1. 1 CHAPTER 9 CELLULAR RESPIRATION: HARVESTING CHEMICAL ENERGY Section B: The Process of Cellular Respiration

2. 2 3- Electron transport chain: The inner mitochondrial membrane الغشاء الداخلي للميتوكوندريا uses يستخدم electron transport سلسلة نقل الاليكترونات to ATP synthesis (90% of ATP) Electrons drop in free energy as they pass down the electron transport chain.Electrons drop in free energy as they pass down the electron transport chain. أي ان الطاقة المخزنة في الاليكترونات تفقد حينما تمر في سلسلة نقل الاليكتروناتأي ان الطاقة المخزنة في الاليكترونات تفقد حينما تمر في سلسلة نقل الاليكترونات Only 4 of 38 ATP produced by تنتج respiration of glucose ( 2 from glycolysis and 2 from Krebs Cycle ).Only 4 of 38 ATP produced by تنتج respiration of glucose ( 2 from glycolysis and 2 from Krebs Cycle ). The vast majority الباقيof the ATP (90%) comes from the energy in the electrons carried by NADH and FADH 2.The vast majority الباقيof the ATP (90%) comes from the energy in the electrons carried by NADH and FADH 2. The energy in these electrons is used in the electron transport chain سلسلة نقل الاليكترونات to power لتدعم ATP synthesis.The energy in these electrons is used in the electron transport chain سلسلة نقل الاليكترونات to power لتدعم ATP synthesis.

3. 3 Fig. 9.13 NADHFADH 2Electrons from NADH or FADH 2 finally pass to oxygen. ملخص هذا الجزء الاليكترونات المحمولة في مركبات الناد والفاد تنتقل عبر سلسلة من المركبات في الميتوكوندريا وعند الانتقال من مركب لاخر تفقد جزء من الطاقة حتي ينتهي بها الحال الي الاكسجين بعد ان تكون قد فقدت الطاقة التي تملكها Electrons carried by NADH are transferred to the first molecule in the electron transport chain ().Electrons carried by NADH are transferred to the first molecule in the electron transport chain (the flavoprotein; FMN). The electrons continue along the chain which includes several Cytochrome proteins and one lipid carrier.The electrons continue along the chain which includes several Cytochrome proteins and one lipid carrier. The electrons carried by FADH 2 have lower free energy and are added to a later point in the chain.The electrons carried by FADH 2 have lower free energy and are added to a later point in the chain.

4. 4 Chemiosmosis: (osmos = puch)Chemiosmosis: (osmos = puch) is the oxidative phosphorelation that results in ATP production in the inner membrane of mitochondria. is the oxidative phosphorelation that results in ATP production in the inner membrane of mitochondria. Fig. 9.14 The ATP synthase molecules are the only place that will allow H + to diffuse back to the matrixThe ATP synthase molecules are the only place that will allow H + to diffuse back to the matrix. This flow of H + is used by the enzyme to generate ATP a process called chemiosmosis.This flow of H + is used by the enzyme to generate ATP a process called chemiosmosis. ATP-synthase, in the cristae actually makes ATP from ADP and P i.ATP-synthase, in the cristae actually makes ATP from ADP and P i. ATP used the energy of an existing proton gradient to power ATP synthesis.ATP used the energy of an existing proton gradient to power ATP synthesis. –This proton gradient develops between the intermembrane space and the matrix. –This concentration of H + is the proton-motive force.

5. 5 Fig. 9.15, Page 168 Energy of NADH and FADH 2 give a maximum yield of 34 ATP is produced by oxidative phosphorylation.

6. 6 During respiration, most energy flows from glucose -> NADH -> electron transport chain -> proton-motive force -> ATP.During respiration, most energy flows from glucose -> NADH -> electron transport chain -> proton-motive force -> ATP. One six-carbon glucose molecule is oxidized to 6 CO 2 molecules.One six-carbon glucose molecule is oxidized to 6 CO 2 molecules. Some ATP is produced by substrate-level phosphorylation during glycolysis and the Krebs cycle, but most ATP comes from oxidative phosphorylation (through electron transport chain).Some ATP is produced by substrate-level phosphorylation during glycolysis and the Krebs cycle, but most ATP comes from oxidative phosphorylation (through electron transport chain). Each NADH from the Krebs cycle and the conversion of pyruvate contributes enough energy to generate a maximum of 3 ATP.Each NADH from the Krebs cycle and the conversion of pyruvate contributes enough energy to generate a maximum of 3 ATP. Each FADH 2 from the Krebs cycle can be used to generate about 2ATP.Each FADH 2 from the Krebs cycle can be used to generate about 2ATP. Energy produced in electron transport chain gives a maximum yield of 34 ATP by oxidative phosphorylation via ATP-synthase.Energy produced in electron transport chain gives a maximum yield of 34 ATP by oxidative phosphorylation via ATP-synthase. Cellular respiration generates many ATP molecules for each sugar molecule it oxidizes

7. 7 Plus the 4 ATP from substrate-level phosphorylation ( glycolysis & Krebs Cycle. ) gives a bottom line of 38 ATP.Plus the 4 ATP from substrate-level phosphorylation ( glycolysis & Krebs Cycle. ) gives a bottom line of 38 ATP..

8. 8 Fig. 9.16, Page 169 Summary of cell respiration

9. 9 Proteins and fats, can also enter the respiratory pathways, including glycolysis and the Krebs cycle, like carbohydrates. Fig. 9.19, Page 172