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UNIT IV – CELLULAR ENERGY
Hillis- Ch 2.5, 6 Big Campbell ~ Ch 8,9,10 Baby Campbell ~ Ch 5,6,7
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I. THE WORKING CELL, cont Energy
Kinetic Energy –energy associated with the relative motion of objects. EX: pool stick cue ball other balls Potential Energy – energy that matter possesses (stored) because of its location or structure. EX: water behind a dam Chemical Energy – Potential energy of molecules
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I. THE WORKING CELL Thermodynamics
First Law of Thermodynamics states that total amount of energy in universe is constant – can be transferred or transformed, but it cannot be created or destroyed Principle of the Conservation of Energy Second Law of Thermodynamics states that energy is lost to the environment as heat; that is, some energy becomes unusable EX: Bear catching fish for food Entropy – measure of disorder or randomness that is a consequence of the loss of useable energy during energy transfer.
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I. THE WORKING CELL, cont Metabolism
Totality (sum) of an organism’s chemical reactions Two types of reactions Catabolic Pathways Breaks down molecules; releases energy; EX: Cellular Respiration Exergonic Anabolic Pathways Pathway that synthesizes larger molecules from smaller ones; requires energy; EX: synthesis of AA, synthesis of proteins Endergonic 4
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I. THE WORKING CELL, cont Gibbs Free Energy (ΔG)
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I. THE WORKING CELL, cont ΔG and Enzyme Catalysis
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I. THE WORKING CELL, cont Energy Coupling
Energy released in exergonic rxn is used to drive endergonic rxn.
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II. ATP Powers 3 kinds of work: - Chemical (synthesis of polymers)
- Transport (pumping substances across the membrane) - Mechanical (beating of cilia, contraction of muscle cells, chromosome movement) 8
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II. ATP Adenosine Triphosphate
Nucleotide that stores & provides usable energy to the cell Structure of ATP 5-C Sugar called Ribose Nitrogen base Adenine 3 Phosphate groups ATP contains potential energy, especially between 2nd and 3rd phosphate groups. P – P bond is unstable Easily broken by HYDROLYSIS 9
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II. ATP, cont ATP → ADP + Pi Catabolic Pathway Exergonic
Coupled with endergonic rxn – specifically, by transferring phosphate group from ATP to another molecule.
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II. ATP, cont ADP + Pi → ATP Anabolic pathway Endergonic
Mechanisms for “making” ATP Substrate-level Phosphorylation – enzyme transfers a P from a substrate molecule to an ADP (organic molecule generated as an intermediate) Oxidative Phosphorylation – powered by the redox reactions of the ETC (on the membranes) during chemiosmosis Photophosphorylation – generation of ATP in the light reactions using chemiosmosis
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II. ATP, cont Substrate-Level Phosphorylation vs
II. ATP, cont Substrate-Level Phosphorylation vs. Oxidative/Photo Phosphorylation
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II. ATP, cont In a human, 10 million molecules of ATP are “made” and “used” per second!! We use 1 X 1025 (10,000,000,000,000,000,000,000,000 or 10 quadrillion) molecules of ATP per day!! That translates to 100 lbs of ATP At any given moment, the amount present is ~ 2 oz!! A working muscle cell recycles its entire supply of ATP in less than a minute!! Bacteria contain a 1 second supply of ATP!!
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III. ♪ ♫ THE CYCLE OF LIFE ♪ ♫
Photosynthesis 6CO2 + 6H2O + sun C6H12O6 + 6O2 Occurs in the chloroplasts of plants Cellular Respiration C6H12O6 + 6O2 6CO2 + 6H2O + ATP Occurs in the mitochondria of plants and animals CO2 + H2O Organic molecules + O2
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IV. ENERGY IN THE CELL Oxidation-Reduction Reactions
Energy yield in catabolism comes from transfer of electrons Movement of electrons releases chemical energy of molecule Released energy used to generate ATP from ADP and Pi Known as redox reaction - One molecule loses an electron and a 2nd molecule gains an e- Oxidation Electron donor (which is oxidized)is known as reducing agent (EX: glucose) Reduction Electron acceptor (which is reduced)is known as oxidizing agent (EX: O2)
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IV. ENERGY IN THE CELL, cont
Oxidation-Reduction Reactions Electron movement in molecules often traced by changes in H atom distribution Reactants Products Becomes oxidized Becomes reduced Water Reducing agent - methane Oxidizing agent - oxygen Carbon dioxide
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IV. ENERGY IN THE CELL, cont
Importance of Electron Carriers Energy contained in molecules (for example, glucose) must be released in a series of steps Electrons released as hydrogen atoms with corresponding proton Hydrogen atoms are passed to an electron carrier Electron carriers are coenzymes “Carry” 2 electrons in the form of H-atoms Allow for maximum energy transfer, minimum energy loss
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IV. ENERGY IN THE CELL, cont
Electron Carriers NAD+ Nicotinamide adenine dinucleotide Electron acceptor in cellular respiration Reduced to _NADH_ FAD Flavin adenine dinucleotide Electron acceptor in Krebs Cycle Reduced to _FADH2__ NADP+ Nicotinamide adenine dinucleotide phosphate Electron acceptor in light reaction of photosynthesis Reduced to _NADPH_
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V. PHOTOSYNTHESIS – AN OVERVIEW
Photosynthesis – Process of capturing light energy and converting it to chemical energy Endergonic – b/c e- increase in potential energy as they move from water to sugar. Plants are _Producers_; also known as _Autotrophs_
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V. PHOTOSYNTHESIS – AN OVERVIEW
Redox Reaction becomes oxidized 6CO2 + 6H2O + sunlight C6H12O6 + 6O2 becomes reduced (e- added) Water is split and e- are transferred with H+ to CO2, reducing it to sugar. 20
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V. PHOTOSYNTHESIS – AN OVERVIEW, cont
Water Movement Root Structure Ψ Transpiration
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V. PHOTOSYNTHESIS – AN OVERVIEW, cont
Leaf Structure Epidermis Cuticle Stomata & Guard Cells Mesophyll Chloroplast Structure Thylakoids – Site of Light Reaction First step in photosynthesis Granum Stroma Site of Calvin Cycle Second step in photosynthesis
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V. PHOTOSYNTHESIS OVERVIEW, cont
Oxidation Reduction 23
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V. PHOTOSYNTHESIS OVERVIEW, cont
Sunlight: giant thermonuclear reactor – energy comes from fusion reactions similar to those in a hydrogen bomb. When light hits matter, it can be reflected, transmitted, or absorbed.
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VI. LIGHT REACTION OF PHOTOSYNTHESIS
Occurs in thylakoid membranes Converts light energy to chemical energy Light energy Visible light is a small portion of the electromagnetic spectrum. Light absorbed by chlorophyll and other photosynthetic pigments to power reactions is not seen. Light not utilized by plant is reflected & seen by human eye. (Leaf appears green b/c it reflects green &absorbs red and blue light) Light energy measured in photons, which each have a fixed quantity of energy inversely related to the wavelength. 25
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VI. LIGHT REACTION OF PHOTOSYNTHESIS, cont
Photosynthetic pigments - (substances that absorb visible light) Chlorophyll a – absorbs mainly blue-violet and red light Chlorophyll b – absorbs mainly blue and orange light Cartenoids – other accessory pigments; expand spectrum of light energy that can be used for photosynthesis carotenoid xanthophyll Chlorophyll a Chlorophyll b
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VI. LIGHT REACTION OF PHOTOSYNTHESIS, cont
The ability of a pigment to absorb various wavelengths of light can be measured with a spectrophometer which directs beams of light of different wavelengths through a solution of pigment and measures light transmitted at each wavelength.
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VI. LIGHT REACTION OF PHOTOSYNTHESIS, cont
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VI. LIGHT REACTION OF PHOTOSYNTHESIS, cont
A photon of light energy is absorbed by pigment molecule in Photosystem II. Energy is passes from one molecule to another until it reaches P680 - pair of chlorophyll a molecules. Electron in each is excited to higher energy state – transferred to primary electron acceptor. Water is split to replace electron lost by P680. O2 is released. H+ ions remain. 29
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VI. LIGHT REACTION OF PHOTOSYNTHESIS, cont
Excited electron moves from primary electron acceptor to Photosystem I via electron transport chain. As electron “falls”, energy is released. Used to synthesize ATP through chemiosmosis. Known as photophosphorylation
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VI. LIGHT REACTION OF PHOTOSYNTHESIS, cont
Light energy is transferred via light-harvesting complexes to P700 in Photosystem I. Excited electron is captured by primary electron acceptor. P700’s electron is replaced by electron transport chain on Photosystem II. Electron from P700 moves through a short electron transport chain, reducing NADP+ to NADPH. 31
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VI. LIGHT REACTION OF PHOTOSYNTHESIS, cont
Linear Electron Flow 32
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VI. LIGHT REACTION OF PHOTOSYNTHESIS, cont
Cyclic Electron Flow Alternative pathway seen in some bacteria, plants May be photoprotective in plants Only utilizes Photosystem I No NADPH production No O2 release Does generate ATP 33
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VII. CALVIN CYCLE OF PHOTOSYNTHESIS
Also known as Dark Reaction, Light-Independent Rxn Occurs in stroma of chloroplasts “Synthesis” part of photosynthesis; utilizes ATP, NADPH generated in Light Reaction + CO2 to produce organic molecules Anabolic; endergonic Requires enzyme Rubisco Three basic steps Carbon Fixation Reduction Regeneration of RuBP 34
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VII. CALVIN CYCLE OF PHOTOSYNTHESIS, cont
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VII. CALVIN CYCLE OF PHOTOSYNTHESIS, cont Sugar Transport
From sugar source sugar sink Sieve tubes – pathway for translocation of sugars (phloem) Moves by Bulk Flow which is driven by positive pressure known as pressure flow. Building of pressure at source & reduction of that pressure at the sink causes sap to flow source sink
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VIII. PHOTORESPIRATION
Counterproductive pathway Plants close stomata to prevent water loss; decreases CO2 Oxygen binds to active site of Rubisco – product splits and a 2C compound leaves chloroplast… Peroxisomes & mitochondria rearrange & split this compound, releasing CO2 Consumes ATP; decrease carbohydrate yield Purpose = neutralize damaging products of the light Rxns which build up when Calvin cycle is limited.
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VIII. PHOTORESPIRATION, cont
Plant Adaptations C4 Plants (C4 Photosynthesis) - Alternate mode of carbon fixation to minimize photorespiration and optimize Calvin cycle - Uses PEP carboxylase to bond CO2 to PEP to form a 4-C compound - Occurs in mesophyll cells - Passes the 4-C compound through plasmodesmata to Bundle sheath cells - EX: sugarcane, corn, grasses
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VIII. PHOTORESPIRATION, cont
Plant Adaptations, cont CAM Plants - Crassulacean acid metabolism - Adaptation to dry, arid - Stomata open at night & closed during day. - Incorporate CO2 at night & convert into 4-C organic acids - Organic acids stored in vacuoles of mesophyll cells until am when stomata close. - EX: succulents such as cacti and pineapple
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IX. CELLULAR RESPIRATION – AN OVERVIEW
Process used by cells to convert chemical energy in glucose (and other molecules) to ATP Primarily takes place in mitochondria of eukaryotic cells Overall Reaction becomes oxidized C6H12O6 + 6O2 6CO2 + 6H2O + energy becomes reduced
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IX. CELLULAR RESPIRATION OVERVIEW, cont
Glycolysis “Sugar-breaking” Initial breakdown of glucose to intermediate, some ATP Pyruvate Oxidation Occurs in mitochondria Krebs Cycle Completes oxidation of glucose to CO2 Produces ATP, but more importantly provides high-energy electrons for etc Electron Transport Chain Oxidative Phosphorylation Highest ATP yield; uses energy released from downhill flow of electrons to generate ATP
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X. GLYCOLYSIS Occurs in cytosol of cell Does not require oxygen
First part of pathway is energy investment phase Second part of pathway is energy pay-off phase Energy Investment Phase
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X. GLYCOLYSIS, cont Energy Pay-Off Phase
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X. GLYCOLYSIS, cont Summary of Glycolysis
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XI. OXIDATIVE RESPIRATION
Pyruvate Oxidation Oxygen must be available Takes place in mitochondrial matrix prior to Citric Acid Cycle … Carboxyl group of pyruvate is removed, given off as CO2 Remaining 2-C molecule is oxidized to acetate → NAD+ reduced to NADH + H+ Acetate binds to molecule known as Coenzyme A to form acetyl CoA
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XI. OXIDATIVE RESPIRATION, cont
Citric Acid Cycle (Krebs cycle, tricarboxylic acid cycle, TCA cycle) 2-C molecule goes through a series of redox rxns. Occurs in mitochondrial matrix Produces NADH, FADH2, ATP, and CO2. CoA is not actually a part of the reaction it is recycled remember, it is an enzyme!
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XI. OXIDATIVE RESPIRATION, cont
Oxidative Phosphorylation Traditionally called Electron Transport Occurs in inner mitochondrial membrane Membrane organized into cristae to increase surface area Two components to Oxidative Phosphorylation Electron Transport Chain Chemiosmosis
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XI. OXIDATIVE RESPIRATION, cont
Electron Transport Chain Collection of molecules, each more electronegative than the one before it Molecules are reduced, then oxidized as electrons are passed down the chain Oxygen is ultimate electron acceptor Purpose is to establish H+ gradient on two sides of inner mitochondrial membrane Energy from “falling electrons” used to pump H+ from matrix into intermembrane space
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XI. OXIDATIVE RESPIRATION, cont
Chemiosmosis Enzyme complexes known as ATP synthases located in inner mitochondrial membrane H+ electrochemical gradient provides energy Known as proton motive force Movement of H+ ions through membrane rotates enzyme complex Rotation exposes active sites in complex ATP is produced from ADP and Pi
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XI. OXIDATIVE RESPIRATION, cont
A summary of oxidative phosphorylation . . .
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XI. OXIDATIVE RESPIRATION, cont
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XII. CELLULAR RESPIRATION – A SUMMARY
Each NADH shuttled through ETC results in approximately ___2.5___ ATP Each FADH2 shuttled through ETC results in approximately __1.5___ ATP. Total ATP Gain in Cellular Respiration = _2_ (glycolysis) + _2_ (citric acid cycle) + _28_ (oxidative phosphorylation) = _32__ ATP / glucose
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XII. CELLULAR RESPIRATION – A SUMMARY, cont
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XIII. CELLULAR RESPIRATION & OTHER FOOD MOLECULES
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XIV. METABOLIC POISONS Blockage of Electron Transport Chain
Inhibition of ATP Synthase “Uncouplers” Prevent creation of H+ ion gradients due to leakiness of mitochondrial membrane
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XV. FERMENTATION Anaerobic pathway Occurs in cytosol Purpose
In glycolysis, glucose is oxidized to 2 pyruvate, 2 NAD+ are reduced to 2 NADH, and there is a net gain of 2 ATP In oxidative respiration, NADH is oxidized back to NAD+ in electron transport chain If oxygen is not present, another mechanism must be available to regenerate NAD+ or glycolysis cannot continue In fermentation, pyruvate is reduced thereby oxidizing NADH to NAD+ Allows glycolysis and net gain of 2 ATP per glucose to continue
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XV. FERMENTATION, cont
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XV. FERMENTATION, cont
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