Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
ENZYMES Enduring Understanding All biological systems need catalysts to alter speed of chemical reactions in the system. Organic catalysts are proteins, therefore they are affected by extremes of temperature and pH changes. Catalysts Chemicals that speed up chemical reactions Not changed at end of reaction Why do we need catalysts in biological systems? Without them the chemical reactions vital to life could not take place quickly enough. Eg. digestion, respiration Biological Molecules 3.2 Enzymes Enzymes and Activation Energy THEME ONE: PRINCIPLES OF BIOLOGY 3.2Enzymes Enzymes • Biological catalysts made up of tertiary proteins. • Produced by living cells (organic) • Speed up chemical reactions • Not changed at end of chemical reaction • Specific in their reaction Structure of enzymes Polypeptides (chains of amino acids) are folded around each other to form a roughly spherical structure. Results in 3-dimensional shape. The shape is maintained by hydrogen bonds. Folding gives rise to active site (place at which enzyme reaction takes place) ACTIVE SITE Pockets or clefts on enzyme surface Shape is complementary to substrate, therefore specific This is where the enzyme substrate reaction actually occurs. High temperature results in loss or alteration of active site, ie. denatured TYPES OF ENZYMES Intracellular These are both made and have their action inside cells. Eg. photosynthetic enzymes inside chloroplasts Extracellular These are made inside the cells but have their action outside the cell. Eg. digestive enzymes in the human gut, enzymes released by fungi and bacteria (decomposers) Naming enzymes Based on what it reacts with (substrate) Add -ase to ending Eg. enzyme lactase – reacts with substrate lactose, a sugar enzyme salivary amylase reacts with substrate starch Example Hydrolytic / digestive enzymes - chemically breaks down larger molecules in the presence of water. Eg. amylase, lipase, proteases, HOW ENZYMES WORK enzyme substrate Click on the link below http://www.bbc.co.uk/education/asguru/biology/02biolo gicalmolecules/01proteins/11enzymes/index.shtml STEPS IN ENZYME REACTION Substrate molecule fits into complementary active site Enzyme-substrate complex formed. Reaction takes place Substrate leaves active site. Enzyme is ready for another reaction NB: A small quantity of enzyme can bring about a large amt of reaction. For an enzyme to work, it must .... 1. Come into physical contact with its substrate 2. Have an active site which fits the substrate Any factor that influence the rate at which an enzyme works do so by affecting one or both of the above conditions. Effect of temperature on enzyme catalysed reaction. (Pg 68, txtbook) At low temperature, the enzyme is less active. Why? Recall kinetic theory + condition 1. As temp. increases, enzyme activity increases. At optimum temperature, enzyme is most active. Beyond optimum temperature, the enzyme begins to denature, ie. The weak bonds within the enzyme start to break down, the enzyme begins to lose its 3-D structure and active site. Therefore, rate of reaction declines. At very high temperature, reaction stops. Enzyme is completely denatured, irreversible structural change into a simple chain of protein. Enzymes are proteins, so ..... Sensitive to temperature Sensitive to pH changes. Effect of Substrate Concentration At low substrate concentrations, the active sites of enzyme molecules are not all occupied. So reaction is fast. WHY?? As substrate concentration increases, more and more of the active sites are being occupied for reaction. Further increase in substrate concentration will not increase speed of reaction. WHY?? Enzyme concentration When there are excess substrate molecules, the speed of reaction is directly proportional to enzyme concentration. A student who had seen a cook place slices of fresh pineapple on top of meat before cooking it, decided to carry out some experiments using fresh pineapple juice. A milk agar was prepared by mixing fat-free milk and warm water with agar powder. It was then poured into a sterilised petri dish and allowed to cool. After it had set, five holes were made in the milk agar. Each hole was filled with a different substance, as shown in Fig. 1.1 The petri dish was then kept at 400C for 2 hours. The results obtained are shown in Fig. 1.2. Explain the results obtained for each of the holes 1-5. THE END