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Tuesday, July 21, 2015 Unit 4: Respiration Title: Link reaction and Krebs cycle Keywords: • the link reaction Learning Objectives: • Krebs cycle We are learning…. • acetylcoenzyme A • What is the link reaction? • FAD • What happens during the Krebs cycle? • What are hydrogen carrier molecules and what is their role in the Krebs cycle? Starter: Quick recap Describe what happens to a molecule of glucose during glycolysis. Glycolysis Glucose (6C) 2 ATP phosphorylation Initial energy investment 2 ADP Fructose diphosphate (6C) Glyceraldehyde 3-phosphate (3C) Glyceraldehyde 3-phosphate (3C) Glyceraldehyde 3-phosphate (3C) Glyceraldehyde 3-phosphate (3C) G3P is oxidised and NAD is reduced Energy Production NAD NAD Reduced NAD Reduced NAD 2 ADP 2 ADP 2 ATP 2 ATP Pyruvate (3C) Pyruvate (3C) What Happens Where? Glycolysis = Cytoplasm of the cell. Link reaction = Matrix of the mitochondria. Krebs cycle = Also in the matrix. Electron transfer chain Utilises proteins found in the membrane of the christa. Linking glycolysis and the Krebs cycle The pyruvate molecules produced during glycolysis possess potential energy that can only be released using oxygen in a process called the Krebs cycle. Before pyruvate molecules can enter the Krebs cycle, they must first be oxidised. This oxidation happens during the link reaction. The Krebs cycle and the link reaction take place in the mitochondria in eukaryotic cells. In prokaryotes, these reactions take place in the cytoplasm and plasma membrane. What is a coenzyme? Coenzymes are molecules that some enzymes require in order to function. Coenzymes play a major role in photosynthesis and respiration where they carry hydrogen atoms from one molecule to another. Examples of coenzymes include: NAD – accepts hydrogen ions to become NADH2 (reduced NAD) FAD – accepts hydrogen ions to become FADH2 (reduced FAD) in the Krebs cycle NADP – accepts hydrogen ions to become NADPH2 (reduced NADP) during photosynthesis. Methylene blue is a blue dye which accepts hydrogen ions and becomes reduced (colourless). Scientists use it to model how coenzymes work. Blue to colourless = hydrogen ions produced so respiration happening. The link reaction Before pyruvate enters the Krebs cycle it combines with a compound called coenzyme A to form acetyl coenzyme A. First of all pyruvate is oxidised by removing hydrogen (loss of electrons). This hydrogen is accepted by NAD to form reduced NAD (NADH2).The reduced NAD is later used to produce ATP. Carbon dioxide is also given off (2 x CO2). The 2-carbon molecule, called an acetyl group, then combines with coenzyme A to form acetylcoenzyme A and a molecule of CO2 is released. The 2-carbon acetyl coenzyme A now enters the Krebs cycle. To summarise: • Pyruvate is decarboxylated: CO2 is removed. • It is added to CoA to form Acetyl CoA • Acetyl CoA is then ready for use in the Krebs Cycle. The Link reaction is important as acetyl-CoA is needed for the Krebs cycle to happen. The Krebs cycle The idea of the Krebs cycle is to ‘unlock’ the remainder of the energy from the glucose molecule. Some of this energy (2 ATP) was released during glycolysis, but most remains in pyruvate. During the Krebs cycle, pyruvate molecules enter the mitochondria and, in the presence of oxygen, are broken down to carbon dioxide and hydrogen atoms. The Krebs cycle is also knows as the citric acid cycle and tricarboxylic acid cycle. The Krebs Cycle Acetyl Coenzyme A (2C) Oxaloacetate (4C) NAD Citrate (6C) Reduced NAD FAD Reduced FAD NAD Reduced NAD ADP ATP (4C) CO2 (5C) Reduced NAD NAD CO2 What happens during the Krebs cycle? The 2-carbon acetyl coenzyme A enters the Krebs cycle. It combines with the 4-carbon oxaloacetate (oxaloacetic acid) to give the 6-carbon citrate (citric acid). Coenzyme A is reformed and may be used to combine with a further pyruvate molecule. The citrate is degraded to a 5-carbon α-ketogluterate (αketoglutaric acid) and then the 4-carbon oxaloacetate by the loss of two carbon molecules. This completes the cycle. What happens during the Krebs cycle? For each turn of the cycle, a total of four pairs of hydrogen atoms are also formed. Of these, three pairs are combined with the hydrogen carrier nicotinamide adenine dinucleotide (NAD) and yield 2.5 ATP’s for each pair of hydrogen atoms. The remaining pair combines with a different hydrogen carrier, flavine adenine dinucleotide (FAD) and yield only 1.5 ATP’s. Each cycle produces enough energy to yield a single molecule of ATP. Energy yields Remember that all of the products of the Krebs cycle (NAD, FAD, ATP, etc.) formed from a single pyruvate molecule. There are two pyruvate molecules produced from a single glucose molecule. The total yields from a single glucose molecule are therefore double those stated. So for example…… Energy yields continued…. 1 pyruvate produces…. (Link reaction – ATP released later on) Pyruvate to Acetylcoenzyme A = 1 x NADH2 = 1 x 2.5 = (2.5 ATP) Krebs cycle (ATP produced during electron transport chain) Citrate to α-ketogluterate = 1 x NADH2 = 1 x 2.5 = (2.5 ATP) α-ketogluterate to oxaloacetate = 2 x NADH2 = 2 x 2.5 = (5 ATP) 1 x FADH2 = 1 X 1.5 = (1.5 ATP) ATP produced directly (no carriers) = 1 ATP You must double these values because glucose produces two pyruvate molecules. So 12.5 x 2 = (25 ATP) from Link and Krebs Add this to (7 ATP) from glycolysis = 32 ATP Key Questions 1. Where does the link reaction and krebs cycle take place? 2. What is pyruvate converted to during the link reaction? 3. What is the final 4 carbon molecule called in the krebs cycle? 4. How many molecules of reduced NAD are produced per molecule of glucose in the link reaction and Krebs cycle? 5. How many molecules of FAD are produced per molecule of glucose in the Krebs cycle? 6. How many molecules of ATP are produced per molecule of glucose in the Krebs cycle? 7. What is the waste product of the two chemical pathways? Summary of Link Reaction and Krebs Cycle Per molecule of glucose: • 8 molecules of reduced NAD are produced (2 x 4). • 2 molecules of reduced FAD are produced (2 x 1). • 2 molecules of ATP are produced. • 6 molecules of CO2 are produced as waste products (2 x 3). Main Activity: Success Criteria: What I’m looking for….. Plenary: How Science Works Plenary: How Science Works Plenary: How Science Works How successful were we this lesson? Learning Objective We were learning…..