Electron Transport Chain Chapter 20 Stryer Short Course.

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Presentation transcript:

Electron Transport Chain Chapter 20 Stryer Short Course

Substrate Level vs. Oxidative Phosphorylation

Overview Redox reactions Electron transport chain Proton gradient ATP synthesis Shuttles Analogy: How does burning coal put flour in the grocery store?

Mitochondria Matrix – Citric acid cycle – NADH Inner membrane space

Redox Half Reactions Reduction potential written in terms of a reduction half reaction A ox  A red Compared to a standard reaction Oxygen has high affinity to gain electrons: Reduction potential NAD + + H 2  NADH + 2 H + NAD +  NADH E o ’ = V Q + H 2  QH H + Q  QH 2 E o ’ = V NAD + has lower affinity for electrons than H + Not spontaneous Q has higher affinity for electrons than H + Spontaneous

Standard Reduction Potential

Redox Reactions Using standard half reactions, can determine spontaneity of any redox reaction Determine  E o ’ Determine  G o ’ FAD  FADH 2 E o ’ = V Flip FADH 2  FAD E o ’ = V Q  QH 2 E o ’ = V FADH 2 + Q  FAD + QH 2 E o ’ = V  G o ’ = -n  F  E o ’ where n = # e- and F = kJ/mol V

Passing electrons down the wire O 2 : high “reduction potential” Substrates – Organic cofactors – Metals (iron/sulfur clusters) – cytochromes

FMN

Redox reactions: electricity 2 e- transfer

Coenzyme Q: Mobile Carrier FADH 2 is a one e- donor Many reactions, including metals Ubiquinone is a key intermediate Can diffuse through nonpolar regions easily

Metals Iron clusters cytochromes Accept/donate 1 electron at a time

Oxygen: the final electron acceptor Water is produced—has very low reactivity, very stable Superoxide, peroxide as Reactive Oxygen Species Superoxide dismutase, catalase, vitamin E Overall reaction NADH + H + + ½ O 2  NAD + + H 2 O

Electron Transport Chain

Protonmotive Force NADH + H + + ½ O 2  NAD + + H 2 O + 10 H + pumped succinate + ½ O 2  fumarate + H 2 O + 6 H + pumped

Complex I NADH  Q through – FMN – Iron-sulfur clusters “Q pool” 4 protons pumped through conformational change induced by Q  QH2

Complex II Non-NADH sources – Complex II (citric acid cycle) – Fatty acid oxidation and Glycerol-3-phosphate shuttle: next chapter Bypasses Complex I – Loss of 4 protons pumped Electrons into Q pool

Complex III QH 2  cytochrome c in the intermembrane space 4 protons pumped Through Q cycle

Complex IV Cytochromes  O 2 Stoichiometry of half of an oxygen atom

Overall 10 protons shuttled from matrix to intermembrane space Makes pH gradient and ion gradient Store of potential energy to run ATP- making machine