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Chapter 8 - An Introduction to Metabolism

Metabolic Reactions and Energy

  • Some chemical reactions release energy

    • exergonic

    • breaking polymers

    • hydrolysis = catabolism

      • cellular respiration

  • Some chemical reactions require input of energy

    • endergonic

    • building polymers

    • dehydration synthesis = anabolism

      • synthesis of proteins (dehydration synthesis)

Endergonic vs. Exergonic Reactions

  • Exergonic

    • energy released

    • -delta G

  • Endergonic

    • energy invested

    • +delta G

  • Delta G

    • change in free energy and the ability to do work

2nd Law of Thermodynamics and Free Energy (Delta G)

  • Entropy

    • measure of disorder

  • Every energy transfer increases the entropy

  • A living system’s free energy is energy that can do work when temperature and pressure are in uniform, as in living

  • Delta G Formula

    • Delta G = Delta H - (T)Delta S

      • ΔH = change in enthalpy 

      • ΔS = change in entropy

      • T = absolute temp (K)

        • Kelvin = Celsius + 273

  • -ΔG = loss of energy (exergonic) and is spontaneous 

  • +ΔG = gain in energy (endergonic) and is nonspontaneous

  • All cells move towards equilibrium ΔG decreases

Equilibrium and Metabolism

  • Reactions in closed systems eventually reach equilibrium = no work

  • Cells are open systems and are not in equilibrium

    • This is due to their constant flow of materials

  • metabolism is never at equilibrium

  • A catabolic pathway in a cell releases free energy in a series of reactions

Energy and life

  • organisms require energy to live

    • where does that energy come from?

      • coupling exergonic reactions (releasing energy) with endergonic reactions (needing energy)

Energy Needs of Life

  • organisms are endergonic systems

  • Energy is needed for

    • synthesis (biomolecules), reproduction, active transport, movement, temperature regulation

Living Economy

  • Fueling the economy

    • eat high energy organic molecules (food)

    • break them down = catabolism (digest)

    • capture energy in form cell can use

  • Need an energy currency

    • a way to pass energy around

    • ATP

      • chemical form of energy known as adenosine triphosphate

BELOW IS NOT IN THE FLASHCARD DECK AS OF 9/22

ATP

  • Adenosine Triphosphate

    • modified nucleotide

      • adenine + ribose + Pi → AMP

      • AMP + Pi → ADP 

      • ADP + Pi → ATP

  • Energy is released from ATP when the terminal phosphate bond is broken

How does ATP store/release energy?

  • In the cell, the energy from the exergonic reaction of ATP hydrolysis can be used to drive an endergonic reaction

  • ATP drives endergonic reactions by phosphorylation

    • phosphorylation

      • transferring a phosphate group to some other

Regeneration of ATP (ATP/ADP Cycle)

  • ATP = renewable and regenerated by addition of a phosphate group to ADP

  • The energy to phosphorylate ADP = Catabloic Reactions

  • ATP/ADP Cycle = energy transferred from catabolic to anabolic pathways

  • A working muscle recycles over 10 million ATPs per sec

Enzymes and Metabolic Reactions

  • breaking down large molecules requires an initial input of energy = activation energy (EA)

  • 2nd Law of Thermodynamics

    • why don’t proteins, carbohydrates and other biomolecules breakdown?

    • at temperatures typical of the cell, molecules don’t make is over the hump of activation energy

  • heat speeds up reactions, but … would denature proteins and kill cells

How do enzymes lower EA?

  • orienting substrates correctly

  • straining substrate bonds

  • providing a favorable microenvironment

  • covalently bonding to the substrate

The Effectiveness of Enzymes

  • Can be affected by pH, Temperature, and some chemicals

    • Optimal enzyme temp for humans: 35-40C

    • Optimal enzyme pH for humans: 6-8

Cofactors

  • Non-Protein enzyme helpers

    • Inorganic Example: metal in ionic form

    • Organic Example: vitamins

Enzyme Inhibitors

  • Competitive

    • bind to the active site, competing with the substrate

  • Noncompetitive

    • bind to another part of an enzyme, making the active site less effective

      • toxins, poisions, pesticides, and antibiotics

Allosteric Regulation of Enzymes

  • either inhibit or stimulate an enzyme’s activity

  • occurs when a regulatory molecule binds to a protein at one site and affects the protein’s function at another site

Activators - stabilizes the active form of the enzyme

Inhibitors - stabilizes the inactive form of the enzyme

  • attractive for drug candidates for enzyme regulation due to their specificity

Chapter 8 - An Introduction to Metabolism

Metabolic Reactions and Energy

  • Some chemical reactions release energy

    • exergonic

    • breaking polymers

    • hydrolysis = catabolism

      • cellular respiration

  • Some chemical reactions require input of energy

    • endergonic

    • building polymers

    • dehydration synthesis = anabolism

      • synthesis of proteins (dehydration synthesis)

Endergonic vs. Exergonic Reactions

  • Exergonic

    • energy released

    • -delta G

  • Endergonic

    • energy invested

    • +delta G

  • Delta G

    • change in free energy and the ability to do work

2nd Law of Thermodynamics and Free Energy (Delta G)

  • Entropy

    • measure of disorder

  • Every energy transfer increases the entropy

  • A living system’s free energy is energy that can do work when temperature and pressure are in uniform, as in living

  • Delta G Formula

    • Delta G = Delta H - (T)Delta S

      • ΔH = change in enthalpy 

      • ΔS = change in entropy

      • T = absolute temp (K)

        • Kelvin = Celsius + 273

  • -ΔG = loss of energy (exergonic) and is spontaneous 

  • +ΔG = gain in energy (endergonic) and is nonspontaneous

  • All cells move towards equilibrium ΔG decreases

Equilibrium and Metabolism

  • Reactions in closed systems eventually reach equilibrium = no work

  • Cells are open systems and are not in equilibrium

    • This is due to their constant flow of materials

  • metabolism is never at equilibrium

  • A catabolic pathway in a cell releases free energy in a series of reactions

Energy and life

  • organisms require energy to live

    • where does that energy come from?

      • coupling exergonic reactions (releasing energy) with endergonic reactions (needing energy)

Energy Needs of Life

  • organisms are endergonic systems

  • Energy is needed for

    • synthesis (biomolecules), reproduction, active transport, movement, temperature regulation

Living Economy

  • Fueling the economy

    • eat high energy organic molecules (food)

    • break them down = catabolism (digest)

    • capture energy in form cell can use

  • Need an energy currency

    • a way to pass energy around

    • ATP

      • chemical form of energy known as adenosine triphosphate

BELOW IS NOT IN THE FLASHCARD DECK AS OF 9/22

ATP

  • Adenosine Triphosphate

    • modified nucleotide

      • adenine + ribose + Pi → AMP

      • AMP + Pi → ADP 

      • ADP + Pi → ATP

  • Energy is released from ATP when the terminal phosphate bond is broken

How does ATP store/release energy?

  • In the cell, the energy from the exergonic reaction of ATP hydrolysis can be used to drive an endergonic reaction

  • ATP drives endergonic reactions by phosphorylation

    • phosphorylation

      • transferring a phosphate group to some other

Regeneration of ATP (ATP/ADP Cycle)

  • ATP = renewable and regenerated by addition of a phosphate group to ADP

  • The energy to phosphorylate ADP = Catabloic Reactions

  • ATP/ADP Cycle = energy transferred from catabolic to anabolic pathways

  • A working muscle recycles over 10 million ATPs per sec

Enzymes and Metabolic Reactions

  • breaking down large molecules requires an initial input of energy = activation energy (EA)

  • 2nd Law of Thermodynamics

    • why don’t proteins, carbohydrates and other biomolecules breakdown?

    • at temperatures typical of the cell, molecules don’t make is over the hump of activation energy

  • heat speeds up reactions, but … would denature proteins and kill cells

How do enzymes lower EA?

  • orienting substrates correctly

  • straining substrate bonds

  • providing a favorable microenvironment

  • covalently bonding to the substrate

The Effectiveness of Enzymes

  • Can be affected by pH, Temperature, and some chemicals

    • Optimal enzyme temp for humans: 35-40C

    • Optimal enzyme pH for humans: 6-8

Cofactors

  • Non-Protein enzyme helpers

    • Inorganic Example: metal in ionic form

    • Organic Example: vitamins

Enzyme Inhibitors

  • Competitive

    • bind to the active site, competing with the substrate

  • Noncompetitive

    • bind to another part of an enzyme, making the active site less effective

      • toxins, poisions, pesticides, and antibiotics

Allosteric Regulation of Enzymes

  • either inhibit or stimulate an enzyme’s activity

  • occurs when a regulatory molecule binds to a protein at one site and affects the protein’s function at another site

Activators - stabilizes the active form of the enzyme

Inhibitors - stabilizes the inactive form of the enzyme

  • attractive for drug candidates for enzyme regulation due to their specificity

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