electron transfer

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Created by
Deborah Otunji

Cards (27)

  • Metabolism
    Breaking down food to harvest electrons
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  • Key Electron Carriers
    • NADH and FADH₂ are molecules that carry high-energy electrons due to their electronegative redox potential
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  • Sources of Electrons
    • Proteins
    • Carbohydrates
    • Fatty Acids
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  • Electron-Transport Chain (ETC)

    Central pathway linking food intake to ATP synthesis
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  • Complete Metabolic Pathway
    Glucose+10NAD++2Q+2ADP+2GDP+4Pi+2H2O→10NADH+10H++2QH2+2ATP+2GTP+6CO2
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  • Hydride Ion (H⁻)

    A negatively charged ion consisting of a proton and two electrons
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  • Role of Hydride Ion in Biology
    Transfers high-energy electrons during metabolic reactions
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  • NADH/NAD⁺
    • NADH (Reduced Form): Main carrier of high-energy electrons
    • NAD⁺ (Oxidized Form): Accepts electrons to become NADH
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  • Electron Transfer Mechanism
    Hydride ion (H⁻) transfer involves two electrons moving from one molecule to another
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    • Proton: ~1.7 x 10⁻²⁷ g
    • Electron: ~1 x 10⁻³⁰ g (2000 times lighter than a proton)
    • NAD⁺: ~1 x 10⁻²¹ g (1 billion times heavier than an electron)
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  • Main Types of Electron Transfer in Biology
    • Hydride Ion Transfer (NADH)
    • Concomitant Transfer of an Electron and a Proton (FADH₂)
    • Direct Electron Transfer (Cytochromes)
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  • Glycolysis and Citric Acid Cycle
    Among the oldest metabolic pathways, present in archae bacteria
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  • Iron–Sulfur World Theory

    Suggests early life formed on iron sulfide minerals, with primitive biochemistry predating proteins and genes
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  • Electric Bacteria
    • Shewanella and Geobacter: Bacteria that use electrons from rocks and metals, demonstrating early forms of electron-based metabolism
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  • Eukaryotic cells retain bacterial biochemistry to produce NADH through glycolysis, pyruvate oxidation, and the citric acid cycle
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  • Citric Acid Cycle
    • Objective: Load electrons into highly electronegative carriers (NADH, FADH₂)
    • Process: Involves 8 key reactions transforming acetyl-CoA into CO₂, NADH, FADH₂, and GTP/ATP
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  • Reaction 1: Citrate Synthase
    1. Action: Joins acetyl-CoA to oxaloacetate to form citrate
    2. Carbon Skeleton: 4C (oxaloacetate) + 2C (acetyl-CoA) = 6C (citrate)
    3. Details: Initiates the cycle by forming a 6-carbon molecule
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  • Reaction 2: Aconitase
    1. Action: Isomerizes citrate to isocitrate
    2. Purpose: Makes the target carbon more accessible for subsequent reactions
    3. Details: Converts citrate to its isomer isocitrate
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  • Reaction 3: Isocitrate Dehydrogenase
    1. Action: Isocitrate donates electrons to NAD⁺, forming NADH and releasing CO₂
    2. Carbon Skeleton: 6C → 5C
    3. Details: The first NADH is produced, and the first CO₂ is released
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  • Reaction 4: Alpha-Ketoglutarate Dehydrogenase
    1. Action: Alpha-ketoglutarate donates electrons to NAD⁺, forming NADH and releasing CO₂
    2. Produces: High-energy intermediate succinyl-CoA
    3. Carbon Skeleton: 5C4C
    4. Details: The second NADH is produced, and the second CO₂ is released
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  • Reaction 5: Succinyl-CoA Synthetase
    1. Action: Cleaves succinyl-CoA to form succinate and transfers energy to GDP, forming GTP
    2. Process: Substrate-level phosphorylation
    3. Details: Produces GTP (an ATP equivalent)
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  • Reaction 6: Succinate Dehydrogenase
    1. Action: Succinate donates electrons to FAD, forming FADH₂
    2. Enzyme Location: Bound to the inner mitochondrial membrane, marking mitochondria during subcellular fractionation
    3. Details: The only citric acid cycle enzyme that is membrane-bound
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  • Reaction 7: Fumarase
    1. Action: Hydrates fumarate to malate
    2. Result: Addition of water
    3. Details: Converts fumarate to malate by adding water
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  • Reaction 8: Malate Dehydrogenase
    1. Action: Malate donates electrons to NAD⁺, forming NADH and regenerating oxaloacetate
    2. Carbon Skeleton: 4C oxaloacetate is recycled
    3. Details: Completes the cycle by regenerating oxaloacetate and producing the third NADH
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  • Key Products of the Citric Acid Cycle
    • Per Turn of the Cycle:
    • 2 CO₂
    • 3 NADH
    • 1 FADH₂
    • 1 GTP (or ATP)
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  • Understanding the citric acid cycle is fundamental to grasping cellular respiration and metabolism
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  • Electrons harvested from food drive ATP synthesis, highlighting the link between diet and energy production
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