Key Themes (2) “Think Like a Biologist”: Understand What Life Is. “Unity” of life: What are common features of eukaryotes? Energy conversions: Sugar breakdown.

Key Themes

(2) “Think Like a Biologist”: Understand What Life Is.“Unity” of life: What are common features of eukaryotes?

Energy conversions: Sugar breakdown & mitochondrial ATP formation

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Lecture 7: Cellular Respiration

Yesterday’s Exit Ticket– Energy-releasing reactions:

• Large, complex smaller, simpler• Release energy and increase entropy

• e.g. ATP ADP and Pi

• e.g. respiration (glucose + O2 H2O + CO2 + ATP)

– Energy-requiring reactions:• Smaller, simpler large complex• Decrease entropy• e.g. ADP + Pi ATP

• e.g. photosynthesis (light E + H2O + CO2 glucose + O2)

Food-to-Energy

Fig. 9.1

Fig. 8.3

Respiration

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Cellular respiration breaks down energy-rich molecules to CO2 & water, extracting their energy.

Fig. 9.2

Lightenergy

ECOSYSTEM

Photosynthesisin chloroplasts

CO2 + H2OCellular respiration

in mitochondria

Organicmolecules+ O2

ATP powers most cellular work

Heatenergy

ATP

High energy

Low energy

C-H bond

“burned” with O2

to H2O + CO2

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Photosynthesis:

Respiration:

ATP

Since ATP is too unstable,

C-H bonds in sugars are used for energy storage.

Converts solar energy

to ATP and uses ATP to make sugars

Converts the energy of sugars back to ATP as needed.

Sugar [CH2O]x + O2CO2 + H20

ATPLight (energy)

H+ & e-

H+ & e-

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What is the goal of cellular respiration?

• Food ATP• Release the energy in C-H bonds• Harness that energy to create ATP

6-C sugar

Glucose + O2

(6-C sugar) ATP + CO2 + H20(energy)

3-C sugars+ some ATP

CO2

+ some ATPH2O + ATP

H+ & e-

O2

H+ & e-

paraibaparadise.com

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What is the goal of cellular respiration?

6-C sugar3-C sugars

+ some ATPCO2

+ some ATPH2O + ATP

H+ & e-

O2

H+ & e-

Step 1: Glycolysis

Step 2: Citric Acid

Cycle

Step 3: Oxidative

Phosphorylation

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Step 1: Glycolysis•Occurs in: cytosol•Starts with: glucose, NAD+, ADP, Pi

•Produces: pyruvate, NADH, and ATP

Glucose (6-C sugar)

Pyruvates(3-C sugars)+ some ATP

H+ & e-

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Cytosol

Fig. 9.6

Glucose Pyruvate

Glycolysis

Electronscarried off by NADH

ATPSome

Step 1: Glycolysis•Occurs in: cytosol•Starts with: glucose, NAD+, ADP, Pi

•Produces: pyruvate, NADH, and ATP

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Pyruvates(3-C sugars)+ some ATP

Glucose (6-C sugar)

Step 1: Glycolysis•Occurs in: cytosol•Starts with: glucose, NAD+, ADP, Pi

•Produces: pyruvate, NADH, and ATP

H+ & e-

NAD+

NADH

Glycolysis can occur with or without O2!!

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Pyruvates(3-C sugars)+ some ATP

CO2

+ some ATPH+ & e-

Step 2: Citric Acid Cycle•Occurs in: mitochondrial matrix (fluid space)•Starts with: pyruvate, NAD+, FAD, ADP, Pi

•Produces: NADH, FADH2, CO2 and ATP

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Fig. 9.6

Mitochondrion

Electrons carried off by

NADH & FADH2

Citricacidcycle

ATP

Glucose Pyruvate

Glycolysis

Electronscarried off by NADH

Some ATPSome

Cytosol

Step 2: Citric Acid Cycle•Occurs in: mitochondrial matrix (fluid space)•Starts with: pyruvate, NAD+, FAD, ADP, Pi

•Produces: NADH, FADH2, CO2 and ATP

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CO2

+ some ATPH+ & e-

Step 2: Citric Acid Cycle•Occurs in: mitochondrial matrix (fluid space)•Starts with: pyruvate, NAD+, FAD, ADP, Pi

•Produces: NADH, FADH2, CO2 and ATP

NAD+

FAD

NADHFADH2

Pyruvates(3-C sugars)+ some ATP

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Step 3: Oxidative Phosphorylation(Using oxygen to phosphorylate ADP)

•Occurs in: mitochondrial inner membranes•Starts with: O2, NADH, FADH2, ADP, Pi

•Produces: H2O, ATP, NAD+, FAD

H2O + ATP

NADH

O2

NADHFADH2

ADPPi

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Electrontransport

andATP synthase

Mitochondrion

ATP

Electrons carried off by

NADH & FADH2

Citricacidcycle

ATP

Glucose Pyruvate

Glycolysis

Electronscarried off by NADH

Fig. 9.6

Some Some ATPLots of

Cytosol

Step 3: Oxidative Phosphorylation(Using oxygen to phosphorylate ADP)

•Occurs in: mitochondrial inner membranes•Starts with: O2, NADH, FADH2, ADP, Pi

•Produces: H2O, ATP, NAD+, FAD

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H (electrons and H+) removed from high energy C-H bonds

CO2

+ some ATPH2O + ATP

H+ & e- (via NADH)

O2

Pyruvates(3-C sugars)+ some ATP

Glucose (6-C sugar)

H+ & e- (via NADH & FADH2)

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I

H - C - OH (CHOH)6 (= C6H12O6 sugar)

I

to

O = C = O CO2

Where does H go?H (electrons and H+) are loaded onto

electron carriers NADH & FADH2

H (electrons and H+) removed from high energy C-H bonds

(all the way to CO2 in the citric acid cycle)

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H (electrons and H+) removed from high energy C-H bonds

CO2

+ some ATPH2O + ATP

H+ & e- (via NADH)

O2

Pyruvates(3-C sugars)+ some ATP

Glucose (6-C sugar)

H+ & e- (via NADH & FADH2)

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ATP

Mitochondrion

ATP

Electrons carried off by

NADH & FADH2

Citricacidcycle

ATP

Cytosol

Glucose Pyruvate

Glycolysis

Electronscarried off by NADH

Fig. 9.6

2 2 ~34

Most ATP is formed by electron transport chainthrough oxidative phosphorylation

Electrontransport

andATP synthase

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Smooth outer membrane

Folded inner membrane:

Matrix:Citric acid cycle

Mitochondria

Electron transport chain & ATP formation

Fig. 6.17

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Fig. 10.16

Potential energy (ion gradient) used for ATP formation

Fig.8.7

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Protein complexof electroncarriers

H+

H+H+

Cyt c

Q

V

FADH2 FAD

NAD+NADH(carrying electronsfrom food)

Electron transport chain & pumping of protons

2 H+ + 1/2O2 H2O

ADP +Pi

H+

H+

ATP synthase

ATP

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The electron transport chain pumps protons against the concentration gradient; builds up a high H+ concentration in intermembrane space.

Intermembranespace

Mitochondrial matrix

Innermembrane

Fig. 9.16

ATP synthesis via H+ flow

Step 3: Oxidative Phosphorylation

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Smooth outer membrane

Folded inner membrane

Intermembrane space

MitochondriaFig. 6.17

Matrix

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Protein complexof electroncarriers

H+

H+H+

Cyt c

Q

V

FADH2 FAD

NAD+NADH(carrying electronsfrom food)

Electron transport chain & pumping of protons

2 H+ + 1/2O2 H2O

ADP +Pi

H+

H+

ATP

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Intermembranespace

Mitochondrial matrix

Innermembrane

Fig. 9.16

ATP synthesis via H+ flow

INTERMEMBRANE SPACE

RotorH+ Stator

Internalrod

Cata-lyticknob

ADP+

P ATPi

MITOCHONDRIAL MATRIX

Fig. 9.14Oxygen (O2) is the final electron (and H+) acceptor

ATP synthase

Protons flow downhill through the ATP synthase, driving phosphorylation of ADP to ATP.

Step 3: Oxidative Phosphorylation

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Let’s take a look at the whole sequence: • Step 1: Glycolysis• Step 2: Citric Acid Cycle • Step 3: Oxidative Phosphorylation

http://www.colorado.edu/ebio/genbio/09_15ElectronTransport_A.html

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Electron Donors and Electron Acceptors

CO2

+ some ATPH2O + ATP

H+ & e- (via NADH)

O2

Pyruvates(3-C sugars)+ some ATP

Glucose (6-C sugar)

H+ & e- (via NADH & FADH2)

Original electron donor in cellular respiration

Electron donors for mitochondrial

electron transport chain

Electron acceptor from mitochondrial

electron transport chain

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ATP links the energy from breakdown of energy-rich food molecules to cellular work

P iADP+

Energy frombreakdown ofenergy-rich molecules

Energy for cellularwork

ATP + H2OEnergy loaded onto

ATPEnergy released from

ATP

Fig. 8.12

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Proteins

Proteins Carbohydrates

Aminoacids

Sugars

Fats

Glycerol Fattyacids

Glycolysis

Glucose

Glyceraldehyde-3-

Pyruvate

P

NH3

Acetyl CoA

Citricacidcycle

Oxidativephosphorylation

Fig. 9.20

The cellular respiration pathway for

Carbohydrates

Fats

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Predict how the enzymes that function early in glycolysis, and start the breakdown of glucose, should be regulated: The enzymes should

A) not be regulated.B) be turned off when enough (ATP) energy is available.C) be turned on when more (ATP) energy is needed.D) be regulated in a dual way, both by activation when more ATP energy is needed and by inactivation when enough ATP energy is available.

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5 min break

www.stthomasblog.com

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Key Themes

Energy conversions: Sugar breakdown without oxygen

via glycolysis + fermentation

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Glucose

Glycolysis

PyruvateCYTOSOL

MITOCHONDRION

Fig. 9.19

• Step 1 of cellular respiration:

Glycolysisoutside

mitochondria

From glucose (6 C) to 2

pyruvate (3 C)Citricacidcycle

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Glucose

Glycolysis

PyruvateCYTOSOL

O2 present:

Aerobic cellular respiration

MITOCHONDRION

Acetyl CoA

Citricacidcycle

Fig. 9.19

•Only when oxygen is present

can glucosebe broken

down completely

in the mitochondria

for high energy yield

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Glucose

Glycolysis

PyruvateCYTOSOL

No O2 present:Fermentation

MITOCHONDRION

Acetyl CoAEthanolor

lactateCitricacidcycle

Fig. 9.19 34

Alcoholic fermentation (forms ethanol plus CO2) by yeasts and bacteria under anaerobic conditions

Glycolysis & fermentation

2 ADP + 2 P i 2 ATP

Glucose Glycolysis

2 Pyruvate

2 NADH2 NAD+

+ 2 H+CO2

2 Acetaldehyde2 Ethanol

(a) Alcohol fermentation

2

Fig. 9.18

The solution when oxygen runs out or is unavailable (anaerobic conditions):

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Glycolysis and fermentation Fermentation to ethanol

2 ADP + 2Pi 2 ATP

Glucose Glycolysis

2 Pyruvate

2 NADH2 NAD+

+ 2 H+CO2

2 Acetaldehyde2 Ethanol(a) Alcohol fermentation

2

Fig. 9.18(a)

Yeasts use alcoholic fermentation to convert hexoses (from sugar cane sucrose or corn starch or

cellulose) into ethanol for fuels

Production of Foods & Fuels

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Alcohol fermentation (forms ethanol plus CO2)• Yeasts & bacteria• Anaerobic conditions

Glycolysis & fermentation

2 ADP + 2 P i 2 ATP

Glucose Glycolysis

2 Pyruvate

2 NADH2 NAD+

+ 2 H+CO2

2 Acetaldehyde2 Ethanol

(a) Alcohol fermentation

2

Fig. 9.18

Do all organisms use alcohol fermentation when oxygen is in

short supply?37

Alcohol fermentation (forms ethanol plus CO2)• Yeasts & bacteria• Anaerobic conditions

Glycolysis & fermentation without oxygen (anaerobic

conditions)

2 ADP + 2 P i 2 ATP

Glucose Glycolysis

2 Pyruvate

2 NADH2 NAD+

+ 2 H+CO2

2 Acetaldehyde2 Ethanol

(a) Alcohol fermentation

2

Glucose

2 ADP + 2 Pi 2 ATP

Glycolysis

2 NAD+ 2 NADH

+ 2 H+

2 Pyruvate

2 Lactate

(b) Lactic acid fermentation

Fig. 9.18

Lactic acid fermentation • Other fungi & bacteria • Also in muscle cells under anaerobic conditions

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Production of Foods and Fuels by Microbes in home & industryYeasts for beer & wine [alcohol fermentation] & for bread leavening [from the CO2 gas formed]; lactic acid bacteria for fermented products from milk or other foods[lactic acid fermentation].

http://www.bact.wisc.edu/themicrobialworld/Effects.html39

Fermentation versus aerobic respiration

Different human muscle fibers use different metabolism (See also Table 49.1):

Glucose

Glycolysis

Pyruvate

CYTOSOL

Fermentation

Aerobic cellular respiration

MITOCHONDRION

Acetyl CoALactate

Citricacidcycle

Fig. 9.1940

Fermentation versus aerobic respiration

Different human muscle fibers use different metabolism (See also Table 49.1):

Glucose

Glycolysis

Pyruvate

CYTOSOL

Fermentation

Aerobic cellular respiration

MITOCHONDRION

Acetyl CoALactate

Citricacidcycle

Fig. 9.19

• Fast-twitch glycolytic fibers (for sprint) use glycolysis - quick, but does not provide much energy.

Glycogen

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Fermentation versus aerobic respiration

Different human muscle fibers use different metabolism (See also Table 49.1):

[Glucose]

Glycolysis

Pyruvate

CYTOSOL

Fermentation

Aerobic cellular respiration

MITOCHONDRION

Acetyl CoALactate

Citricacidcycle

Fig. 9.19

• Fast-twitch glycolytic fibers (for sprint) use glycolysis - quick, but does not provide much energy.

• Slow-twitch oxidative fibers (with many mitochondria for extended exercise) use oxidative respiration -slower, but yields much more energy.

Fats

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Glucose

Glycolysis

PyruvateCYTOSOL

No O2 present:Fermentation

O2 present:

Aerobic cellular respiration

MITOCHONDRION

Acetyl CoAEthanolor

lactateCitricacidcycle

Fig. 9.19

Fermentation in absence

of O2

Aerobic respiration in

presence of O2

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Fig. 9.544

Hank’s Crash Course in Cellular Respiration

3:30-end

http://www.youtube.com/watch?v=00jbG_cfGuQ&feature=relmfu

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Today’s Exit Ticket

Glucose

Process:

Location:

# ATPs:

Process:

Location:Products Released:

Location:Products Released:

# ATPs:

# ATPs:

Process:

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