Lecture 6 Outline (Ch. 9, 10) I.Citric Acid Cycle II.Electron transport chain & oxidative...
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Transcript of Lecture 6 Outline (Ch. 9, 10) I.Citric Acid Cycle II.Electron transport chain & oxidative...
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Lecture 6 Outline (Ch. 9, 10)
I. Citric Acid Cycle
II. Electron transport chain & oxidative phosphorylation
III. Anaerobic respiration
IV. Respiration with other molecules
V. Chloroplasts
VI. Light
VI. Summary
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Steps of Respiration
Glucose is OXIDIZED/REDUCED to _____.Oxygen is OXIDIZED/REDUCED to _____.
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Steps of Respiration
• Stages of respiration:
3. Citric acid cycle
Mitochondrial matrix
e- transfer: redox
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Cellular Respiration
3. Citric acid cycle
• 2 Acetyl CoA (2C) join oxaloacetate (4C)
• few ATP so far
• e- to carriers
(NAD+, FAD)
• now in mito. matrix
• 2 citrate (6C) converted several steps, 4C lost (CO2)
• 2 ATP made
Where do the outputs go?
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In thinking about cellular respiration:
a. What is/are the overall function(s) of glycolysis?
b. What is/are the overall function(s) of pyruvate oxidation and the Krebs cycle?
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Steps of Respiration• Stages of respiration:
4. ETC
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Cellular Respiration
• ETC e- collection molecules
• embedded on inner mitochondrial membrane
Electron transport chain (ETC)
• accept e- in turn
• e- ultimately accepted by O2
(O2 reduced to H2O)
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~100 H+ (stored)
10 H2O
-outputs:
ATP (none yet)
Where do outputs go?
Electron transport chain (ETC)
-inputs:per glucose,
10 NADH
2 FADH2
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Cellular Respiration 4. Chemiosmosis
• ATP synthase: inner mitochondrial membrane
• H+ stock-piled in inner membrane space = gradient
• chemiosmosis – ion gradient to do work
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Cellular Respiration
• ATP synthase: enzyme that makes ATP using H+ gradient
3. Chemiosmosis
• H+ must enter matrix here
• Generates 1 ATP per ~3.4 H+
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In thinking about cellular respiration:
a. At what stage(s) in the overall process is each of the
reactants used?
b. At what stage(s) in the overall process is each of the products
produced?
C6H12O6 + O2 CO2 + H2O + Energy
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Cellular RespirationSummary of respiration
KNOW THIS DIAGRAM – EXCELLENT SUMMARY
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Cellular Respiration - anaerobic
• no O2 – no oxidative phosphorylation
• fermentation = extension of glycolysis
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Cellular Respiration - anaerobic
• Types of fermentation -
1. alcohol
• pyruvate converted to acetaldehyde
• acetaldehyde accepts e- to regenerate NAD+
• ethanol produced
• brewing & baking
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Cellular Respiration - anaerobic
• pyruvate accepts e- to regenerate NAD+
• lactate produced
• Types of fermentation -
2. Lactic acid
• muscle fatigue & dairy industry
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Cellular Respiration
• Comparison of aerobic vs. anaerobic respiration:
• ATP per glucose:
Aerobic Anaerobic
• initial e- acceptor:
• final e- acceptor:
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Let’s say it takes 1,000 g of glucose to grow 10 g of yeast anaerobically.
How many grams of glucose would it take (estimate approximately) to grow 10 g of yeast aerobically?
Hint: If it takes X amount of glucose to grow 10 g of yeast without oxygen, what factor would you have to multiply or divide X by to grow 10 g of the same yeast with oxygen?
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Cellular Respiration – other biomolecules
• Glucose catabolism – one option
• Proteins:
• Fats: enter CAC or before
Catabolized into a.a.
Amino group removed (pee out in urine)
• If have more glucose than needed, can run “backward” to store energy as glycogen or fats!
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Self-Check
Step of Respiration
Inputs Outputs CO2/H2O ATP produced
e- carriers loaded
Glycolysis 1 glucose 2 pyruvate None 2 net 2 NADH
Coenzyme Junction
Citric Acid Cycle
Electron Transport Chain
Oxidative phosphorylation & Chemiosmosis
Fermentation
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Photosynthesis - overview
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Overall purpose:
Photosynthesis - overview
• photosynthesis:
light chemical energy
• complements respiration
- light reaction: solar energy harvest
- Calvin cycle: energy to organics
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chloroplast recap
Outer membrane
Inner membrane
Thylakoid membrane
Intermembrane space
Stroma
Thylakoid space
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Photosynthesis - overview
• Photosynthesis -
1. light reaction: store energy & split water
NADPH & ATP given off
Chloroplast model:
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H2O + CO2 + energy C6H12O6 + O2
In photosynthesis,
water is OXIDIZED/REDUCED to _______ and
carbon dioxide is OXIDIZED/REDUCED to ______.
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Redox Reactions
Equation for photosynthesis
CO2 + H2O + light energy C6H12O6 + O2
photo synthesis
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Photosynthesis – light absorption
• visible light ~380 to 750 nm
• chloroplast pigments – absorb blue-violet & red/orange
- transmit and reflect green
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• pigments:
• chlorophyll a
• accessory pigments
-energy-absorbing ring
-hydrocarbon tail
- carotenoids
- photoprotective
Photosynthesis – light absorption
- chlorophyll b
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• chlorophyll a – abs blue-violet, red
~400-450, 650-700
• chlorophyll b & carotenoids – abs broadly blue-violet
450-500 & 600-650
• more wavelengths used for photosynthesis = more light energy absorbed
Photosynthesis – light absorption
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If a car is red, which light wavelengths are reflected (NOT absorbed)?
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Self-Check