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Transcript
LECTURE PRESENTATIONS
For CAMPBELL BIOLOGY, NINTH EDITION
Jane B. Reece, Lisa A. Urry, Michael L. Cain, Steven A. Wasserman, Peter V. Minorsky, Robert B. Jackson
Lectures by
Erin Barley
Kathleen Fitzpatrick
Forms of Energy
• Energy is the capacity to cause change
• Energy exists in various forms, some of which can
perform work
Kinetic
Chemical
Energy
Forms
Heat
Potential
• Kinetic energy is energy associated with motion
• Heat (thermal energy) is kinetic energy
associated with random movement of atoms or
molecules
• Potential energy is energy that matter possesses
because of its location or structure
• Chemical energy is potential energy available
for release in a chemical reaction
• Energy can be converted from one form to another
A diver has more potential
energy on the platform
than in the water.
Climbing up converts the kinetic
energy of muscle movement
to potential energy.
Diving converts
potential energy to
kinetic energy.
A diver has less potential
energy in the water
than on the platform.
The First Law of Thermodynamics
• First law of
thermodynamics, the
energy of the universe
is constant
– Energy can be
transferred and
transformed, but it
cannot be created or
destroyed
• The first law is also
called the principle of
conservation of
energy
Chemical
energy
The Second Law of Thermodynamics
• During every energy
transfer or transformation,
some energy is unusable,
and is often lost as heat
• According to the second
law of thermodynamics
– Every energy transfer or
transformation increases
the entropy (disorder) of
the universe
Heat
(b) Second law of thermodynamics
Spontaneous processes occur without energy input; they
can happen quickly or slowly
For a process to occur without energy input, it must increase
the entropy of the universe
Metabolism and the Laws of
Thermodynamics
Metabolism is the totality
of an organism’s chemical
reactions
Catabolism:
Anabolism:
Degrade and breakdown
substances to release
energy
Building/Synthesis of
larger substances from
smaller – requires energy
Discussion Question:
• Does the evolution of more complex organisms
violate the second law of thermodynamics?
© 2011 Pearson Education, Inc.
Biological Order and Disorder
• Cells create ordered
structures from less
ordered materials
• Organisms also replace
ordered forms of matter
and energy with less
ordered forms
• Energy flows into an
ecosystem in the form of
light and exits in the form
of heat
Organization of Metabolic Pathways
• A metabolic pathway begins with a specific
molecule and ends with a product
• Each step is catalyzed by a specific enzyme
Enzyme 2
Enzyme 1
A
Reaction 1
Starting
molecule
Enzyme 3
D
C
B
Reaction 2
Reaction 3
Product
Concept 8.2: The free-energy change of a
reaction tells us whether or not the reaction
occurs spontaneously
• Biologists want to know which reactions occur
spontaneously and which require input of
energy
• To do so, they need to determine energy
changes that occur in chemical reactions
© 2011 Pearson Education, Inc.
Figure 8.5
• More free energy (higher G)
• Less stable
• Greater work capacity
In a spontaneous change
• The free energy of the system
decreases (G  0)
• The system becomes more
stable
• The released free energy can
be harnessed to do work
• Less free energy (lower G)
• More stable
• Less work capacity
(a) Gravitational motion
(b) Diffusion
(c) Chemical reaction
Free-Energy Change, G
• A living system’s free energy is energy that can do
work when temperature and pressure are uniform, as
in a living cell
Free
energy
(Instability)
∆G = ∆H – T∆S
Enthalpy
(total energy)
Entropy
Temperature (K)
• Only processes with a negative ∆G are spontaneous
• Spontaneous processes can be harnessed to perform work
Free Energy, Stability, and Equilibrium
• Free energy is a measure of a system’s
instability, its tendency to change to a more
stable state
• During a spontaneous change, free energy
decreases and the stability of a system
increases
• Equilibrium is a state of maximum stability
• A process is spontaneous and can perform
work only when it is moving toward equilibrium
© 2011 Pearson Education, Inc.
Figure 8.6a
(a) Exergonic reaction: energy released, spontaneous
Exergonic
Free energy
Reactants
Amount of
energy
released
(G  0)
Energy
Products
Progress of the reaction
Figure 8.6b
(b) Endergonic reaction: energy required, nonspontaneous
Endergonic
Free energy
Products
Amount of
energy
required
(G  0)
Energy
Reactants
Progress of the reaction
Equilibrium and Metabolism
• Reactions in a closed system eventually reach
equilibrium and then do no work
• Cells are not in equilibrium; they are open
systems experiencing a constant flow of materials
• A defining feature of life is that metabolism is
never at equilibrium
• A catabolic pathway in a cell releases free energy
in a series of reactions
• Closed and open hydroelectric systems can
serve as analogies
© 2011 Pearson Education, Inc.
Equilibrium and Metabolism
Mixing of Terms
How do catabolic/anabolic reactions relate to the idea of
endergonic/exergonic reactions?
How are cells an example of an “open system?”
Can cells every be in energy equilibrium?
G  0
G  0
Figure 8.7b
(b) An open hydroelectric
system
G  0
Figure 8.7c
G  0
G  0
G  0
(c) A multistep open hydroelectric system
Concept 8.3: ATP powers cellular work
by coupling exergonic reactions to
endergonic reactions
• A cell does three main kinds of work
– Chemical
– Transport
– Mechanical
• To do work, cells manage energy resources by
energy coupling, the use of an exergonic
process to drive an endergonic one
• Most energy coupling in cells is mediated by ATP
© 2011 Pearson Education, Inc.
ATP Structure: The Cell’s Energy Shuttle
Adenine
3 phosphate groups
Phosphate groups
Ribose
Adenine
(a) The structure of ATP
Ribose
Terminal
phosphate!
Can be
hydrolyzed
Adenosine
triphosphate
(ATP)
Energy
Inorganic
phosphate
Adenosine
diphosphate
(ADP)
Hydrolysis of ATP Performs Work
• Energy comes from the
chemical change to a state of
lower free energy, not from the
phosphate bonds themselves
• Cellular work (mechanical,
transport, and chemical) are
powered by the hydrolysis of
•Energy from the exergonic
reaction of ATP hydrolysis can
be used to drive an endergonic
reaction
•Overall, the coupled reactions
are exergonic
ATP Hydrolysis Drives Endergonic Reactions
(a) Glutamic acid
conversion
to glutamine
NH3
Glutamic
acid
(b) Conversion
reaction
coupled
with ATP
hydrolysis
NH2
Glu
Glu
GGlu = +3.4 kcal/mol
Glutamine
Ammonia
NH3
P
1
Glu
ATP
Glu
2
ADP
Glu
Phosphorylated
intermediate
Glutamic
acid
NH2
Glutamine
GGlu = +3.4 kcal/mol
(c) Free-energy
change for
coupled
reaction
NH3
Glu
GGlu = +3.4 kcal/mol
+ GATP = 7.3 kcal/mol
Net G = 3.9 kcal/mol
ATP
NH2
Glu
GATP = 7.3 kcal/mol
ADP
Pi
ADP
Pi
Transport protein
Solute
ATP
ADP
P
Pi
Pi
Solute transported
(a) Transport work: ATP phosphorylates transport proteins.
Cytoskeletal track
Vesicle
ATP
ADP
ATP
Motor protein
Protein and
vesicle moved
(b) Mechanical work: ATP binds noncovalently to motor
proteins and then is hydrolyzed.
Pi
ATP is a Renewable Energy Source
ATP
Energy from
catabolism (exergonic,
energy-releasing
processes)
ADP
H2O
Pi
Energy for cellular
work (endergonic,
energy-consuming
processes)
•The energy to phosphorylate ADP comes from other
catabolic reactions in the cell
•Energy is passed from catabolic to anabolic reactions
Enzymes Speed Up Reaction Time
Sucrase
Sucrose
(C12H22O11)
Glucose
(C6H12O6)
Fructose
(C6H12O6)
• A catalyst is a chemical agent that speeds up
a reaction without being consumed by the
reaction
• An enzyme is a catalytic protein
Figure 8.12
A
B
C
D
Free energy
Transition state
A
B
C
D
Activation Energy
(EA) is the energy
barrier needed to
start a reaction!
Comes from
surrounding heat!
EA
Reactants
A
B
G  O
C
D
Products
Progress of the reaction
Figure 8.13
Free energy
Course of
reaction
without
enzyme
EA
without
enzyme
EA with
enzyme
is lower
Reactants
G is unaffected
by enzyme
Course of
reaction
with enzyme
Products
Progress of the reaction
Animation: How Enzymes Work
Right-click slide / select “Play”
© 2011 Pearson Education, Inc.
Substrate Specificity of Enzymes
Substrate
Active site
Enzyme
(a)
Enzyme-substrate
complex
(b)
Induced fit of a substrate brings chemical groups of the
active site into positions that enhance their ability to catalyze
the reaction
Catalysis in the Enzyme’s Active Site
The active site can lower an EA barrier by
–
–
–
–
Orienting substrates correctly
Straining substrate bonds
Providing a favorable microenvironment
Covalently bonding to the substrate
1 Substrates enter active site.
2 Substrates are held
in active site by weak
interactions.
Substrates
Enzyme-substrate
complex
Active
site
Enzyme
1 Substrates enter active site.
2 Substrates are held
in active site by weak
interactions.
Substrates
Enzyme-substrate
complex
3 Active site can
lower EA and speed
up a reaction.
Active
site
Enzyme
4 Substrates are
converted to
products.
1 Substrates enter active site.
2 Substrates are held
in active site by weak
interactions.
Substrates
Enzyme-substrate
complex
3 Active site can
lower EA and speed
up a reaction.
6 Active
site is
available
for two new
substrate
molecules.
Enzyme
5 Products are
released.
4 Substrates are
converted to
products.
Products
Environment Affects Enzymes Activity
Rate of reaction
Optimal temperature for
Optimal temperature for
typical human enzyme (37°C) enzyme of thermophilic
(heat-tolerant)
bacteria (77°C)
0
20
40
60
80
Temperature (°C)
100
120
Each enzyme has an optimal temperature in which it can
function
Environment Affects Enzyme Activity
Rate of reaction
Optimal pH for pepsin
(stomach
enzyme)
0
1
2
3
4
Optimal pH for trypsin
(intestinal
enzyme)
5
pH
6
7
8
9
Each enzyme has an optimal pH in which it can function
10
Enzyme Regulation
Enzyme activity must be regulated!
To control activity enzymes can be activated or controlled.
Keep in mind:
Catabolic pathways break down substances and generate ATP
Anabolic pathways build up substances and use ATP
Catalase is an enzymes found in almost all cells.
Turns H2O2 into H2O and O2 at a rate of 40 million reactions per
second.
Enzyme Regulation: Cofactors
• Cofactors are
inorganic nonprotein
enzyme helpers (such
as a metal in ionic
form)
• An organic cofactor is
called a coenzyme
(such as vitamins)
Enzyme Regulation: Inhibitors
(a) Normal binding
(b) Competitive inhibition
(c) Noncompetitive
inhibition
Substrate
Active
site
Competitive
inhibitor
Enzyme
Noncompetitive
inhibitor
Competitive inhibitors bind to the active site of an enzyme, competing with the
substrate
Noncompetitive inhibitors bind to another part of an enzyme, causing the
enzyme to change shape and making the active site less effective
Competitive Inhibitors
Inhibitor competes with the substrate for active site!
Similar structure to substrate!
Noncompetitive (Allosteric) Inhibitors
Inhibitor binds to a secondary regulatory site which creates a
conformational change in the enzyme’s active site – making it
unavailable to the substrate!
The Evolution of Enzymes
• Enzymes are proteins encoded by genes
• Changes (mutations) in genes lead to changes
in amino acid composition of an enzyme
• Altered amino acids in enzymes may alter their
substrate specificity
• Under new environmental conditions a novel
form of an enzyme might be favored
© 2011 Pearson Education, Inc.
Two changed amino acids were
found near the active site.
Two changed amino acids
were found in the active site.
Active site
Two changed amino acids
were found on the surface.
Concept 8.5: Regulation of enzyme
activity helps control metabolism
• Chemical chaos would result if a cell’s
metabolic pathways were not tightly regulated
• A cell does this by switching on or off the
genes that encode specific enzymes or by
regulating the activity of enzymes
© 2011 Pearson Education, Inc.
Allosteric Regulation of Enzymes
• Allosteric regulation may either inhibit or
stimulate an enzyme’s activity
• Allosteric regulation occurs when a regulatory
molecule binds to a protein at one site and
affects the protein’s function at another site
© 2011 Pearson Education, Inc.
Active form
Inactive form
Oscillates
between 2 forms
Figure 8.19a
(a) Allosteric activators and inhibitors
Allosteric enzyme
with four subunits
Active site
(one of four)
Regulatory site
(one of four)
Activator
Active form
Stabilized active form
Oscillation
Nonfunctional
active site
Inactive form
Inhibitor
Stabilized inactive form
Cooperativity
Substrate
Inactive form
Stabilized active
form
One substrate molecule primes an enzyme to act on
additional substrate molecules more readily
Identification of Allosteric Regulators
• Allosteric
regulators are
attractive drug
candidates for
enzyme
regulation
because of their
specificity
Example:
Finding
Allosteric
Inhibitors
Caspases are
proteolytic
enzymes
connected to
inflammation
Inhibition of
proteolytic
enzymes called
caspases may
help management
of inappropriate
inflammatory
responses
Active
site
Substrate
Caspase 1
SH
SH
Known active form
Active form can
bind substrate
Known inactive form
SH
Allosteric
binding site
Allosteric
inhibitor
Hypothesis: allosteric
inhibitor locks enzyme
in inactive form
Allosteric Regulators can be used to
Control Enzyme Activity!
RESULTS
Caspase 1
Inhibitor
Active form
Allosterically
inhibited form
Inactive form
Allosteric inhibited for looks like inactive form!
Feedback Inhibition
• In feedback
inhibition, the end
product of a metabolic
pathway shuts down
the pathway
• Prevents a cell from
wasting chemical
resources by
synthesizing more
product than is
needed
Feedback
Inhibition for
Isoleucine
Active site
available
Isoleucine
used up by
cell
Active site of
Feedback
enzyme 1 is
inhibition
no longer able
to catalyze the
conversion
of threonine to
intermediate A;
pathway is
switched off. Isoleucine
binds to
allosteric
site.
Initial
substrate
(threonine)
Threonine
in active site
Enzyme 1
(threonine
deaminase)
Intermediate A
Enzyme 2
Intermediate B
Enzyme 3
Intermediate C
Enzyme 4
Intermediate D
Enzyme 5
End product
(isoleucine)
Specific Localization of Enzymes
Within the Cell
• In eukaryotic cells, some enzymes reside in
specific organelles; for example, enzymes for
cellular respiration are located in mitochondria
Enzyme
Location
Mitochondria
Structures within
the cell help bring
order to metabolic
pathways
Some enzymes act
as structural
components of
membranes or
reside in specific
organelles
The matrix contains
enzymes in solution that
are involved in one stage
of cellular respiration.
Enzymes for another
stage of cellular
respiration are
embedded in the
inner membrane.
1 m
Figure 8.UN03
Free energy
Course of
reaction
without
enzyme
EA
without
enzyme
EA with
enzyme
is lower
Reactants
G is unaffected
by enzyme
Course of
reaction
with enzyme
Products
Progress of the reaction
Figure 8.UN04
Figure 8.UN05
Figure 8.UN06
Figure 8.UN07