electron transport chain

Created by

Deborah Otunji

Cards (27)

Energy 
The capacity to do work
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Design and Work 
For energy to do useful work, a suitable design is required
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Chemical Work in Cells 
Cells perform chemical work to drive non-spontaneous reactions (positive ΔG)
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Metabolism 
Involves harnessing energy from nutrients and storing it in molecules like NADH and ATP
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Photosynthesis 
Converts light energy into chemical energy in leaves
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Cellular Respiration 
Uses the energy stored in nutrients to perform chemical work
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Suitable Design for Energy Harnessing 
A car engine harnesses work from chaotic explosions
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Mitochondria Design 
Inner membrane ridges (cristae) provide a design to accumulate and use a proton gradient to drive ATP synthesis
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Redox Potential 
The tendency of a molecule to acquire electrons and be reduced
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Positive Redox Potential 
Greater affinity for electrons (e.g., O₂, +0.82V)
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Negative Redox Potential 
Greater propensity to donate electrons (e.g., NADH, -0.34V)
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Electron Flow 
Electrons flow from molecules with a negative redox potential to those with a positive redox potential, releasing energy
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Complex I (NADH Dehydrogenase) 
Transfers electrons from NADH to ubiquinone (Q), pumping protons (H⁺) across the membrane
Consists of 45 proteins
NADH + H⁺ + Q → NAD⁺ + QH₂
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Complex II (Succinate Dehydrogenase)
Transfers electrons from succinate to ubiquinone without proton pumping
Entry point for electrons from FADH₂
Succinate + Q → Fumarate + QH₂
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Complex III (Cytochrome b-c1 Complex)
Transfers electrons from ubiquinol to cytochrome c, pumping protons
Consists of 22 proteins
QH₂ + 2 Cyt c (Fe³⁺) → Q + 2 Cyt c (Fe²⁺) + 2 H⁺
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Complex IV (Cytochrome Oxidase) 
Transfers electrons from cytochrome c to oxygen, forming water and pumping protons
Consists of 26 proteins
4 Cyt c (Fe²⁺) + 4 H⁺ + O₂ → 4 Cyt c (Fe³⁺) + 2 H₂O
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Ubiquinone (Coenzyme Q) 
Mobile electron carrier transporting electrons between complexes I, II, and III
Exists in oxidized (Q) and reduced (QH₂) forms
Q + 2 H⁺ + 2 e⁻ → QH₂
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Mechanism of Proton Pumping
1. Each complex exists in three conformations with different affinities for H⁺
2. High Affinity (A, B): Binds protons
3. Low Affinity (C): Releases protons
4. Electron flow induces conformational changes, facilitating proton pumping and creating a proton gradient
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Energy Conversion in the ETC
Electrons Flow: Converts potential energy (voltage) into kinetic energy
Proton Gradient: Stores energy as a high concentration of protons in the intermembrane space
ATP Synthesis: Proton gradient drives ATP synthesis through ATP synthase
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Analogies and Examples 
Electric Circuit: ETC functions like an electric circuit with electrons flowing from negative to positive potentials
Car Engine: Suitable design (mitochondrial cristae) harnesses energy efficiently
Cable Bacteria: Electron flow from hydrogen sulfide to oxygen demonstrates redox potential in nature
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Proton-Motive Force (PMF) 
The force exerted by the proton gradient across the inner mitochondrial membrane
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ATP Synthase 
Enzyme that uses the PMF to synthesize ATP from ADP and inorganic phosphate (Pi)
Protons flow through ATP synthase, causing it to rotate and catalyze ATP formation
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ETC Efficiency and Regulation
The design of the ETC allows for efficient energy conversion and minimal loss of energy as heat
ETC activity is regulated by the availability of substrates (NADH, FADH₂, O₂) and ADP
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Redox Potential determines the direction of electron flow
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Electron Transport Chain works like an electric circuit, converting energy to create a proton gradient
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Proton Gradient is essential for ATP synthesis
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Design in Mitochondria: Cristae increase surface area for efficient energy conversion and storage
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