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AP Biology 2006-2007
-Cellular Respiration-Breaking the bonds of sugar
to produce ATP
ATP
AP Biology
Cellular Respiration – makes ATP by breaking down sugars and other carbon-based molecules.
3 metabolic stages Anaerobic respiration
1. Glycolysis - “Glucose Breaking” Anaerobic respiration -respiration without O2
Located in the cytoplasm Produces a net of 2 ATP molecules/glucose
Aerobic respiration phase – respiration with O2
2. Krebs cycle Located in the mitochondria matrix Produces 2 ATP/glucose 3. Electron transport chain Located in the mitochondrial inner membrane Produces 32-34 ATP/glucose
AP Biology
2 2 32-34
C6H12O6 6O2 36-38 ATP6H2O6CO2+ + +
AP Biology
Mitochondria — Structure
intermembranespace inner
membrane
outermembrane
matrix
cristae
Double membraned energy harvesting organelle highly folded inner membrane increases surface area
Cristae Matrix
inner fluid-filled space enzymes
Found free in matrix & as well as membrane-bound
What cells would have a lot of mitochondria?
AP Biology
Glycolysis –anaerobic respiration occurs in cytoplasm Sugar is broken into two pyruvic acid molecules and
releases 2 molecules of ATP/Glucose
Net gain of 2 ATP produced for every glucose
2x6C 3Cglucose pyruvate
AP Biology
ATP2
ADP2
ATP4
ADP4
NAD+2
2Pi
2
-2 ATPs release energy-Phosphate is added to another compound.
-An electron moving down membranes, eventually bonding with NAD+.This gain of electrons attracts hydrogen ions, which bonds to NAD+, storing energy in the bonds of NADH
-ADP gains the third phosphate, forming ATP. Energy is stored in the phosphate bonds.
AP Biology
Step 1. Two ATP molecules are used to energize a glucose molecule. The glucose molecule is split into two three-carbon molecules.
P PP
PP
2
2
PP
PP
C C C C C C
P PP
P P
C C C C C C PP
C C CP C C C P
C C C PC C CP
AP Biology
Step 2. Energized electrons and hydrogen ions from the three-carbon molecules are transferred to molecules of NAD+, becoming NADH. A series of reactions converts the 3-carbon molecules to Acetyl Co-A which enters cellular respiration
P PP
P
PP
2
2
PP PP
P PP
PP2
2 P PP
PP2
2
NAD+2
2
NAD+2
2
AP Biology
Glycolysis- The Song!
http://www.youtube.com/watch?v=jJvAL-iiLnQ
AP Biology
If No Oxygen is present the pyruvate cannot enter the Kreb Cycle and goes into Fermentation instead.
AP Biology
2 Types of Fermentation A. Alcoholic Fermentation – occurs in Plants & Bacteria Produces NAD+, 2 ATP, and ethanol. Used in the production of wines, cheeses, breads.
AP Biology
B. Lactic Acid Fermentation – In Animals Produces NAD+ and Lactic acid
Causes pain in the joints.
AP Biology
IV. STAGE 2: KREBS CYCLE – AEROBIC RESPIRATION
a. Occurs in the mitochondrial matrixb. A process that breaks pyruvate through a series of reactions
producing Electron Carrier compounds, ATP and carbon dioxide gas.
c. Produces large quantities of electron carriers like NADH, and FADH2 that go to the Electron Transport Chain.
Step 1. Pyruvate (from glycolysis) is broken down (loses a carbon).
Step 2 Coenzyme A (CoA) bonds to the two-carbon molecule. This intermediate molecule (Acetyl-CoA) enter the Krebs cycle.
AP Biology
C C C
Wheredoes the
Carbon go?Exhale!+ Coenzyme A (CoA)
3C
Oxidation of Pyruvate
NAD+
e- & H+
Acetyl Group
C C
Acetyl-CoA C C
To the KrebsCycle!
Loss of CO2
C
Remember, this happens twice,once for each
Pyruvate!
2= 2 CO2
= 2 NADH = 2 Acetyl CoA
AP Biology
Step 3 Citric Acid is formed by bonding acetyl-coA to a four carbon molecule.
Step 4: Citric acid is broken down by releasing a carbon, and a five-carbon molecule is made.
Step 5. The five-carbon molecule is broken down. A four-carbon molecule is made.
Step 6. The four-carbon molecule is rearranged. 2 ATPs are formed.
Products from breakdown of one molecule of pyruvate:•CO2 given off as a waste product each time a carbon is broken off.•2 ATP•4 NADH goes to ETC•1 FADH2 goes to ETC
AP Biology
4C
6C
4C
4C
4C
2C
6C
5C
4C
CO2
CO2
citrate
acetyl CoA
Now for the Krebs Cycle-count the carbons!
3Cpyruvate
x2
oxidationof sugars
This happens twice. One for each pyruvate molecule.
CO 2
AP Biology
4C
6C
4C
4C
4C
2C
6C
5C
4C
CO2
CO2
citrate
acetyl CoA
Now, count the electron carriers!
3Cpyruvate
Storing energyusing electron
carriers
This happens twice for each pyruvatemolecule x2
CO 2
NADH
NADH
NADH
NADH
ATP
FADH22
AP Biology
AP Biology
So we fully oxidized glucose
C6H12O6
6CO2
& ended up with all of 4 ATP!2 from Glycolysis
2 from Krebs Cycle
Whassup with this?
What’s the point?
AP Biology
What’s so important about
electron carriers?
H+
H+
H+
H+
H+H+
H+H+
H+
ATP
ADP+ Pi
Krebs cycle produces large quantities of
electron carriers 8 NADH 2 FADH2
go to Electron Transport Chain!
AP Biology
STAGE 3: Electron Transport Chain
Takes place in the inner mitochondrial membrane A process that uses high electron carriers from the Krebs
cycle to generate ATP by oxidative phosphorylation. Produces 32-34 ATP molecules per molecule of glucose.
Step 1. H+ and e- are removed from NADH and FADH2.
Step 2. Hydrogen ions are transported across the membrane.
Step 3. ADP is changed into ATP when hydrogen ions flow through ATP Synthase.
Step 4. Water is formed when oxygen picks up electrons and hydrogen ions.
AP Biology
AP Biology
Mitochondria
intermembranespace
innermembrane
outermembrane
matrixcristae
H+
H+H+
H+
H+ H+
H+H+
H+
NAD+
Q
C
NADH H2O
H+
e–
2H+ + O2
H+H+
e–FADH2
12
NADH dehydrogenase
cytochrome bc complex
cytochrome coxidase complex
FAD
e–
ADP+ Pi
TA-DA!!Moving electrons
do the work!
H+ H+ H+
P
H+
O-
O-O-
H+
ATP
H+
P PP PP P P H+
H+ O-H+H+H+
AP Biology H+
H+H+
H+
H+ H+
H+H+
H+
NAD+
Q
C
NADH H2O
H+
e–
2H+ + O2
H+H+
e–FADH2
12
NADH dehydrogenase
cytochrome bc complex
cytochrome coxidase complex
FAD
e–
ADP+ Pi
TA-DA!!Moving electrons
do the work!
H+ H+ H+
Chemiosmosis powers the proton pump!
P
H+
O-
O-O-
H+
ATP
H+
P PP PP P P H+
H+ O-H+H+H+
The diffusion of ions across a membrane build up of proton gradient just so H+ could flow
through ATP synthase enzyme to build ATP The final electron acceptor is oxygen, which forms
water.
AP Biology
. SUMMARY - The products of cellular respiration – including glycolysis
are:
CO2 from the Kreb’s Cycle and from the breakdown of pyruvate before the Krebs cycleWater from the Electron Transport ChainA net gain of up to 36-38 ATP molecules for every glucose molecule – 2 ATP from glycolysis, 2 ATP from the Krebs cycle, and up to 32-34 ATP from the electron transport chain.
C6H12O6 6O2 36-38 ATP6H2O6CO2+ + +
Kreb’s Cycle
Electron Transport Chain
AP Biology
AP Biology
A single cell uses about 10 million ATP molecules per
second!
If you are chasing prey for food, or being chased by a predator,
it is probably higher…
http://www.hyperbaric-oxygen-info.com/aerobic-cellular-respiration.html
AP Biology
ETC backs up nothing to pull electrons down chain NADH & FADH2 can’t unload H
ATP production ceases cells run out of energy and you die!
Taking it beyond… What is the final electron
acceptor in Electron Transport Chain?
O2
So what happens if O2 unavailable?
NAD+
Q
C
NADH H2O
H+
e–
2H+ + O2
H+H+
e–FADH2
12
NADH dehydrogenase
cytochrome bc complex
cytochrome coxidase complex
FAD
e–
AP Biology
http://www.youtube.com/watch?v=StXlo1W3Gvg&feature=related
What happens when you run out of Oxygen!
A single cell uses about 10 million ATP molecules per second –
http://www.hyperbaric-oxygen-info.com/aerobic-cellular-respiration.html
