1. Energy in Living Organisms: Cellular Respiration

2. Review: Autotrophs Autotrophs get their energy from the sun.
Convert light energy into stored chemical energy (glucose) via photosynthesis.

3. Review: Heterotrophs
Heterotrophs get their energy from the autotrophs.
Convert stored chemical energy (glucose) into usable chemical energy (ATP).
This process is called cellular respiration.

4. Cellular Respiration (aerobic)
Process by which glucose (C6H12O6) is broken down to release energy for making ATP, another form of chemical energy.

5. What is ATP?
Energy used by all cells!
Adenosine Triphosphate
Organic molecule containing high-energy Phosphate bonds

6. How does ATP supply us with energy?
By breaking the high- energy bonds between the last two phosphates in ATP!
Think of a piggy bank...

7. How?
Hydrolysis! (adding H2O)

8. Aerobic Respiration – Equation
C6H12O6 + 6 O H2O + 6 CO ATP
food
(glucose, a carbohydrate)
oxygen
water
carbon
dioxide

9. A Huge Theme in Biology… Interdependence!
Photosynthesis:
6 H2O + 6 CO2 + energy (sun) → C6H12O6 + 6 O2
Aerobic Cellular Respiration:
C6H12O6 + 6 O2 → 6 H2O + 6 CO2 + energy (ATP)
Any Observations?

10. Why ATP? An analogy to money…
Glucose in our food is a great source of energy! ($100 bill)
However, individual cell processes may only require a small amount of energy ($1 bill)
Analogy: most vending machines do not accept $100 bills! We need a smaller form of “currency” for these processes.
ATP (adenosine triphosphate) is this important cellular “currency” for life.
ATP releases more appropriate amounts of energy for the individual cellular processes that require energy.

11. Do only animals respire? Or do plants respire too?
The BIG Question is…
Do only animals respire?
Or do plants respire too?
Only plants perform photosynthesis
Plants AND animals perform cellular respiration!
(Can you explain why??)

12. Steps of Cell Respiration
Stage
Occurs in the…
Glycolysis
Cytoplasm
Krebs Cycle
Matrix of mitochondria
Electron Transport Chain
Mitochondrial membrane

13. Glycolysis
BIG IDEA: Splits glucose into 2 three-carbon molecules called pyruvate!
Anaerobic – doesn’t require oxygen!
Releases CO2
Net production of 2 ATP
Takes 2 ATP to get started, produces 4 ATP  overall gain of 2 ATP!

14. Summary: Produces 2 ATP, NADH & FADH2, CO2
Krebs Cycle
Aerobic – requires oxygen!
Produces 2 ATP
Summary: Produces 2 ATP, NADH & FADH2, CO2

15. The Electron Transport Chain
32-34 ATP are produced!
Aerobic – requires oxygen
H2O is also produced

16. Significant ATP Production
Aerobic cellular respiration releases energy SLOWLY, using oxygen to convert ONE molecule of glucose to 36 ATP!
It’s a good thing too! Each cell uses 1-2 BILLION ATP per minute!

17. But… What happens when cells don’t have enough oxygen?
Some organisms live in an oxygen-free environment. How do they get their energy?

18. Cellular Respiration (anaerobic)
Anaerobic respiration is also called fermentation  the process by which energy is released from glucose when oxygen is NOT available.
Allows organisms to continue to produce energy until oxygen is available.
However, this process only releases 2 ATP per molecule of glucose.

19. Fermentation
Anaerobic way of converting energy for yeast and other microorganisms
Glucose broken down to produce alcohol, CO2 and energy (ATP)
C6H12O6  ethanol + CO2 + 2 ATP
EX: baking bread with yeast

20. Fermentation - Bread Source of sugar? DOUGH! (sugar and/or flour)
Yeast use up the O2 and ferment sugar
Produce CO2, which is trapped within
tiny bubbles & results in the dough rising
Produce ethanol, which evaporates in the baking process

21. Lactic Acid Fermentation
Anaerobic way of converting energy in animal cells and some microorganisms
Glucose broken down to produce lactic acid, CO2 and energy (ATP)
C6H12O6  lactic acid + CO2 + 2 ATP
EX: muscle cells during strenuous exercise (causes the “burn”) fermenting cheese, yogurt, sour cream

22. Comparing ATP Production
First, your body breaks down glucose through aerobic respiration to produce 36 ATP per glucose molecule; however, this is a slow process.
When muscle cells cannot get enough O2 they break down glucose through lactic acid fermentation to produce 2 ATP per glucose…
Therefore, AEROBIC RESPIRATION is much more efficient in terms of ATP production – ATP compared to 2 ATP!

23. Aerobic Training Ex: long runs, biking, swimming
Can increase the size and number of mitochondria in muscle cells
Can increase the delivery of O2 to muscles by improving the heart and lungs

24. Anaerobic Training Ex: sprints, strides, quick bursts of energy
Increase the glycogen levels in the muscles
Increase body’s tolerance to lactic acid