Chapter 8: An Introduction To Metabolism - PowerPoint PPT Presentation

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Chapter 8: An Introduction To Metabolism

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Title: An Introduction To Metabolism Author: James C. Reidy Last modified by: Authorized User Created Date: 6/30/1998 6:47:28 PM Document presentation format – PowerPoint PPT presentation

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Title: Chapter 8: An Introduction To Metabolism


1
Chapter 8 An Introduction To
Metabolism
2
Essential Knowledge
  • 2.a.1 All living systems require constant input
    of free energy (8.1-8.3).
  • 4.b.1 Interactions between molecules affect
    their structure and function (8.4 8.5).

3
Metabolism
  • The totality of an organisms chemical processes
  • Concerned with managing the material and energy
    resources of the cell

4
Catabolic Pathways
  • Pathways that break down complex molecules into
    smaller ones, releasing energy
  • Example Cellular respiration
  • DOWNHILL!

5
Anabolic Pathways
  • Pathways that consume energy, building complex
    molecules from smaller ones
  • Example Photosynthesis, condensation synthesis
  • UPHILL!

6
1st Law of Thermodynamics
  • Energy cannot be created or destroyed
  • It can be converted from one form to another
  • The sum of the energy before the conversion is
    equal to the sum of the energy after the
    conversion

7
2nd Law of Thermodynamics
  • Some usable energy dissipates during
    transformations and is lost
  • During changes from one form of energy to
    another, some usable energy dissipates, usually
    as heat
  • The amount of usable energy therefore decreases

8
Energy
  • Ability to do work
  • The ability to rearrange a collection of matter
  • Forms of energy
  • Kinetic
  • Potential
  • Activation

9
Kinetic and Potential Energy
  • Kinetic
  • Energy of action or motion
  • Ex heat/thermal energy
  • Potential
  • Stored energy or the capacity to do work
  • Ex chemical energy

10
Activation Energy
  • Energy needed to convert potential energy into
    kinetic energy

Activation Energy
Potential Energy
11
Free Energy
  • The portion of a system's energy that can perform
    work
  • Known as ?G

12
Free Energy
  • ?G ? H - T ? S
  • ? change (final-initial)
  • ?G free energy of a system
  • ?H total energy of a system (enthalpy)
  • T temperature in oK
  • ?S entropy of a system

13
Free Energy of a System
  • If the system has
  • more free energyless stable (greater work
    capacity)
  • less free energymore stable (less work capacity)
  • As rxn moves towards equilibrium, ?G will decrease

14
Chemical Reactions
  • These are the source of energy for living systems
  • They are based on free energy changes
  • Two types exergonic and endergonic

15
Reaction Types
  • Exergonic
  • chemical reactions with a net release of free
    energy
  • Ex cellular respiration
  • - ?G , energy out, spontaneous
  • Endergonic
  • chemical reactions that absorb free energy from
    the surroundings
  • Ex Photosynthesis
  • ?G , energy in, non-spontaneous

16
Exergonic/Endergonic
- ?G
?G
17
Cell Energy
  • Couples an exergonic process to drive an
    endergonic one
  • ATP is used to couple the reactions together
  • Types mechanical, transport, chemical

18
ATP Description
  • Adenosine Triphosphate
  • Made of
  • Adenine (nitrogenous base)
  • Ribose (pentose sugar)
  • 3 phosphate groups
  • bonds can be broken to make ADP

19
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20
Keys to ATP
  • Three phosphate groups and the energy they
    contain
  • Negative charges repel each other and makes the
    phosphates unstable
  • Tail is unstable more free energy more
    instability
  • Works by energizing other molecules by
    transferring phosphate groups
  • Hydrolysis of ATP free energy is released as
    heat (can be adv or not adv)

21
ATP Cycle
  • Energy released from ATP drives anabolic
    reactions
  • Energy from catabolic reactions recharges ATP
  • Very fast cycle
  • 10 million made per second

Coupled RXN
22
ATP Cycle
23
ATP is Made
  • Takes place in cytoplasm and mitochondria
  • Using special process called substrate-level
    phosphorylation
  • Energy from a high-energy substrate is used to
    transfer a phosphate group to ADP to form ATP

24
Enzymes
  • Biological catalysts made of protein
  • Speeds up rxn without being consumed
  • Cause the speed/rate of a chemical rxn to
    increase
  • By lowering activation energy

25
Basic Chemical Reaction
  • AB CD AC BD
  • AB and CD are reactants
  • AC and BD are products
  • Involves bond forming/breaking
  • Transition state can be unstable

26
Unstable state
Energy is released as heat
27
Enzymes
Intro to Enzymes movie
  • Lower the activation energy for a chemical
    reaction to take place
  • Why do we need enzymes?
  • Cells cant rely on heat to kick start rxns
  • Why? Denaturation, heat cant decipher between
    rxns
  • Enzymes are selective! Can only operate on a
    given chemical rxn

28
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29
Enzyme Terms
  • Substrate
  • the material the enzyme works on
  • Enzyme names
  • Ex. Sucrase
  • - ase name of an enzyme
  • 1st part tells what the substrate is (i.e.
    Sucrose)

30
Enzyme Name
  • Some older known enzymes don't fit this naming
    pattern
  • Examples pepsin, trypsin

31
Active Site
  • The area of an enzyme that binds to the substrate
  • Structure is designed to fit the molecular shape
    of the substrate
  • Therefore, each enzyme is substrate specific

32
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33
Enzyme equation
  • Enzyme Enzyme- Enzyme
  • Subtrate Sub complex Product
  • Notice Complex becomes product, but enzyme stays
    the same! Enzyme is NOT CONSUMED!

34
Models of How Enzymes Work
  • Lock and Key model
  • Induced Fit model
  • Reminder Enzymes and substrates are usually held
    together by weak chemical interactions (H/ionic
    bonds)

35
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36
Lock and Key Model
  • Substrate (key) fits to the active site (lock)
    which provides a microenvironment for the
    specific reaction

37
Induced Fit Model
  • Substrate almost fits into the active site,
    causing a strain on the chemical bonds, allowing
    the reaction

38
Enzymes
  • Usually specific to one substrate
  • Each chemical reaction in a cell requires its own
    enzyme
  • Dont change during rxn
  • Always catalyze in direction towards equilibrium

39
Four Mechanisms to Lower EA
  1. Active site is template for enzyme
  2. Enzymes may break/stretch bonds needed to be
    broken/stretched
  3. Active site is microenvironment
  4. Active site directly participates in chemical rxn

40
Factors that Affect Enzymes
  • Environment
  • Cofactors
  • Coenzymes
  • Inhibitors
  • Allosteric Sites

41
Environment
  • Factors that change protein structure will affect
    an enzyme.
  • Examples
  • pH shifts (6-8 optimal)
  • Temperature (up, inc activity)
  • Salt concentrations

42
Cofactors Coenzymes
  • Cofactors
  • Non-protein helpers for catalytic activity
  • Examples Iron, Zinc, Copper
  • Coenzymes
  • Organic molecules that affect catalytic activity
  • Examples Vitamins, Minerals, usually proteins

43
Enzyme Inhibitors
Inhibitor video
  • Competitive
  • mimic the substrate and bind to the active site
    (compete for active site)
  • Toxins/poisons Ex DDT
  • Can be used in medicine painkillers,
    antibiotics
  • Noncompetitive
  • bind to some other part of the enzyme
  • Causes active site to change shape

44
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45
Summary
  • Identify forms of energy and energy
    transformations.
  • Recognize the Laws of Thermodynamics.
  • Recognize that organisms live at the expense of
    free energy.
  • Relate free-energy to metabolism.
  • Identify exergonic and endergonic reactions.
  • Identify the structure and hydrolysis of ATP.
  • Recognize how ATP works and is coupled to
    metabolism.
  • Recognize the ATP cycle
  • Relate enzymes and activation energy.
  • Recognize factors that affect enzymes specificity
    and enzyme activity..
  • Recognize factors that control metabolism.
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