Enzymology Lesson 5 PDF
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Universidad CEU San Pablo
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This document presents a lesson on enzymology, covering concepts like the importance of enzymes in biological reactions, water-soluble vitamins as coenzymes, enzyme regulation, and enzymatic kinetics. Different aspects of enzyme structure and function are detailed, including active sites, specificity, and efficiency.
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ENZYMOLOGY LESSON 5 Enzymology Concept Importance of enzymes in the development of biological reactions. Water-soluble vitamins as coenzymes. Regulation of enzyme activity Structure of enzymes Enzyme: A protein that catalyzes a specific chemical reaction Active site: The region of...
ENZYMOLOGY LESSON 5 Enzymology Concept Importance of enzymes in the development of biological reactions. Water-soluble vitamins as coenzymes. Regulation of enzyme activity Structure of enzymes Enzyme: A protein that catalyzes a specific chemical reaction Active site: The region of an enzyme surface that binds the substrate molecule and catalytically transforms it; also known as the catalytic site. Their catalytic activity depends on the integrity of their native protein conformation The surface of the active site is lined with amino acid residues with substituent groups that bind the substrate and catalyze its chemical transformation Increase the speed of the reaction Enzymes properties High specificity: Substrate specificity: They can bind only one substrate Reaction: They always catalyze the same reaction Efficiency: proximity creates tension between the substrate and catalytic residues. Increase the reaction rate in mild conditions: Compatible with life Enzymatic reactions occur in specialized pockets called active sites Under regulation: Some agents can modulate their activity by modifying the active site. How do enzymes work? CHEMICAL REACTION Initial compound Final compound Intermediate Initial energy state Final state (less energy than Transition state (higher energy) the initial compound) To reach the intermediate compound, a lot of activation energy needs to be given to the substrate. How do enzymes work? ENZYMATIC REACTION Enzymes increase reaction rates, lowering reaction activation barriers Steps in an enzymatic reaction: 1. E-S complex is formed 2. E-S complex is transformed into a transition complex. 3. Formation of the E-P complex 4. Separation of the E-P complex into enzyme and product. Enzymatic kinetics The study of the rate of a reaction and how it changes in response to changes in experimental parameters 𝑑𝑑𝑑𝑑 𝑑𝑑𝑑𝑑 V0 = − = = Slope 𝑑𝑑𝑑𝑑 𝑑𝑑𝑑𝑑 Product concentration will increase as substrate concentration declines Rate or velocity of a reaction (V0): number of substrate molecules converted to product per unit time Enzymatic kinetics (EXTERNAL) FACTORS AFFECTING REACTION RATE Enzyme concentration Substrate concentration [E] V0 [S] V0 *Until maximum velocity is reached pH Each enzyme has an optimal pH and Maximum velocity (Vmax): Maximum rate of a Temperature temperature for its activity reaction when the enzyme is saturated with substrate (all the enzymes are attached to substrate) Metabolic pathway Metabolic pathway: Sequences of consecutive enzymatic reactions in which the product of one reaction becomes the substrate in the next one Each metabolic pathway consists of several reactions with several enzymes. Each pathway includes one or more enzymes that have a greater effect on the rate (velocity) of the overall sequence. Regulatory enzyme: An enzyme with a regulatory function, through its capacity to undergo a change in catalytic activity by allosteric mechanisms or by covalent modification. Changes in the rate of a metabolic pathway occur because at least one enzyme in that pathway, the regulatory enzyme, has been activated or inhibited, or the amount of enzyme has increased or decreased. Regulators of enzyme activity Allosteric enzyme: A regulatory enzyme with catalytic activity modulated by the ALLOSTERIC REGULATION noncovalent binding of a specific metabolite at a site other than the active site. Allosteric inhibitor Allosteric activator Allosteric site: The specific site on the surface of an Allosteric modulators or effectors: small allosteric protein molecule to which the modulator or metabolites or cofactors that bind to the allosteric site effector molecule binds.. of an allosteric enzyme and modify its catalytic activity Regulators of enzyme activity REVERSIBLE COVALENT MODIFICATION The activity is modulated by covalent modification of one or more of the amino acid residues in the enzyme molecule Charasteristic in hormonal signal adrenaline, glucagon or insulin The most common covalent modification Phosphorylation REVERSIBLE COVALENT MODIFICATION Regulators of enzyme activity Coenzymes PARTS IN AN ENZYME Apoenzyme: The protein portion of an enzyme Prosthetic group: A metal ion or organic compound (other than an amino acid) covalently bound to a protein and essential to its activity. Cofactor inorganic ions Coenzyme complex organic or metalloorganic molecule Group transports Coenzyme A Vitamins Electron transfer NADH, FADH2 Derive from hydrosoluble vitamins (C and all the B group). Coenzyme Q Non-vitamins NTP
