1. Ch. 7.4: Cellular Respiration
Vocabulary
Aerobic Electron transport chain
Objectives:
Relate breathing and cellular respiration.
Summarize the cellular respiration equation.
Tell how “falling” electrons are a source of energy.
Explain the role of electron transport chains.

2. Ch. 7.4: Breathing & Respiration
Cellular respiration converts the energy stored in food to energy stored in ATP.
Physical processes of moving O2 & CO2
Chemical rxn involving the oxidation of glucose to H2O& CO2
Gases exchanged b/w blood & outside air via lungs.
Gases exchanged b/w cells & surroundings (blood or lymph)

3. Ch. 7.4: Cellular Respiration Equation
Respiration occurs in a SERIES of reactions (not 1 rxn).
Goal: Generate ATP for cellular work.

4. 7.4: Where does energy for ATP come from?
Moving to an outer energy level is like climbing uphill … it costs energy.
Moving to a lower energy level is like moving downhill.
Falling Electrons = Energy Source for ATP
“Falling Electrons” release energy; Excited --> ground state
Why?: Negative electrons are attracted to positive nucleus. Moving farther fr. nucleus requires energy; falling to nucleus releases energy.

5. 7.4: Reacting with Oxygen; Oxidation
Oxygen is an excellent “electron-grabber”; electrons are pulled to O (electro-negative).
(O is much better than N or attracting electrons)
In respiration, C-H bonds of glucose are re-arranged into C-O and H-O bonds of carbon dioxide and water. These bonds store less energy. The energy difference is stored in ATP.
Respiration
Oxidation
+ ATP ENERGY
If glucose is BURNED in a combustion rxn; energy is released as heat and light all at once.

6. 7.4: Electron Transport Chains (E.T.C.)
Energy from glucose is released in small steps.
Electrons from glucose are passed from one molecule to another in an E.T.C.
Each transfer releases energy to make ATP. Electrons are “falling downhill”.
O2 is ultimate end of ETC. O2 grabs electrons and combines w/ H+ions to form H2O.

7. 7.5: Making ATP Vocab: Metabolism Krebs Cycle Glycolysis ATP synthase
Objectives:
Describe the structure of the mitochondrion.
Summarize the 3 stages of cellular respiration and identify where ATP is made.

8. 7.5: Mitochondia Found in almost all eukaryotic cells.
2 membranes (inner & outer)
Inner membrane - highly folded w/ enzymes (ATP synthase) built in.
Thick fluid in matrix.
Structure & Function go together: Folds of inner membrane increases surface area for enzymes and sites for reactions … MORE ATP gets made (more surface area = more ATP synthase)!

9. 7.5: Steps of Cellular Respiration
Metabolism: all of a cell’s combined chemical reactions.
Respiration is a series of rxns … a metabolic pathway.

10. Step 1: Glycolysis
Break down glucose molecule into (2) 3 carbon-molecules called PYRUVATES.
Outside mitochondria, in cytoplasm (cystol)
Requires 2 ATPs to break glucose; Electrons & H+ ions transfer to NAD --> NADH and make 4 ATP
Summary: Glucose breaks down into 2 Pyruvates (3 C) and 2 ATPs!

11. 7.5: Step 2: Krebs Cycle
Pyruvic acid (3C) --> Acetyl CoA (2C) --> CO2; Energy Released and stored in ATP, NADH, and FADH2 (Electron acceptors)
Where: Enzymes in fluid matrix inside inner membrane.
Summary: 2 Pyruvate (3C) break down to CO2 & 2ATP, NADH, FADH2

12. 7.5: Step 3: Electron Transport Chain and ATP Synthase Action
Electrons (fr. Glucose) carried by NADH move thru. E.T.C. (getting pulled by stronger electron-attractor molecules)
Oxygen grabs end; combines w/ H+ to make H2O.
Energy from ETC used to PUMP H+ (fr. NADH) across membrane AGAINST GRADIENT. H+ ions then move down gradient thru. channel proteins called ATP synthase.
ATP synthase: enzyme that catazlyzes ADP + P --> ATP

13. Electron Transport Chain & ATP Synthase
Summary: Use moving electrons to make ATP!
Makes BULK of ATP (~34 ATP)

14. 7.5: Cellular Respiration
Energy stored in bonds of glucose --> ~ 38 ATP molecules
Most ATP production occurs after glycolysis and REQUIRES OXYGEN.

15. 7.5: Cellular Respiration

16. 7.6: Anaerobic Respiration (Fermentation)
Vocab.:
Fermentation Anaerobic
Objectives:
Explain how fermentation in muscle cells is different from cellular respiration.
Give examples of products that depend on fermentation in microorganisms.

17. 7.6: Fermentation What: Making ATP w/out O2 (using glycolysis)
Context: Working muscles need an ongoing ATP supply; faster than O2 can be supplied for respiration.
Yield: 2 ATPs for each glucose (but regular respiration is same time too).
Waste Product: Lactic Acid
2 Lactic acid

18. 7.6: Fermentation in Humans
After rigorous exercise, fermentation leads to a build up of lactic acid --> MUSCLE FATIGUE & SORENESS As your body converts lactic acid --> pyruvic acid you NEED OXYGEN and breathe heavily.

19. 7.6: Fermentation in Microorganisms
Yeast (fungi) cells can ferment sugar in anaerobic Environments (No O2 ).
Product of yeast fermentation is ETHANOL, an alcohol (not lactic acid) and CO2 .

20. 7.6: Application of Fermentation
Production of:
Breads (CO2 makes break rise)
Alcoholic beverages
Yogurts and cheeses from milk (Fungi & bacteria that make lactic acid)
Soy sauce (fr. Soybeans)
Sauerkraut (fr. Cabbage)