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Download Unit 1 PPT 3 (2biii-iv Binding and conformation)
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Transcript
AH Biology: Unit 1 Proteomics and Protein Structure 3 Binding to Ligands Think • How is protein production controlled? • Why is it important that protein production is controlled? • Why is protein structure important in relation to its function? Binding to ligands • A ligand is a substance that can bind to a protein. • R groups not involved in protein folding can allow binding to these other molecules. • Binding sites will have complementary shape and chemistry to the ligand. • The ligand can either be a substrate or a molecule that affects the activity of the protein. Nucleosomes Nucleosomes • Nucleosomes animation • DNA replication animation Transcription • Other proteins have binding sites that are specific to particular sequences of doublestranded DNA and when bound to can either stimulate or inhibit initiation of transcription. • lac Operon • Transcription animation Binding changes the conformation of a protein • Enzymes and proteins are three-dimensional and have a specific shape or conformation. • As a ligand binds to a protein binding site, or a substrate binds to an enzyme’s active site, the conformation of the protein changes. • This change in conformation causes a functional change in the protein and may activate or deactivate it. Induced fit • In enzymes, specificity between the active site and substrate is related to induced fit. • When the correct substrate starts to bind, a temporary change in shape of the active site occurs, increasing the binding and interaction with the substrate. • Induced fit Induced fit Activation energy lowered Allosteric enzymes • An allosteric enzyme is an enzyme that can have its activity altered by a ligand called a modulator. • In allosteric enzymes, modulators bind at secondary binding sites away from the active site. • The conformation of the enzyme changes and this alters the affinity of the active site for the substrate. Modulators • Negative modulators reduce the enzyme’s affinity for the substrate. • Positive modulators increase enzyme affinity for the substrate. Negative modulators Negative modulators • End product inhibition occurs when the final product of a cascade of enzyme reactions interacts with an allosteric site of the first enzyme in the cascade to inhibit it and thus the production of the end product. • This is an example of negative feedback. • End product inhibition animation Competitive inhibition Competitive inhibition example 1 • Ethanol is metabolised in the body to acetaldehyde by oxidation with alcohol dehydrogenase, which is in turn further oxidised to acetic acid by aldehyde oxidase enzymes. • Normally, the second reaction is rapid so acetaldehyde does not accumulate in the body. • A drug called disulfiram (Antabuse) inhibits the aldehyde oxidase, which causes the accumulation of acetaldehyde with subsequent unpleasant side effects of nausea and vomiting. • This drug is sometimes used to help people overcome alcoholism. Competitive inhibition example 2 • Methanol poisoning occurs because methanol is oxidised to formaldehyde and formic acid, which attack the optic nerve and cause blindness. • Ethanol is given as an antidote for methanol poisoning because ethanol competitively inhibits the oxidation of methanol. • Ethanol is oxidised in preference to methanol and consequently the oxidation of methanol is slowed down and the toxic by-products do not have a chance to accumulate. • The methanol is then excreted in the urine. Competitive inhibition example 3 • Ethylene glycol, if ingested, can be poisonous. • Ethylene glycol is oxidised by the same enzymes used in the previous two examples. • Ethylene glycol → glycolaldehyde → glycolic acid. • Glycolic acid is toxic to the nervous system and kidneys. • Describe how ethanol can be used as an antidote. Non-competitive inhibition Enzyme kinetics and inhibition Competitive inhibition Competitive inhibition • If the concentration of inhibitor is less than that of the substrate and the substrate has a higher affinity for the active site, is the enzyme inhibited a lot or a little? • If the concentration of inhibitor is more than that of the substrate is the enzyme inhibited a lot or a little? • If the enzyme is inhibited and we then increase the substrate concentration what happens to the initial rate of reaction? Non-competitive inhibition Competitive inhibition Non-competitive inhibition Enzyme kinetics and inhibition Positive modulators • Positive modulators increase the enzyme affinity for the substrate by altering the shape of the active site so that it has a better fit for the substrate. • Positive modulation animation of a steroid on a GABAA receptor linked ion channel. Enzyme kinetics questions • Enzyme kinetics questions. Cooperativity in haemoglobin • Binding and release of oxygen in haemoglobin. Cooperativity in hemoglobin • Deoxyhaemoglobin has a relatively low affinity for oxygen. • As one molecule of oxygen binds to one of the four haem groups in a hemoglobin molecule it increases the affinity of the remaining three haem groups to bind oxygen. • Conversely, oxyhaemoglobin increases its ability to loose oxygen as oxygen is released by each successive haem. • This creates the classic sigmoid shape of the oxygen dissociation curve. Cooperativity in haemoglobin Effects of temperature and pH • Low pH = low affinity. • High temperature = low affinity. • Exercise increases body temperature and produces CO2, acidifying the blood. • This has a corresponding effect on the oxyhaemoglobin dissociation curve. Bohr effect Oxygen dissociation curve • Oxygen dissociation review in relation to a patient admitted to hospital. • What sort of conditions affect the ability of red blood cells to transport oxygen? • Under what conditions would haemoglobin struggle to bind oxygen? Red blood cell disorders • Sickle cell anaemia • Thalassaemia High-altitude conditions • High-altitude medicine • High-altitude effects: BBC Horizon, ‘How to Kill a Human Being’ Think • How is protein production controlled? • Why is it important that protein production is controlled? • Why is protein structure important in relation to its function?
