.3 kJ. mol-1. Dit hoog energetisch intermediair wordt gebruikt om pyruvaat te carboxyleren. • Welk belangrijk principe wordt door pyruvaat carboxylase gedemonstreerd? ATP hydrolysis drives metabolism or can perform work by shifting the equilibrium of coupled reactions A B ΔG0' = + 16.7 kJ mol -1 K'eq = [Beq]/[Aeq] = 10 - ΔG0'/5.71 = 1.19 x 10-3 = 1 / 841 At equilibrium 841 molecules of A and 1 molecule B or a protein in conformatie A or B!! Coupled with ATP hydrolysis (ΔG0' = -30.6 kcal mol -1) B + ADP + Pi + H+ A + ATP + H2O (ΔG0' = 16.7 – 30.6 = -13.9 kJ mol -1) K'eq = [Beq]/[Aeq] x ([ADP]eq [Pi]eq)/[ATP]eq = 10 - ΔG0'/5.71 = 2.72 x 102 M-1 The ATP-generating system in the cells maintains the ATP]/[ADP][Pi] ratio around 500 M-1. With this ratio is the equilibrium between A and B is shifted further towards excess B. K'eq x [ATP]cel/([ADP]cel [Pi]cel)= [Beq]/[Aeq] [Beq]/[Aeq] = 2.72 x 102 x 500 = 1.36 x 105 Thus by coupling with ATP hydrolysis the ratio [A]/[B] shifts from 1 A 841 to = B 1 136000 Why is ATP an energy-rich molecule? ΔG0’ = - 30.6 kJ/mol • ATP + H2O ADP + Pi + H+ : • ADP + H2O AMP + Pi + H+ • AMP + H2O adenosine + Pi + H+ : ΔG0’ = -14.3 kJ/mol : ΔG0’ = - 30.6 kJ/mol The structural basis of the high phosphoryl transfer potential of ATP •Resonance stabilization •Electrostatic repulsion •Stabilization of phosphate by hydration 3x 2x 2x Free phosphate (4x) has more energetic favorable resonance structures compared with the terminal phosphate of ATP or ADP The amount of ATP is limited. ATP is continuously regenerated • 100 g ATP in your body • In rest 40 kg turnover in 24 hours. Turnover 3.6 min • Running: 500 g / min. Turnover 0.2 min The ATP-ADP cycle The oxidation of carbon fuels is the only source of cellular energy for animals but not for microorganisms (15.3) (H2 gas) Free energy of oxidation of single carbon compounds In aerobic organisms the electron acceptor in the oxidation of carbon and hydrogen is O2 and the oxidation products are CO2 and H2O Fats are more efficient fuel source than carbohydrate because carbon is more reduced Stages in the extraction of cellular energy from foodstuffs, mainly reducing equivalents 8 e- = 3 x NADH, 1 x FADH2 Extraction of free energy in the form of ATP from fuel molecules • In catabolism, some ATP is generated (substrate level phosphorylation), but most of the free energy is temporary stored in the reducing equivalents extracted from fuel molecules. • The reducing equivalents are transferred to NAD+ and FAD. NADH and FADH2 are formed. • Reducing equivalents are transferred to an electron transport chain, a respiratory chain. • Free energy is stored in a proton gradient that drives the synthesis of ATP. Oxidation can be coupled directly to ATP synthesis De overgang van een C-H naar een C-OH binding produceert 58.6 kJ . mol-1 Energy of oxidation is trapped as a high phosphoryltransfer-potential compound and then used to form ATP Electron transport chains generates ion gradients across membranes providing an important form of cellular energy that can be coupled to ATP synthesis NADH, FADH2 The total process is called oxidative phosphorylation High-energy electrons: redox potentials and free-energy changes - The relation between a redox potential change and the free energy change of a reactions is: ΔG = −nFΔE ' ' ΔG = − nFΔE 0' ' 0 F = 96.49 kJ.V-1.mol-1 Redox potential + Redox potential (ΔE) and free energy (ΔG) • A 1.14-volt potential difference between NADH and O2 drives electron transport through the respiratory chain. This electron transport is coupled to the formation of a proton gradient (ΔG0 = -2 x 96.49 x 1.14 = -220 kJ.mol-1) • A strong reductant has a negative reduction potential, a strong oxidizing agent has a positieve reduction potential Standard reduction potentials of biological important reactions The mitochondrial electron transport chain, bacterial respiratory chains function essential similar ATP synthesis from a proton gradient Comparison between photosynthesis and oxidative phosphorylation Figuur 19.25 Licht wordt gebruikt om electronen naar een sterkere reductor over te brengen Figuur 18.6 Figuur 19.23 Metabolic pathways contain many recurring motifs (15.3) • Activated carriers • Key reactions are reiterated • Metabolic processes are regulated in only three principle ways Activated carriers of electrons for fuel oxidation Structures of the oxidized forms of nicotinamidederived electron carriers NAD+ • R = H: NAD+ • R= PO3 : NADP+ • The nicotinamide ring of NAD+ accepts a hydrogen atom and two electrons, which is equivalent to a hydride ion, H- NADPH is the reductant in biosynthesis, NADH is used primarily for the generation of ATP Flavin adenine dinucleotide is an electron carrier • FAD consists of flavin mononucleotide and an AMP unit • The molecule accepts 2 electrons and 2 protons The redox reaction of FAD Redox reactions and the involved redox carriers (NAD(P)+) H- (hydride) transfer • The redox reaction catalyzed by NAD+ dependent redox enzymes. • NAD+ always functions as coenzyme (cosubstrate) Redox reactions and the involved redox carriers (FAD) H (hydrogen) transfer • The redox reaction catalyzed by FAD dependent redox enzymes • FAD is always bound to the enzyme (prosthetic group) Coenzyme A is the carrier for activated acyl groups CoA ΔG0' of hydrolysis is -30.6 kJ mol-1 Carriers used in metabolism The activated carriers are (kinetically) stable Key reactions are reiterated throughout metabolism The six fundamental reactions types are the basis of all reactions of metabolism Oxidation-reduction reactions Ligation reactions form bonds by using the free energy from ATP hydrolysis Isomerization reactions Group-transfer reactions Hydrolytic reactions The hydrolysis of a peptide bond Lyases: enzymes that catalyze the addition or the removal of functional groups to/from double bonds or the cleavage involving electron rearrangement rearrangements Metabolic processes are regulated in three different principle ways • The amount of enzymes – rate of transcription • The catalytic activity of the enzymes – – – – reversible allosteric control feed back inhibition reversible covalent modification hormones coordinate metabolic relations between different tissues often via reversible covalent modification of key enzymes • The accessibility of substrates – controlling the flux of substrates from one compartment to another (e.g. cytosol to mitochondria). Biosynthetic and degradative pathways are almost always distinct for energetic reasons [ ATP ] + 12 [ ADP ] Regulation by the energy charge = [ ATP ] + [ ADP ] + [ AMP ] The evolution of metabolic pathways • Why do activated carriers such as ATP, NADH, FADH2 and coenzyme A contain adenosine diphosphate units? • Binding to a uracil unit in a niche of an RNA enzyme (ribozyme) in the RNA world • In the protein world, the carrier function could be continued without any adaptation