RESPIRATION 4 2 Link Reaction and Krebs Cycle
RESPIRATION 4. 2 Link Reaction and Krebs Cycle
Learning Objectives Success Criteria Describe what the link reaction is Produce accurate notes on the link reaction Describe what happens during the Krebs cycle Summarise in a diagram the key events in the Krebs cycle Explain the role of hydrogen carrier molecules in the Krebs cycle Carry out an experiment and analyse the results to demonstrate the role of coenzymes in respiration
Starter Write down the word equation for Glycolysis What is used up in glycolysis? What else is produced in glycolysis?
Glycolysis Glycogen NAD+ + 2 H NADH + H+ (oxidised form ) (reduced form) NB Rather then write NADH, examiners often simply refer to it as reduced NAD or reduced coenzyme You start with glycogen. 2 ATP 4 ADP + 4 Pi Glyceraldehyde 3 -phosphate (3 C x 2) Glucose (6 C) 2 ADP 4 ATP Pyruvate (3 C x 2) 2 H x 2 NAD Reduced NAD Nicotinamide adenine dinucleotide = So it gains electrons You finish with Pyruvate
Respiration The process of respiration can be split into 4 stages. 1. 2. 3. 4. Glycolysis Link reaction Krebs Cycle Electron Transport Chain
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.
Products of Glycolysis 2 reduced NAD (NADH + H+) 2 Pyruvate 2 ATP The Fate of Pyruvate? THIS DEPENDS ON THE AVAILABILITY OF OXYGEN!!!
Aerobic Respiration If O 2 is present 3 C pyruvate passes into mitochondria. Here it is completely oxidised forming CO 2 and H 2 O. The second stage of aerobic respiration is the link reaction.
The Link Reaction Cytoplasm Glycolysis The Link reaction Mitochondria The Krebs Cycle Links Glycolysis to the Krebs Cycle. The end product of the link reaction can enter the Krebs Cycle.
NAD+ NADH + H+ Acetate (2 C) Pyruvate (3 C) Coenzyme A Acetyl coenzyme A (2 C) CO 2 Coenzyme A now combines with the Acetate The Pyruvate is decarboxylated (CO 2) to form Start with Pyruvate produced in Glycolysis This produces Acetate Acetyl coenzyme It is also dehydrogenated (H+Aremoved) The Acetyl coenzyme A now enters Krebs cycle
Link Reaction One carbon atom is removed from pyruvate in the form of CO 2. The remaining 2 -carbon molecule combines with coenzyme A to produce acetylcoenzyme A (acetyl Co. A). Another oxidation reaction occurs when NAD+ collects more hydrogen ions. This forms reduced NAD (NADH + H+) No ATP is produced in this reaction. Pyruvate(3 C) Decarboxylation CO 2 (1 C) Oxidation Coenzyme (Co. A) NAD+ Reduction NADH + H+ Acetyl Co. A (2 C)
The Link Reaction occurs Twice for every Glucose Molecule For each glucose molecule used in glycolysis, two pyruvate molecules are made. But the link reaction uses only one pyruvate molecule, so the link reaction and the Krebs cycle happen twice for every glucose molecule which goes through glycolysis. Overall equation for one link reaction and Kreb cycle: Pyruvate + NAD + Co. A acetyl Co. A + reduced NAD + CO 2
The Products of the Link Reaction go to the Krebs Cycle and the ETC So for each glucose molecule: 2 acetylcoenzyme A (go into the Krebs cycle) 2 Carbon dioxide (released as a waste products) 2 Reduced NAD (go to the electron transport chain)
Krebs Cycle Sir Hans Krebs in 1937 AKA Citric acid cycle or the Tricarboxylic acid cycle (TCA cycle) Takes place in the matrix.
Krebs Cycle From one glucose molecules you get 2 pyruvate molecules. So Krebs cycle go around twice per glucose molecule.
The Krebs Cycle Acetyl Coenzyme A (2 C) NA Re NA duce d D FAD D (4 C) Reduced FAD (4 C) P D A i P + P T A Coenzyme A 2 C Oxaloacetate (4 C) Citrate (6 C) CO 2 CO NAD Reduced NAD (5 C) 2 NA (4 C) D Re NA duce d D
De. Na A Fa. . . Na This little tune will help you to remember the Krebs Cycle. Remember, respiration is all about releasing energy from your food. Oxidation releases energy. When a carbon compound is oxidised, coenzymes are reduced. The coenzymes involved are: NAD and FAD. Carboxylation is the removal of CO 2. Remember this: 665 and five 4’s.
DENA A FA. . . NA DENA: Decarboxylation and production of reduced NAD A: Production of ATP FA. . . : Production of reduced FAD (The ‘. . . ’ means a gap) NA: Production of reduced NAD
The Krebs Cycle: DENA A FA. . . NA Acetyl Coenzyme A (2 C) NA D Re N d u NA ce A d D FAD (4 C) FA Reduced FAD (4 C) P D A i P + A P T A Coenzyme A 2 C Oxaloacetate (4 C) Citrate (6 C) CO 2 NAD DENA Reduced NAD DE (5 C) NA (4 C) NA D Re NA duce d D
Krebs Cycle Summary Each Acetyl Co. A entering the cycle results in: 1. 2 CO 2 molecules 2. 1 ATP molecules (S. L. P) 3. 8 pairs of H atoms (Later used in the E. T. C to produce ATP) Used to reduce NAD and FAD. Three reduced NAD are produced and 1 reduced FAD per cycle. NAD = Nicotinamide adenine dinucleotide FAD = Flavine adenine dinucleotide
Coenzymes in Respiration • Coenzymes are complex organic molecules that are used by enzymes to accept or donate molecules involved in a reaction. • They are often referred to as ‘Helper’ molecules as they carry chemical groups or ions about, e. g. NAD removes H+ and carries it to other molecules. Now carry out the practical about Coenzymes in respiration
Homework 1. Complete the questions on the practical sheet 2. Read ‘coenzymes in respiration’ on page 55 of the textbook then answer questions 1 -5
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