How Cells Harvest Energy - PowerPoint PPT Presentation

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How Cells Harvest Energy

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How Cells Harvest Energy Chapter 9 Outline Cellular Energy Harvest Cellular Respiration Glycolysis Oxidation of Pyruvate Krebs Cycle Electron Transport Chain – PowerPoint PPT presentation

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Title: How Cells Harvest Energy


1
How Cells Harvest Energy
  • Chapter 9 Outline
  • Cellular Energy Harvest
  • Cellular Respiration
  • Glycolysis
  • Oxidation of Pyruvate
  • Krebs Cycle
  • Electron Transport Chain
  • Catabolism of Protein and Fat
  • Fermentation

2
Cellular Respiration
  • Cells harvest energy by breaking bonds and
    shifting electrons from one molecule to another.
  • aerobic respiration - final electron acceptor is
    oxygen
  • anaerobic respiration - final electron acceptor
    is inorganic molecule other than oxygen
  • fermentation - final electron acceptor is an
    organic molecule

3
ATP
  • Adenosine Triphosphate (ATP) is the energy
    currency of the cell.
  • used to drive movement
  • used to drive endergonic reactions

4
ATP
  • Most of the ATP produced in cells is made by the
    enzyme ATP synthase.
  • Enzyme is embedded in the membrane and provides a
    channel through which protons can cross the
    membrane down their concentration gradient.
  • ATP synthesis is achieved by a rotary motor
    driven by a gradient of protons.

5
NAD NADH
  • Nicotinamide adenine dinucleotide, NAD, is a
    coenzyme found in all living cells.
  • The compound is a dinucleotide, since it consists
    of two nucleotides joined through their phosphate
    groups with one nucleotide containing an
    adenosine ring, and the other containing
    nicotinamide.
  • In metabolism, NAD is involved in redox
    reactions, carrying electrons from one reaction
    to another.
  • The coenzyme is therefore found in two forms in
    cells NAD is an oxidizing agent it accepts
    electrons from other molecules and becomes
    reduced,
  • this reaction forms NADH, which can then be used
    as a reducing agent to donate electrons. These
    electron transfer reactions are the main function
    of NAD.

6
NAD NADH
7
The Cellular isms
  • Metabolism is the set of chemical reactions
    that occur in living organisms in order to
    maintain life.
  • These processes allow organisms to grow and
    reproduce, maintain their structures, and respond
    to their environments.
  • Usually divided into two categories.
  • Catabolism and Anabolism
  • Catabolism breaking down
  • Anabolism building up

8
The Cellular isms
  • Catabolism the set of metabolic pathways which
    break down molecules into smaller units and
    release energy.
  • Large molecules such as polysaccharides, lipids,
    nucleic acids and proteins are broken down into
    smaller units such as monosaccharides, fatty
    acids, nucleotides and amino acids, respectively.
  • These processes produce energy

9
The Cellular isms
  • Anabolism the set of metabolic pathways that
    construct molecules from smaller units.
  • These reactions require energy.
  • Anabolism is powered by catabolism. Many anabolic
    processes are powered by adenosine triphosphate
    (ATP).
  • Anabolic processes tend toward "building up"
    organs and tissues.
  • These processes produce growth and
    differentiation of cells and increase in body
    size, a process that involves synthesis of
    complex molecules.

10
Glucose Catabolism
  • Cells catabolize organic molecules and produce
    ATP in two ways
  • substrate-level phosphorylation
  • aerobic respiration
  • in most organisms, both are combined
  • glycolysis
  • pyruvate oxidation
  • Krebs cycle
  • electron transport chain

11
Aerobic Respiration
12
Stage One - Glycolysis
  • For each molecule of glucose that passes through
    glycolysis, the cell nets two ATP molecules.
  • Priming
  • glucose priming
  • cleavage and rearrangement
  • Substrate-level phosphorylation
  • oxidation
  • ATP generation

13
Priming Reactions
14
Cleavage Reactions
15
Energy-Harvesting Reactions
16
Recycling NADH
  • As long as food molecules are available to be
    converted into glucose, a cell can produce ATP.
  • Continual production creates NADH accumulation
    and NAD depletion.
  • NADH must be recycled into NAD.
  • aerobic respiration
  • fermentation

17
Recycling NADH
18
Stage Two - Oxidation of Pyruvate
  • Within mitochondria, pyruvate is decarboxylated,
    yielding acetyl-CoA, NADH, and CO2.

19
Stage Three - Krebs Cycle
  • Acetyl-CoA is oxidized in a series of nine
    reactions.
  • two steps
  • priming
  • energy extraction

20
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21
Overview of Krebs Cycle
  • 1 Condensation
  • 2-3 Isomerization
  • 4 First oxidation
  • 5 Second oxidation
  • 6 Substrate-level phosphorylation
  • 7 Third oxidation
  • 8-9 Regeneration and oxaloacetate

22
Krebs Cycle
23
Krebs Cycle
24
Harvesting Energy by Extracting Electrons
  • Glucose catabolism involves a series of
    oxidation-reduction reactions that release energy
    by repositioning electrons closer to oxygen
    atoms.
  • Energy is harvested from glucose molecules in
    gradual steps, using NAD as an electron carrier.

25
Electron Transport
26
Stage Four The Electron Transport Chain
  • NADH molecules carry electrons to the inner
    mitochondrial membrane, where they transfer
    electrons to a series of membrane-associated
    proteins.

27
Electron Transport Chain
28
Chemiosmosis
29
ATP Generation
  • This process begins with pyruvate, the product of
    glycolysis, and ends with the synthesis of ATP

30
Theoretical ATP Yield of Aerobic Respiration
31
Regulating Aerobic Respiration
  • Control of glucose catabolism occurs at two key
    points in the catabolic pathway.
  • glycolysis - phosphofructokinase
  • Krebs cycle - citrate synthetase

32
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33
Control of Glucose Catabolism
34
Catabolism of Proteins and Fats
  • Proteins are utilized by deaminating their amino
    acids, and then metabolizing the product.
  • Fats are utilized by beta-oxidation.

35
Cellular Extraction of Chemical Energy
36
Fermentation
  • Electrons that result from the glycolytic
    breakdown of glucose are donated to an organic
    molecule.
  • regenerates NAD from NADH
  • ethanol fermentation
  • lactic acid fermentation
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