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MITOCHONDRIA

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MITOCHONDRIA Oval shaped organelles; randomly scattered around the cytoplasm. Energy factories of the cell; produce the majority of the cell's ATP – PowerPoint PPT presentation

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Title: MITOCHONDRIA


1
MITOCHONDRIA
  • Oval shaped organelles randomly scattered around
    the cytoplasm.
  • Energy factories of the cell produce the
    majority of the cell's ATP
  • These ATP producing reactions cannot take place
    without oxygen, therefore the steps of cellular
    respiration that occur in the mitochondria are
    said to be aerobic.
  • Pyruvate Oxidation (Link reaction), Krebs Cycle
    and the Electron Transport Chain (ETC) are all
    aerobic.
  • Eukaryotes use mitochondria to produce cellular
    energy. Prokaryotes do these reactions in the
    cytoplasm and with much less energy being
    produced.

2
MITOCHONDRIA
  • The mitochondria are double-membraned organelles.
  • The folded inner membrane is known as cristae.
    The cristae has many proteins and other molecules
    embedded in it to help with the process of
    cellular respiration.
  • The matrix is the protein rich fluid inside the
    cristae.
  • The fluid-filled space between the two membranes
    is known as the intermembrane (-ous) space.
  • Mitochondria have their own DNA, mtDNA, and can
    therefore reproduce on their own. This mtDNA is
    very similar to prokaryotic DNA and has lead to
    the creation of the endosymbiosis hypothesis
    which states that mitochondria are descendants of
    early prokaryotic cells who developed a symbiotic
    relationship with early eukaryotic cells.

3
PYRUVATE OXIDATION (LINK REACTION)?
  • The two pyruvates formed at the end of glycolysis
    are transported into the matrix
  • In the matrix, under the control of a
    multi-enyzme, three changes occur.
  • The carboxyl end is removed as carbon dioxide.
    This is known as a decarboxylation reaction and
    is catalyzed by pyruvate decarboxylase.
  • Pyruvate becomes oxidized into acetate and NAD
    is reduced to NADH H
  • A sulfur-containing compound (coenzyme-A) is
    attached to the acetate, forming acetyl-coA.

4
PYRUVATE OXIDATION
  • Co-A comes from vitamin B5 (pantothenic acid).
  • The overall reaction
  • 2 pyruvate 2NAD 2 CoA --gt 2 acetyl-CoA
    2NADH 2H 2CO2
  • Acetyl-coA enters the Kreb cycle,
  • NADH go to the electron transport chain to
    produce ATP by oxidative phosphorylation
  • Carbon dioxide diffuses out of the cell as a
    waste produt
  • The protons (2H) stay in the matrix.
  • Acetyl-coA is the central molecule in energy
    metabolism. The majority of macromolecules that
    we use for catabolism are changed into
    acetyl-coA.
  • Acetyl-coA can produce ATP or lipids. If you
    need energy you get it as acetyl-coA enters the
    Krebs Cycle. If you do not need energy then
    acetyl-coA is used to produce fat for energy
    storage.

5
KREBS CYCLE
  • Founded by Hans Krebs (biochemist at the Univ. of
    Sheffield) in 1937. He won the Nobel Prize in
    1953 along with Fritz Albert Lipmann who
    discovered the importance of coenzyme-A.
  • An 8-step process with each step catalyzed by a
    specific enzyme.
  • It is a cycle because the product of step 8 is
    the reactant in step 1 (oxaloacetate).

6
KREBS CYCLE
  • The overall chemical equation is
  • Oxaloacetate acetyl-coA ADP P 3NAD FAD
  • --gt CoA ATP 3NADH 3H FADH2 2CO2
    oxaloacetate
  • By the end of the Krebs Cycle, the original
    glucose molecule is consumed. The six carbon
    atoms have left as carbon dioxide molecules.
  • All that is preserved are 4ATP (two from
    glycolysis and two from the Krebs Cycle) and 12
    reduced coenzymes
  • 2 NADH from glycolysis
  • 2 NADH from pyruvate oxidation
  • 6 NADH from the Krebs Cycle and
  • 2 FADH2 from the Krebs Cycle
  • Most of the energy from glucose will be produced
    in the next stage (ETC)
  • Notice in the figure on page 103 that all the
    carbons in the original glucose molecule are
    transformed into carbon dioxide.
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