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How Cells Release Energy

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10 reactions that break glucose into 2 molecules of pyruvic acid ... Oxidize NADH to NAD No yield of additional ATP very inefficient! 2 major pathways: ... – PowerPoint PPT presentation

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Title: How Cells Release Energy


1
How Cells Release Energy
  • Glycolysis
  • Cell Respiration
  • Fermentation

2
Glycolysis
  • Glucose breaking
  • 10 reactions that break glucose into 2 molecules
    of pyruvic acid
  • Occurs in the cytoplasm
  • Energy yield 2 ATP

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What is glucose?
  • 6-carbon sugar (monosaccharide)
  • Main source of energy for most cells
  • What is pyruvic acid?
  • 3-carbon sugar
  • Starting matter for most biosynthetic pathways
  • What is ATP?
  • Adenosine Triphosphate
  • Temporary energy storage molecule

5
Glucose Activation
  • 1st half of glycolysis
  • Phosphorylation by ATP allows enzyme to act on
    glucose and allows it to split into two PGAL
    (phosphoglyceraldehye) molecules.
  • Energy expended as 2 ATP

6
2nd Half of Glycolysis
  • 2 NAD reduced to NADH storing energy for later
    use.
  • 4 ADP converted to ATP
  • Net yield

7
2nd Half of Glycolysis
  • 2 NAD reduced to NADH storing energy for later
    use.
  • 4 ADP converted to ATP
  • Net yield 2 ATP
  • 2 molecules of Pyruvic acid (3 carbon sugar
    molecule)

8
Fermentation
  • Anaerobic respiration occurs in the absence of
    oxygen.
  • Oxidize NADH to NAD
  • No yield of additional ATP very inefficient!
  • 2 major pathways
  • Alcoholic fermentation
  • Lactic acid fermentation

9
Alcoholic Fermentation
  • Carried out by yeast
  • Used to make beer and bread
  • Yeast coverts pyruvic acid to ethanol and CO2.

10
Lactic Acid Fermentation
  • Bacteria
  • Animal cells deprived of O2
  • Common during periods of intense exercise
  • May occur in cancer cells
  • May occur in times of stress

11
Anaerobic Respiration
  • Inorganic molecules act as electron acceptors.
  • 3 common ones nitrate (NO3-) sulfate (SO42-)
    and Carbon dioxide (CO2)
  • Carried out by bacteria called facultative
    anaerobes

12
Cell (aerobic) Respiration
  • Requires oxygen to complete the breakdown of
    pyruvic acid
  • Occurs in the mitochondria
  • Provides an additional 34 ATP in animal cells
  • 3 stages
  • Acetyl CoA formation
  • Krebs cycle
  • Respiratory chain

13
Acetyl CoA Formation
  • Pyruvic acid loses a molecule of CO2 as NAD is
    reduced to NADH.
  • The molecule that remains is called Acetyl
    coenzyme
  • This enters the Krebs cycle

14
Formation of Acetyl CoA
15
Krebs Cycle
  • Process discovered by Sir Hans dolf Krebs
    English biochemist
  • Continuing series of 8 reactions
  • Also called Citric acid cycle
  • CO2 produced as a by-product
  • Energy storage compounds produced
  • 6 NADH
  • 2 FADH2
  • 2 ATP

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Total Energy Yield So Far
  • From Glycolysis
  • 2ATPs and 2 NADHs
  • From Pyruvate - Acetyl CoA
  • 2 NADHs
  • From Krebs Cycle
  • 2 ATPs, 6NADHs, and 2 FADH2s
  • Where is all of the energy?

18
IT IS ALL LOCKED IN THE NADHS AND THE FADH2S!
19
The Electron Transport Chain
  • What is the ETC? Where is it located?
  • It is a series of electron carrier molecules,
    that transfer electrons to each other through a
    connected series of redox reactions.
  • It is located within the inner membrane of the
    mitochondrion
  • Electrons combine with free H ions and oxygen to
    produce H20
  • So oxygen necessary to extract energy!

20
The Final Count
  • For every NADH produced in the mitochondrion, how
    many ATPs are created?
  • 3
  • For every FADH2 produced, how many ATPs are
    created?
  • 2
  • For the 2 NADHs generated in glycolysis how many
    ATPs are created?
  • 2

21
  • 2 NADHs from glycolysis ----gt4-6 ATPs
  • 8 NADHs from the mitochondrial matrix ----gt 24
    ATPs
  • 2 FADH2s from KC -----gt

22
  • 2 NADHs from glycolysis ----gt

23
  • 2 NADHs from glycolysis ----gt4-6 ATPs
  • 8 NADHs from the mitochondrial matrix ----gt

24
  • 2 NADHs from glycolysis ----gt 4-6 ATPs
  • 8 NADHs from the mitochondrial matrix ----gt 24
    ATPs
  • 2 FADH2s from KC -----gt 4 ATPs
  • Total ATPs

25
  • 2 NADHs from glycolysis ----gt 4-6 ATPs
  • 8 NADHs from the mitochondrial matrix ----gt 24
    ATPs
  • 2 FADH2s from KC -----gt 4 ATPs
  • Total ATPs 32- 36 ATPs
  • ATPs from glycolysis

26
  • 2 NADHs from glycolysis ----gt4-6 ATPs
  • 8 NADHs from the mitochondrial matrix ----gt 24
    ATPs
  • 2 FADH2s from KC -----gt 4 ATPs
  • Total ATPs 32-34 ATPs
  • ATPs from glycolysis 2 ATP
  • ATPs from KC

27
  • 2 NADHs from glycolysis ----gt4-6 ATPs
  • 8 NADHs from the mitochondrial matrix ----gt 24
    ATPs
  • 2 FADH2s from KC -----gt 4 ATPs
  • Total ATPs 32-34 ATPs
  • ATPs from glycolysis 2 ATP
  • ATPs from KC 2 ATP
  • GRAND TOTAL

28
  • 2 NADHs from glycolysis ----gt4-6 ATPs
  • 8 NADHs from the mitochondrial matrix ----gt 24
    ATPs
  • 2 FADH2s from KC -----gt 4 ATPs
  • Total ATPs 32-34 ATPs
  • ATPs from glycolysis 2 ATP
  • ATPs from KC 2 ATP
  • GRAND TOTAL 36- 38 ATPs

29
The Equation of Respiration
  • Glucose O2 CO2 H2O ATP
  • The Equation of Fermentation
  • Glucose Pyruvic acid Lactic acid or Alcohol
    CO2

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