How Cells Harvest Chemical Energy

1. How Cells Harvest Chemical Energy

2. ATP Is Universal Energy Source • Photosynthesizers get energy from the sun • Consumers get energy from plants or other organisms • ENERGY is ALWAYS converted to the chemical bond energy of ATP • Photosynthesis and Respiration are LINKED

3. Photosynthesis • Overall reaction: 6 CO2 + 12 H2O  C6 H12O6 + 6 O2 + 6 H2O Often shown as 6 CO2 + 6 H2O  C6 H12O6 + 6 O2

4. Photosynthesis Overview Sunlight 12 H2O 6 CO2 ATP ADP + P Light Dependent Reactions Light-Independent Reactions NADPH NADP+ 6 O2 Glucose-P + 6 H2O Reactions occur in grana of the thylakoid membrane system Reactions occur in stroma

5. Overview of Cellular Respiration • Glucose + 6 O2  6 CO2 + 6 H2O The overall reaction is exergonic. The energy given off is used to make ATP. 30 - 32 ATP

6. Breathing O2 CO2 Lungs Bloodstream O2 CO2 Muscle cells carrying out Cellular Respiration Glucose  6 O2 6 CO2 6 H2O  30-32 ATP • Breathing and cellular respiration are closely related:

7. Cellular Respiration and ATP • Cellular respiration releases the energy stored in glucose in a series of steps • The energy released is stored as ATP and released as heat • Aerobic respiration is ~34% efficient • Meaning… 34% of the energy stored in the glucose is captured and stored as ATP

8. How Cells Make ATP • ATP is made in two ways during cellular respiration: • Substrate level phosphorylation • Glycolysis • Citric acid cycle (Krebs cycle) • Oxidative phosphorylation • Electrons transport system and chemiosmosis

9. Substrate-level phosphorylation ENZYME ATP is made in an enzyme in a coupled reaction. Substrate gives energy and phosphate group (Pi) to ADP and makes ATP. Substrate Product Fig. 9.7

10. Oxidative phosphorylation • Electron carriers (NADH and FADH2) deliver electrons to the Electron Transport Chain (ETC) on the inner membrane of the mitochondria • Electrons are passed from membrane protein to protein. • Each transfer releases energy and pumps H+ out of the matrix • Energy is used to create a chemical gradient • Gradient is used to drive ATP synthesis by the enzyme ATP synthase

11. Overview of Cellular Respiration

12. Carbohydrate Metabolism • The first pathway of carbohydrate metabolism is called glycolysis. • Glucose is the starting material for glycolysis. • Glycolysis reactions occur in the cytoplasm.

13. Glycolysis • Step #1: Glucose is converted to glucose-6-phosphate in a phosphorylation reaction • Reaction is endergonic • Reaction requires an input of ATP • Step #2: A rearrangement reaction occurs to make fructose-6-phosphate

14. Glycolysis • Step #3: Another phosphorylation reaction occurs to made fructose-1,6-diphosphate • Reaction is endergonic • Reaction requires an input of ATP • Step #4: Fructose-1,6-diphosphate is broken in to 2 three carbon compounds

15. Glycolysis • 5 more steps occur and 2 pyruvate are made • These steps release energy and electrons. • Energy released is used to make ATP by substrate level phosphorylation • Electrons are attached to the electron carrier NAD+ to form 2 NADH • The NADH deliver electrons and H+ to the electron transport system

16. More on NADH • Synthesis of NADH (simplified version): NAD+ + 2 e + H+ NADH • Is NAD+ oxidized or reduced in this reaction?

17. Glycolysis Energy requiring steps: 2 ATP invested Energy releasing steps: 2 NADH formed 4 ATP formed Net yield is 2 ATP and 2 NADH Does NOT require O2 Occurs in the cytoplasm

18. Glycolysis Summary • Where it occurs: • First substrate: (starting “material”) • End product: • Also made: • net gain of ____ ATP (why net?, how made?) • _____ NADH (made from?)

19. Glycolysis Summary Where it occurs: Cytoplasm First Substrate:Glucose (6C) End product:2 Pyruvate (3C)

20. Glycolysis Summary Also made • net gain of 2 ATP made by substrate-level phosphorylation • Pathway requires an input of 2 ATP to start and makes a total of 4 ATP • 2 NADH – each made from NAD+ ,2e and H+

21. Energy Releasing Pathways • What happens to the products of glycolysis depends upon cell conditions.  Aerobic conditions • Preparatory step and Citric Acid/Krebs cycle • Electron transport chain Anaerobic conditions • Fermentation

22. GLYCOLYSIS OR ANAEROBIC Conditions No oxygen present Net gain of 2 ATP AEROBIC RESPIRATION Oxygen present Net gain of 30-32 ATP

23. GLYCOLYSIS OR • AEROBIC • RESPIRATION • Preparatory step • Krebs Cycle • Electron Transport Chain • Reactions occur in mitochondria • ANAEROBIC • Fermentation occurs • Type depends upon cell type • Reactions occur in cytoplasm

24. Pathways ofAerobic Respiration • Glycolysis followed by Pyruvate oxidation • Citric Acid cycle • Also called Krebs Cycle • Electron Transport Chain (ETC) and Chemiosmosis

25. Aerobic Conditions • The first reaction that occurs after glycolysis is pyruvate oxidation • Also called the Preparatory Step • This reaction occurs as the pyruvate enter the matrix of the mitochondria

26. Pyruvate Oxidation • As the pyruvate enter the mitochondria each has a carbon removed and co-enzyme A added • Produced in the Prep. Step • 2 NADH (go to ETC) • 2 CO2 (diffuse out of mitochondria and cell)

27. Cytoplasm Pyruvate Oxidation ------------------------------ ------------------------------ Matrix of the mitochondria

28. Aerobic Respiration • For each glucose metabolized the Preparatory Step makes • 2 NADH - go to ETC • 2 CO2 - diffuse out of mitochondria and cell • 2 Acetyl Co-A - enter into Citric acid cycle *aka – Krebs cycle

29. Pyruvate Oxidation Summary • Where and when it occurs: • Substrate: • End Product: • Also made: • ___________ • ___________

30. Pyruvate Oxidation Summary Where and when it occurs: Occurs as pyruvate enter mitochondria, occurs under aerobic conditions Substrate: 2 Pyruvate (3C) End Product: 2 Acetyl-CoA (2C) Also made: • 2 CO2 • 2 NADH

31. Citric Acid Cycle = Krebs Cycle • Step 1: Each Acetyl-CoA (2C) joins with an oxaloacetate (4C) to form a citrate (6C) • Rest of the citric acid cycle reactions occur • Last reaction produces another oxaloacetate (4C) which joins with the next available acetyl-co A……. • ATP, NADH, FADH2, and CO2 are made in these reactions….see board

32. CoA Acetyl CoA CoA 2 carbons enter cycle Oxaloacetate Citrate +H+ NADH leaves cycle CO2 NAD+ CITRIC ACID CYCLE NAD+ Malate + H+ NADH + ADP P FADH2 ATP Alpha-ketoglutarate FAD leaves cycle CO2 Succinate NAD+ +H+ NADH

34. In the Krebs cycle, the metabolism of 2 pyruvates made from a single glucose produces: • 2 ATP - by substrate-level phosphorylation • 6 NADH - go to ETC • 2 FADH2- go to ETC • 4 CO2- diffuse out of mitochondria and cell

35. Citric Acid Cycle Summary • Where it occurs: • Starting substrates: • Last product of pathway: • Also made (in total for 2 acetyl-CoA entering) ____ CO2 ____ ATP (method made by?) ____ NADH ____ FADH2

36. Citric Acid Cycle Summary • Where it occurs: matrix of mitochondria • Starting substrates: acetyl-CoA, oxaloacetate • Last product of pathway: oxaloacetate • Also made (in total for 2 acetyl-CoA) 4 CO2 2 ATP (by substrate level phophorylation) 6 NADH 2 FADH2

37. Electron Transport Chain(ETC) • ETC occurs at electron carriers (proteins) located on the inner membrane of the mitochondria • Electrons from NADH and FADH2 are passed from one electron carrier to the next. • Transfers are called red-ox reactions • Each transfer releases energy

38. ETC • Some of the electron carriers are also proton (H+) pumps • Use the energy released by the red-ox reactions (e transfer reactions) to pump H+ out of the matrix.

39. H+ H+ H+ H+ H+ Protein complex H+ H+ Electron carrier ATP synthase H+ H+ Intermembrane space Inner mitochondrial membrane FADH2 FAD Electron flow 1 2 O2 + 2 NADH NAD+ H+ H+ Mitochondrial matrix H+ P ADP + ATP H+ H2O H+ Chemiosmosis Electron Transport Chain

40. ETC • NADH and FADH2 each transfer2e and H+ to a specific ETS protein • Notice -- they do NOT start with the same ETC protein • In the process are the NADH and FADH2 oxidized or reduced?

41. H+ H+ H+ H+ H+ Protein complex H+ H+ Electron carrier ATP synthase H+ H+ Intermembrane space Inner mitochondrial membrane FADH2 FAD Electron flow 1 2 O2 + 2 H+ NADH NAD+ H+ H+ P ADP + ATP H+ H2O Mitochondrial matrix H+ Chemiosmosis Electron Transport Chain

42. ETC • H+ from the matrixfollow the electrons into proton pumps • At each proton pump the H+ are pumped out of the matrix into the intermembrane space • This creates an electrical & chemical gradient • Form of _________ energy

43. ETC • Electron transfers stop when the last ETC protein transfers the 2e to oxygen which: • Joins with H+ to form water • The last electron acceptor is oxygen and water forms. (know this)

44. Chemiosmosis and ATP Synthesis • ….back to the H+ ions pumped into the intermembrane space • The potential energy of H+ gradient is drive ATP synthesis at the enzyme ATP synthase

45. ETC and ATP Synthesis • The enzyme ATP synthase is embedded in the inner membrane of the mitochondria • The flow of H+ through this enzyme releases energy and this energy is used to make ATP .

46. Chemiosmosis and ATP Synthesis • This method of making ATP is called • Oxidative phosphorylation • Also referred to as chemiosmosis

47. Chemiosmosis and ATP Synthesis • The more H+ pumped out of the matrix • The steeper the gradient • the more potential energy • the more ATP that can be made by ATP synthase

48. ETC and ATP Synthesis • Each NADH made in the mitochondria results in enough H+ being pumped out of the matrix to make 2.5 ATP. • Each FADH2 results in enough H+ being pumped out of the matrix to make 1.5 ATP.

49. NADH from Glycolysis • The NADH made in glycolysis must enter the matrix in order to deliver their electrons to the ETC • How they “enter” the mitochondria depends upon the cell type.

50. NADH from Glycolysis • In most cells the 2 NADH made in glycolysis pass their electrons and H+ to FADin the matrix making: • 2 FADH2 -- take the electrons and H+ to the ETC where a total of ____ ATP are made