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AP Biology Chapter 6: An Introduction to Metabolism

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Title: AP Biology Chapter 6: An Introduction to Metabolism


1
AP Biology Chapter 6An Introduction to
Metabolism
2
Metabolism
  • Totality of an organisms reactions
  • (from Greek metabole, to change)
  • An emergent property from interactions between
    chemicals within the environment of the cell
  • Concerned with managing the material and energy
    resources of the cell

3
Metabolism
  • Made of two types of reactions
  • Catabolic Pathways release energy by breaking
    down complex molecules into simpler compounds
    (e.g. cellular respiration)
  • downhill reactions
  • Anabolic Pathways consume energy to build
    complicated molecules from simpler ones (e.g.
    synthesis of proteins from amino acids)
  • uphill reactions
  • These reactions are coupled together

4
Bioenergetics
  • The study of how organisms manage their energy
    resources
  • Energy the capacity to do workability to
    rearrange a collection of matter
  • Kinetic energy of motion
  • Potential stored energy
  • Chemical form of potential energy stored in
    molecules as the result of the arrangement of
    atoms

5
Thermodynamics
  • Study of the energy transformations that occur in
    a collection of matter
  • First Law of Thermodynamics energy is
    constantenergy can be transferred and
    transformed but it cannot be created nor
    destroyed
  • Second Law of Thermodynamics every energy
    transfer makes the universe more disordered or
    random or increases the entropy (measure of the
    randomness)

6
Entropy
  • In most energy transformations, some of the
    energy stored is converted to heat (the most
    random form of energy)
  • Organisms are open systems and exchange energy
    and materials with the surroundingstakes in both
    organized and unorganized forms of matter and
    energy and releases both into the environment
  • Depletions of energy in organisms is due to the
    loss as heat.

7
Free Energy
  • The portions of a systems energy that is
    available to perform work when temperature is
    uniform throughout the system
  • Not all of the energy in a system is available
    for work
  • G H T S
  • G Free EnergyH Total Energy (of the
    system)T Temperature (in Kelvin)S Entropy

8
Energy Changes
  • ?G ?H - T ?S
  • For spontaneous, downhill reactions, ?G must be
    negative (?G lt 0)

9
Free Energy and Metabolism
  • Exergonic Reactions (energy outward) proceeds
    with a net release of free energy. ?G is
    negative. Reactions are spontaneous
  • Endergonic Reactions (energy inward) absorbs
    free energy from its surroundings, stores free
    energy in molecules. ?G is positive. Reactions
    are nonspontaneous. Require energy to drive
    reaction

10
Energy Changes
11
Metabolic Disequilibrium
  • Equilibrium ?G 0. There is no net change in
    the system. No work is being performed
  • Reactions in closed systems will eventually reach
    equilibrium
  • Living organisms are open systems and maintain
    disequilibrium by constantly flowing materials
    into and out of the cell
  • Analogy hydroelectric systems

12
Metabolic Disequilibrium
13
What work do cells do?
  • Mechanical Work beating cilia, contraction of
    muscles, movement of chromosomes during cell
    division
  • Transport Work pumping substances across
    membranes against spontaneous movement
  • Chemical Work pushing of endergonic reactions,
    synthesis of polymers
  • All these works require energy in the form of
    ATP

14
ATP
  • Adenosine triphosphate is closely related to a
    nucleotide. It contains an adenine base,
    ribose, and 3 phosphate groups
  • The phosphate groups are highly charged and when
    broken apart by hydrolysis releases large amounts
    of energy. (?G -13 kcal/mole)

15
How ATP does work
  • With the help of enzymes, the cell can couple the
    energy release of ATP hydrolysis with an
    endergonic process by transferring a phosphate
    group from ATP to another molecule.
  • The recipient of the phosphate is phosphorylated
    and becomes a more reactive intermediate

16
Regeneration of ATP
  • An organism at work (alive) uses ATP
    continuously, but ATP is a renewable resource and
    can be regenerated from ADP by adding a phosphate
    (Pi)
  • The energy required to phosphorylate ADP comes
    from the break down (catabolism) of molecules in
    the cell
  • Very quick process?A working muscle cell
    regenerates ALL its ATP in under 1 minute (10
    million molecules/second)

17
Catalysts
  • Chemical agent that changes the rate of a
    reaction without being consumed by the reaction
  • Enzymes are biological catalysts, most often made
    of protein (there are a few ribozymes made of
    RNA)
  • Without enzymes, most reactions, even
    spontaneous, exothermic reactions, proceed VERY
    slowly.
  • Example Sucrose in water will not break down

18
Activation Energy Barrier
  • Chemical reactions involve forming and breaking
    of bonds. Existing bonds in reactants must be
    broken and new bonds of products formed.
  • Breaking bonds requires an input of energy
  • The initial investment of energy for starting a
    reactionenergy required to break bonds is
    called the activation energy or free energy of
    activation (EA)

19
Enzymes and Activation Energy
  • Enzymes speed up reactions by lowering the EA
    barrier, so the transition state is within reach
    at moderate temperatures.
  • They do not change the ?G of the reaction

20
Enzymes are Substrate Specific
  • The reactant a specific enzyme works on is called
    a substrate
  • Enzymes bind to their substrate(s) allowing the
    catalytic action of the enzyme to create the
    products
  • Substrate Enzyme Product
  • Enzymes can distinguish their substrate by shape.
    The substrate must fit into the active site of
    the enzyme, a groove or pocket in the protein

21
Enzyme-Substrate Cycle
22
Induced Fit
  • Active sites are not rigid like a lock-and-key
    but instead change shape slightly to fit snugly
    around the substratelike a handshake
  • Induced fit brings chemicals together into
    positions that enhance their ability to catalyze

23
Environmental Effects on Enzymes
  • Enzyme activity is greatly affected by general
    environmental factors
  • Enzymes have optimal conditions where they work
    best
  • Temperature thermal agitation can disrupt
    conformation. Optimal temp allows greatest
    number of molecular collisions without
    denaturing (usually 35-40ºC)
  • pH H concentration can also disrupt
    conformation. Optimal range for most enzymes is
    between pH 6-8

24
Cofactors
  • Many enzymes require non-protein helpers for
    catalytic activity, called cofactors which are
    bound to the active site
  • They can be permanent or bind reversibly with the
    substrate
  • Cofactors are inorganic such as iron, zinc, or
    copper
  • Coenzymes are organic cofactors

25
Enzyme Inhibitors
  • Certain chemicals selectively inhibit the action
    of an enzyme by covalently bonding to the active
    site. Usually irreversibly
  • Competitive Inhibition bind with the active
    site, competing with the substrate for access to
    the active site
  • Can be overcome by increase the concentration of
    the substrate
  • Noncompetitive Inhibition bind with the enzyme
    outside of the active site, changing the enzymes
    conformation and impeding the substrate binding
  • Examples poisons, antibiotics

26
Allosteric Regulation
  • Reversible noncompetitive inhibitors are in
    charge of most of the control of metabolism
  • Regulatory molecules (activators or inhibitors)
    bind at an allosteric site away from the active
    site to turn on/off an enzymes activity
  • Allosteric enzymes have multiple subunits
    (polypeptide chains)

27
Feedback Inhibition
  • Products of a pathway can act as the allosteric
    inhibitors and switch off an enzyme in the
    catabolic process
  • Example ATP is the allosteric inhibitor for the
    ATP-generating catabolic pathway

28
Cooperativity
  • Substrate molecules can stimulate an enzyme.
    Binding a substrate can induce the enzyme to
    change into a shape which is more favorable for
    binding at other sites
  • Amplifies the response of enzymes to substrates

29
Localization of Enzymes
  • Organisms are more efficient because they can
    keep all the enzymes required for a pathway in
    one place, organ or organelle.
  • Metabolic pathways can be assembled together into
    a multienzyme complex to keep everything
    organized and efficient
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