1 / 23

RESPIRATION

RESPIRATION. The stepwise breakdown of glucose to carbon dioxide and water to release energy. Aerobic respiration. References: Rowland pages 120 - 132 Collins pages 11 - 17 Aerobic respiration glucose + oxygen carbon dioxide and water + energy

holmes-king
Télécharger la présentation

RESPIRATION

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. RESPIRATION The stepwise breakdown of glucose to carbon dioxide and water to release energy

  2. Aerobic respiration • References: Rowland pages 120 - 132 Collins pages 11 - 17 • Aerobic respiration glucose + oxygen carbon dioxide and water + energy C6H12O6 + 6O2 6CO2 + 6H20 + 38 mols ATP • A great deal of energy is released when glucose is oxidised to carbon dioxide and water in the presence of oxygen. If all this energy was released in one go, as it is in combustion, it would damage the cell. • It is released in a stepwise catabolism of glucose to release usable amounts of energy to produce ATP

  3. ATP • ATP - adenosine triphosphate = adenosine P - P - P • ADP - adenosine diphosphate = adenosine P - P ADP + P ATP ATP ADP + P + energy for all cell activities

  4. Oxidation and reduction (redox) Three ways in which oxidation and reduction occurs in respiration • Direct involvement of oxygen A + O2 AO2 (oxidation = addition of oxygen) AO2 A + O2 (reduction = removal of oxygen) • Removal/addition of hydrogen AH A + H(oxidation = removal of hydrogen) A + H AH (reduction = addition of hydrogen) • Removal/addition of electrons Ae- A + e- (oxidation = removal of electrons) A + e- Ae- (reduction = addition of electrons)

  5. Hydrogen carriers • Oxidation of substrates in respiration often involves the removal of hydrogen atoms (dehydrogenation) and is important in the synthesis of ATP. • With the help of a dehydrogenaseenzyme, hydrogen atoms are removed from a compound and taken up by a hydrogen carrier (acceptor) • There are two types of hydrogen carriers in respiration: NAD nicotinamide adenine dinucleotide FAD flavine adenine dinucleotide AH2 NAD BH2 A NADH + H+ B

  6. Aerobic respiration can be divide into 4 stages • Glycolysistakes place in the cytoplasm • Link reaction • Krebs cycletake place in the mitochondria • Electron transport chain Total yield of ATP from one molecule of glucose = 38ATP

  7. GLYCOLYSIS • Takes place in cytoplasm • Does not need oxygen • Each glucose molecule yields 2 ATP molecules • Common to both aerobic and anaerobic respiration Glycolysis represents a series of reactions in which one molecule of glucose is broken down into 2 molecules of pyruvate. 3 main steps: • Phosphorylation of glucose(6C) to form fructose diphosphate (6C) • Fructose diphosphate split into two molecules of 3C sugars • Conversion of two 3C sugars into two molecules of pyruvate (3C) • Net gain of 2 ATP and 2 NADH + H+

  8. Glycolysis Read textbook references • Rowland pages122 – 125 • Collins page 11-12 • Make notes on glycolysis

  9. What happens next? • If no oxygen is available: Pyruvate is converted (reduced) to lactate by accepting hydrogen from NADH There is no further production of ATP, so net gain of anaerobic respiration is 2 ATP from 1 molecule of glucose • If oxygen is available: • Pyruvate enters the mitochondria and will be fully oxidised to carbon dioxide and water and 38ATP produced • The mitochondrion is the site of the Link Reaction, the Krebs Cycle and the Electron Transport Chain

  10. Into the mitochondrion • Need to know the structure of a mitochondrion and to be able to recognise electronmicrographs; see Core Principles • The Link Reaction and the Krebs Cycle occur in the matrix of the mitochondrion • The Electron Transport Chain takes place on the membranes of the cristae • The cristae are highly folded to increase the surface area for the reactions to take place

  11. The Link Reaction • The Link Reaction links glycolysis to the Krebs Cycle. • Oxygen is needed for the process • It occurs in the matrix of the mitochondrion • The products are all x 2 as there are 2x pyruvates which enter the Link Reaction

  12. So what happens? • Pyruvate enters the mitochondria (the inner mitochondrial membrane is impermeable to glucose and other intermediates) • The 3-carbon pyruvate combines with the carrier molecule coenzyme A (CoA) • It forms a 2-carbon compound called acetyl coenzyme A (acetylCoA) • The extra carbon is lost as carbon dioxide. • NAD+ removes hydrogen to form reduced NAD(NADH +H+) • The process is therefore called oxidative decarboxylation

  13. The Krebs Cycle • Oxygen is needed for the process to occur • It takes place in the matrix of the mitochondrion • The cycle goes round twice for every molecule of glucose oxidised; the products are, therefore, all x2 • It is where most of the oxidation takes place in aerobic respiration • It results in the complete breakdown of pyruvate to carbon dioxide and water

  14. So what happens? • Acetyl coenzyme A enters the cyclic series of reactions called the Krebs Cycle • The 2-carbon acetyl part of the molecule joins up with a 4-carbon acceptor molecule to form a 6-carbon acid • There are 2 decarboxylations to regenerate the 4-carbon acceptor molecule and to release 2 molecules of carbon dioxide • Hydrogens and electrons are removed at 4 points in the cycle; involves NAD+ at three points and FAD at one point • One molecule of ATP is produced for each turn of the cycle; called substrate level phosphorylation

  15. Result At the end of glycolysis, the Link Reaction and Krebs Cycle for every glucose molecule oxidised: • Glycolysis 2NADH 2ATP • Link Reaction 2NADH 2CO2 • Krebs Cycle 6NADH 2ATP 4CO2 2FADH2 So where are the 38 ATP molecules? Don’t miss next week’s exciting instalment!

  16. Link Reaction and Krebs Cycle • Read textbooks and make notes on Link Reaction and Krebs Cycle • Rowland page 124 onwards • Roberts page 101 onwards • Collins page 12-13

  17. Electron Transport Chain • Oxygen is needed • Takes place in the phospholipid bilayer of the inner mitochondrial membranes - the cristae • Reduced coenzymes NAD (NADH + H+) and FAD (FADH2) are re-oxidised to release large amounts of ATP • 34 molecules of ATP are produced from the oxidation of the reduced coenzymes

  18. So what happens? • Reduced NAD and FAD are reoxidised by the removal of hydrogen by dehydrogenase enzymes located on the cristae of the inner membrane of the mitochondrion. • Each hydrogen atom is split into ahydrogen ion (H+) and an electron (e-) • The electrons then pass from one electron carrier molecule to another electron carrier molecule; • Electron carrier molecules in the ETC are called cytochromes and are proteins embedded in the cristae membranes • The electron carrier molecules are at successively lower energy levels

  19. And more …… • As the electrons are transferred from one carrier to another some of their energy is released and used to convert ADP into ATP • One molecule of ATP is formed every time an electron is transferred from one carrier to the next • The removal of hydrogen ions and electrons is oxidation and so the overall reactions of the ETC are known as oxidative phosphorylation • Finally,each electron is reunited with a hydrogen ion(H+) which immediatelycombines with oxygen to form water

  20. ETC - even more detail! • As the electrons are passed from one electron carrier to another, the energy released is used to actively pump hydrogen ions (H+ - protons) from the matrix into the space between the inner and outer membranes of the mitochondrion • Hydrogen ions accumulate and this sets up a large hydrogen ion gradient with a higher concentration of H+ in the inter-membrane space than in the matrix; this makes it more positively charged. • Hydrogen ions can only diffuse back down the concentration and electrical gradients through large protein carrier molecules which span the membrane, called ATP synthases • As H+ ions pass through the enzyme, it catalyses the synthesis of ATP from ADP and Pi

  21. And finally ….. • The passage of a pair of electrons from one reduced NAD molecule along the ETC provides enough energy to move sufficient hydrogen ions to produce 3 molecules of ATP • As the first electron carrier is FAD, the passage of electrons from reduced FAD results in the production of only 2 ATP molecules • The final carrier in the chain transfers the electrons to 2 oxygen atoms. Each of these oxygen atoms picks up two protons (H+ ions) to produce a molecule of water 2e- + 2H+ + O —> 2H2O • The enzyme cytochrome oxidase catalyses this last reaction involving oxidation by oxygen; it is inhibited by the poison cyanide

  22. How much ATP is produced? • Calculate the number of ATPs produced by these processes: • a) Substrate level phosphorylation • glycolysis = • Krebs Cycle = • b) Oxidative phosphorylation • re-oxidation of 10 NADH along ETC @ 3ATPs a go • re-oxidation of 2 FADH2 along ETC @ 2ATPs a go • Total 2 2 30 4 38

  23. Electron Transport Chain • Read and make additional notes from • Rowland pages 127 - 128 • Collins page 14 • Roberts pages 103 - 104

More Related