Chapter 4 Cellular Metabolism

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Chapter 4 Cellular Metabolism

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Title: Chapter 4 Cellular Metabolism

1
Chapter 4 Cellular Metabolism
2
Cells and the Flow of Energy

Energy is the ability to do work.
Living things need to acquire energy this is a
characteristic of life.
Cells use acquired energy to
Maintain their organization
Carry out reactions that allow cells to develop,
grow, and reproduce

3
Forms of Energy

There are two basic forms of energy.
Kinetic energy is the energy of motion.
Potential energy is stored energy.
Food eaten has potential energy because it can be
converted into kinetic energy.
Potential energy in foods is chemical energy.
Organisms can convert chemical energy into a form
of kinetic energy called mechanical energy for
motion.

4
Two Laws of Thermodynamics

The flow of energy in ecosystems occurs in one
direction energy does not cycle.
The two laws of thermodynamics explain this
phenomenon.
First Law Energy cannot be created or destroyed,
but it can be changed from one form to another.
Second Law Energy cannot be changed from one
form to another without loss of usable energy.

5
Flow of energy
6

Energy exists in several different forms.
When energy transformations occur, energy is
neither created nor destroyed but there is always
loss of usable energy, usually as heat.
For this reason, living things depend on an
outside source of energy.
The ultimate source of energy for ecosystems is
the sun, and this energy is passed from plants to
animals.

7
Cells and Entropy

The term entropy is used to indicate the relative
state of disorganization.
Cells need a constant supply of energy to
maintain their internal organization.
Complex molecules like glucose tend to break
apart into their building blocks, in this case
carbon dioxide and water.
This is because glucose is more organized, and
thus less stable, than its breakdown products.
The result is a loss of potential energy and an
increase in entropy.

8
Cells and entropy
9
Metabolic Reactions and Energy Transformations

Metabolism is the sum of all the chemical
reactions that occur in a cell.
Reactants are substances that participate in a
reaction products are substances that form as a
result of a reaction.
A reaction will occur spontaneously if it
increases entropy.
Biologists use the term free energy instead of
entropy for cells.

Free energy, G, is the amount of energy to do
work after a reaction has occurred.
?G (change in free energy) is calculated by
subtracting the free energy of reactants from
that of products.
A negative ?G means the products have less free
energy than the reactants, and the reaction will
occur spontaneously.

Exergonic reactions have a negative ?G and energy
is released.
Endergonic reactions have a positive ?G and occur
only if there is an input of energy.
Energy released from exergonic reactions is used
to drive endergonic reactions inside cells.
ATP is the energy carrier between exergonic and
endergonic reactions.

12
ATP Energy for Cells

ATP (adenosine triphosphate) is the energy
currency of cells.
ATP is constantly regenerated from ADP (adenosine
diphosphate) after energy is expended by the
cell.
Use of ATP by the cell has advantages
1) It can be used in many types of reactions.
2) When ATP ? ADP P, energy released is
sufficient for cellular needs and little energy
is wasted.

3) ATP is coupled to endergonic reactions in such
a way that it minimizes energy loss.
ATP is a nucleotide made of adenine and ribose
and three phosphate groups.
ATP is called a high-energy compound because a
phosphate group is easily removed.

14
The ATP cycle
15
Coupled Reactions

In coupled reactions, energy released by an
exergonic reaction drives an endergonic reaction.

16
Coupled reactions
17
Function of ATP

Cells make use of ATP for
Chemical work ATP supplies energy to synthesize
macromolecules, and therefore the organism
Transport work ATP supplies energy needed to
pump substances across the plasma membrane
Mechanical work ATP supplies energy for
cellular movements

18
Two types of metabolic reactions

Anabolism
larger molecules are made
requires energy

Catabolism
larger molecules are broken down
releases energy

4-2
19
Anabolism
Anabolism provides the substances needed for
cellular growth and repair

Dehydration synthesis
type of anabolic process
used to make polysaccharides, triglycerides, and
proteins
produces water

4-3
20
Anabolism
4-4
21
Catabolism
Catabolism breaks down larger molecules into
smaller ones

Hydrolysis
a catabolic process
used to decompose carbohydrates, lipids, and
proteins
water is used
reverse of dehydration synthesis

4-5
22
Catabolism
4-6
23
Metabolic Pathways and Enzymes

Cellular reactions are usually part of a
metabolic pathway, a series of linked reactions,
illustrated as follows
E1 E2 E3 E4 E5
E6 A ? B ? C ? D ? E ? F ?
G
Here, the letters A-F are reactants or
substrates, B-G are the products in the various
reactions, and E1-E6 are enzymes.

An enzyme is a protein molecule that functions as
an organic catalyst to speed a chemical reaction.
An enzyme brings together particular molecules
and causes them to react.
The reactants in an enzymatic reaction are called
the substrates for that enzyme.

25
Energy of Activation

The energy that must be added to cause molecules
to react with one another is called the energy of
activation (Ea).
The addition of an enzyme does not change the
free energy of the reaction, rather an enzyme
lowers the energy of activation.

26
Energy of activation (Ea)
27
Enzyme-Substrate Complexes

Every reaction in a cell requires a specific
enzyme.
Enzymes are named for their substrates
Substrate Enzyme
Lipid Lipase
Urea Urease
Maltose Maltase
Ribonucleic acid Ribonuclease

Only one small part of an enzyme, called the
active site, complexes with the substrate(s).
The active site may undergo a slight change in
shape, called induced fit, in order to
accommodate the substrate(s).
The enzyme and substrate form an enzyme-substrate
complex during the reaction.
The enzyme is not changed by the reaction, and it
is free to act again.

29
Control of Metabolic Reactions
Enzymes

control rates of metabolic reactions

lower activation energy needed to start reactions

globular proteins with specific shapes

not consumed in chemical reactions

substrate specific

shape of active site determines substrate

4-7
30
Control of Metabolic Reactions

Metabolic pathways
series of enzyme-controlled reactions leading to
formation of a product
each new substrate is the product of the
previous reaction

Enzyme names commonly
reflect the substrate
have the suffix ase
sucrase, lactase, protease, lipase

4-8
31
Control of Metabolic Reactions

Coenzymes
organic molecules that act as cofactors
vitamins

Cofactors
make some enzymes active
ions or coenzymes

Factors that alter enzymes
heat
radiation
electricity
chemicals
changes in pH

4-9
32
Energy for Metabolic Reactions

Energy
ability to do work or change something
heat, light, sound, electricity, mechanical
energy, chemical energy
changed from one form to another
involved in all metabolic reactions

Release of chemical energy
most metabolic processes depend on chemical
energy
oxidation of glucose generates chemical energy
cellular respiration releases chemical energy
from molecules and makes it available for
cellular use

4-10
33
Enzymatic reaction
34
Induced fit model
35
Factors Affecting Enzymatic Speed

Enzymatic reactions proceed with great speed
provided there is enough substrate to fill active
sites most of the time.
Enzyme activity increases as substrate
concentration increases because there are more
collisions between substrate molecules and the
enzyme.

36
Temperature and pH

As the temperature rises, enzyme activity
increases because more collisions occur between
enzyme and substrate.
If the temperature is too high, enzyme activity
levels out and then declines rapidly because the
enzyme is denatured.
Each enzyme has an optimal pH at which the rate
of reaction is highest.

37
Rate of an enzymatic reaction as a function of
temperature and pH
38

A cell regulates which enzymes are present or
active at any one time.
Genes must be turned on or off to regulate the
quantity of enzyme present.
Another way to control enzyme activity is to
activate or deactivate the enzyme.
Phosphorylation is one way to activate an enzyme.

39
Enzyme Inhibition

Enzyme inhibition occurs when an active enzyme is
prevented from combining with its substrate.
When the product of a metabolic pathway is in
abundance, it binds competitively with the
enzymes active site, a simple form of feedback
inhibition.
Other metabolic pathways are regulated by the end
product binding to an allosteric site on the
enzyme.

40
Feedback inhibition
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43
Enzyme Cofactors

Presence of enzyme cofactors may be necessary for
some enzymes to carry out their functions.
Inorganic metal ions, such as copper, zinc, or
iron function as cofactors for certain enzymes.
Organic molecules, termed coenzymes, must be
present for other enzymes to function.
Some coenzymes are vitamins.

44
Oxidation-Reduction and the Flow of Energy

Oxidation is the loss of electrons and reduction
is the gain of electrons.
Because oxidation and reduction occur
simultaneously in a reaction, such a reaction is
called a redox reaction.
Oxidation also refers to the loss of hydrogen
atoms, and reduction refers to the gain of
hydrogen atoms in covalent reactions in cells.

These types of oxidation-reduction, or redox,
reactions are exemplified by the overall
reactions of photosynthesis and cellular
respiration.
The two pathways of photosynthesis and cellular
respiration permit the flow of energy from the
sun though all living things.

46
Cellular Respiration

The overall equation for cellular respiration is
opposite that of photosynthesis
C6H12O6 6O2 ? 6CO2 6H2O Energy
In this reaction, glucose is oxidized and oxygen
is reduced to become water.
The complete oxidation of a mol of glucose
releases 686 kcal of energy that is used to
synthesize ATP.

47
Chapter Summary

Two laws of thermodynamics state that energy
cannot be created or destroyed, and energy
transformations result in a loss of energy,
usually as heat.
As a result of these laws, we know the entropy of
the universe is ever increasing, and that it
takes energy to maintain the organization of
living things.

Metabolism refers to all the chemical reactions
in the cell.
Only reactions with a negative free energy occur
spontaneously.
Endergonic reactions are thus coupled with
exergonic reactions.
Energy is stored in cells in ATP molecules.
Metabolic pathways are a series of
enzyme-catalyzed reactions.

Each reaction requires a specific enzyme.
Substrate concentration, temperature, pH, and
enzyme concentration affect the rates of
reactions.
Most metabolic pathways are regulated by feedback
inhibition.
Cellular respiration involves oxidation-reduction
reactions and accounts for the flow of energy
through all living things.

50
Cellular Respiration

Occurs in three series of reactions
Glycolysis
Citric acid cycle
Electron transport chain

Produces
carbon dioxide
water
ATP (chemical energy)
heat

Includes
anaerobic reactions (without O2) - produce
little ATP
aerobic reactions (requires O2) - produce most
ATP

4-11
51
Overview of Cellular Respiration

Cellular respiration is the step-wise release of
energy from carbohydrates and other molecules
energy from these reactions is used to synthesize
ATP molecules.
This is an aerobic process that requires oxygen
(O2) and gives off carbon dioxide (CO2), and
involves the complete breakdown of glucose to
carbon dioxide and water.

The oxidation of glucose is an exergonic reaction
(releases energy) which drives ATP synthesis,
which is an endergonic reaction (energy is
required).
The overall equation for cellular respiration
shows the coupling of glucose breakdown to ATP
buildup.
The breakdown of one glucose molecule results in
a maximum of 36 to 38 ATP molecules, representing
about 40 of the potential energy within the
glucose molecule.

53
ATP Molecules

each ATP molecule has three parts
an adenine molecule
a ribose molecule
three phosphate molecules in a chain

third phosphate attached by high-energy bond

when the bond is broken, energy is transferred

when the bond is broken, ATP becomes ADP

ADP becomes ATP through phosphorylation

phosphorylation requires energy released from
cellular respiration

4-12
54
Cellular respiration
55
Phases of Complete Glucose Breakdown

The oxidation of glucose by removal of hydrogen
atoms involves four phases
Glycolysis the breakdown of glucose to two
molecules of pyruvate in the cytoplasm with no
oxygen needed yields 2 ATP
Transition reaction pyruvate is oxidized to a
2-carbon acetyl group carried by CoA, and CO2 is
removed occurs twice per glucose molecule

Citric acid cycle a cyclical series of
oxidation reactions that give off CO2 and produce
one ATP per cycle occurs twice per glucose
molecule
Electron transport system a series of carriers
that accept electrons removed from glucose and
pass them from one carrier to the next until the
final receptor, O2 is reached water is produced
energy is released and used to synthesize 32 to
34 ATP
If oxygen is not available, fermentation occurs
in the cytoplasm instead of proceeding to
cellular respiration.

57
Outside the Mitochondria Glycolysis

Glycolysis occurs in the cytoplasm and is the
breakdown of glucose to two pyruvate molecules.
Glycolysis is universally found in all organisms
and likely evolved before the citric acid cycle
and electron transport system.
Glycolysis does not require oxygen.

58
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59
Glycolysis

series of ten reactions
breaks down glucose into 2 pyruvic acids
occurs in cytosol
anaerobic phase of cellular respiration
yields two ATP molecules per glucose

Summarized by three main events
phosphorylation
splitting
production of NADH and ATP

4-13
60
Energy-Investment Steps

As glycolysis begins, two ATP are used to
activate glucose, a 6-carbon molecule that splits
into two C3 molecules known as PGAL.
PGAL carries a phosphate group from ATP.
From this point on, each C3 molecule undergoes
the same series of reactions.

61
Glycolysis

Event 1 - Phosphorylation
two phosphates added to glucose
requires ATP

Event 2 Splitting (cleavage)
6-carbon glucose split into two 3-carbon
molecules

4-14
62
Energy-Harvesting Steps

Oxidation of PGAL now occurs by the removal of
electrons that are accompanied by hydrogen ions,
both picked up by the coenzyme NAD
2 NAD 4H ? 2 NADH 2 H
The oxidation of PGAL and subsequent substrates
results in four high-energy phosphate groups used
to synthesize ATP in substrate-level
phosphorylation.

63
Glycolysis

Event 3 Production of NADH and ATP
hydrogen atoms are released
hydrogen atoms bind to NAD to produce NADH
NADH delivers hydrogen atoms to electron
transport chain if oxygen is available
ADP is phosphorylated to become ATP
two molecules of pyruvic acid are produced

4-15
64
Glycolysis Summary

Inputs
Glucose
2 NAD
2 ATP
4 ADP 2 P

Outputs
2 pyruvate
2 NADH
2 ADP
2 ATP (net gain)

65
Anaerobic Reactions

If oxygen is not available -
electron transport chain cannot accept NADH
pyruvic acid is converted to lactic acid
glycolysis is inhibited
ATP production declines

4-16
66
Aerobic Reactions

If oxygen is available
pyruvic acid is used to produce acetyl CoA
citric acid cycle begins
electron transport chain functions
carbon dioxide and water are formed
36 molecules of ATP produced per glucose molecule

4-17
67
Inside the Mitochondria

A mitochondrion is a cellular organelle that has
a double membrane, with an intermembrane space
between the two layers.
Cristae are folds of inner membrane that jut out
into the matrix, the innermost compartment, which
is filled with a gel-like fluid.
The transition reaction and citic acid cycle
occur in the matrix the electron transport
system is located in the cristae.

68
Transition Reaction

The transition reaction connects glycolysis to
the citric acid cycle, and is thus the transition
between these two pathways.
Pyruvate is converted to a C2 acetyl group
attached to coenzyme A (CoA), and CO2 is
released.
During this oxidation reaction, NAD is converted
to NADH H the transition reaction occurs
twice per glucose molecule.

69
Citric Acid Cycle

The citric acid cycle is a cyclical metabolic
pathway located in the matrix of the
mitochondria.
At the start of the citric acid cycle, CoA
carries the C2 acetyl group to join a C4
molecule, and C6 citrate results.
Each acetyl group received from the transition
reaction is oxidized to 2 CO2 molecules.

During the cycle, oxidation occurs when NAD
accepts electrons in three sites and FAD accepts
electrons once.
Substrate-level phosphorylation results in a gain
of one ATP per every turn of the cycle it turns
twice per glucose.
During the citric acid cycle, the six carbon
atoms in glucose become CO2.
The transition reaction produces two CO2, and the
citric acid cycle produces four CO2 per molecule
of glucose.

71
Citric Acid Cycle

begins when acetyl CoA combines with oxaloacetic
acid to produce citric acid
citric acid is changed into oxaloacetic acid
through a series of reactions
cycle repeats as long as pyruvic acid and oxygen
are available

for each citric acid molecule
one ATP is produced
eight hydrogen atoms are transferred to NAD and
FAD
two CO2 produced

4-18
72
Citric acid cycle
73
Citric acid cycle inputs and outputs per glucose
molecule

Inputs
2 acetyl groups
6 NAD
2 FAD
2 ADP 2 P

Outputs
4 CO2
6 NADH
2 FADH2
2 ATP

74
Electron Transport System

The electron transport system located in the
cristae of mitochondria is a series of protein
carriers, that pass electrons from one to the
other.
Electrons carried by NADH and FADH2 enter the
electron transport system.
As a pair of electrons is passed from carrier to
carrier, energy is released and is used to form
ATP molecules by oxidative phosphorylation.

Oxygen receives energy-spent electrons at the end
of the electron transport system.
Next, oxygen combines with hydrogen, and water
forms
½ O2 2 e- 2 H ? H2O
When NADH carries electrons to the first carrier,
enough energy is released by the time electrons
are accepted by O2 to produce three ATP two ATP
are produced when FADH2 delivers electrons to the
carriers.

76
Overview of the electron transport system
77
Organization of Cristae

The electron transport system is located in the
cristae of the mitochondria and consists of three
protein complexes and two mobile carriers.
The mobile carriers transport electrons between
the complexes, which also contain electron
carriers.
The carriers use the energy released by electrons
as they move down the carriers to pump H from
the matrix into the intermembrane space of the
mitochondrion.

A very strong electrochemical gradient is
established with few H in the matrix and many in
the intermembrane space.
The cristae also contain an ATP synthase complex
through which hydrogen ions flow down their
gradient from the intermembrane space into the
matrix.
The flow of three H through an ATP synthase
complex causes a conformational change, which
causes the ATP synthase to synthesize ATP from
ADP P.

Mitochondria produce ATP by chemiosmosis, so
called because ATP production is tied to an
electrochemical gradient, namely an H gradient.
Once formed, ATP molecules are transported out of
the mitochondrial matrix.

80
Organization of cristae
81
Electron Transport Chain

NADH and FADH2 carry electrons to the ETC
ETC series of electron carriers located in
cristae of mitochondria
energy from electrons transferred to ATP
synthase
ATP synthase catalyzes the phosphorylation of
ADP to ATP
water is formed

4-19
82
Energy Yield from Glucose Metabolism

Per glucose molecule, there is a net gain of two
ATP from glycolysis, which occurs in the
cytoplasm by substrate-level phosphorylation.
The citric acid cycle, occurring in the matrix of
mitochondria, adds two more ATP, also by
substrate-level phosphorylation.

Most ATP is produced by the electron transport
system and chemiosmosis.
Per glucose molecule, ten NADH and two FADH2 take
electrons to the electron transport system three
ATP are formed per NADH and two ATP per FADH2.
Electrons carried by NADH produced during
glycolysis are shuttled to the electron transport
chain by an organic molecule.

84
Accounting of energy yield per glucose molecule
breakdown
85
Summary of Cellular Respiration
4-20
86
Summary of Catabolism of Proteins, Carbohydrates,
and Fats
4-21
87
Carbohydrate Storage

Excess glucose stored as
glycogen (primarily by liver and muscle cells)
fat
converted to amino acids

4-22
88
Nucleic Acids and Protein Synthesis
Genetic information instructs cells how to
construct proteins stored in DNA
Gene segment of DNA that codes for one protein
Genome complete set of genes
Genetic Code method used to translate a
sequence of nucleotides of DNA into a sequence of
amino acids
4-24
89
DNA Structure and Replication

In the mid-1900s, scientists knew that
chromosomes, made up of DNA (deoxyribonucleic
acid) and proteins, contained genetic
information.
However, they did not know whether the DNA or the
proteins was the actual genetic material.

90
Structure of DNA

The structure of DNA was determined by James
Watson and Francis Crick in the early 1950s.
DNA is a polynucleotide nucleotides are composed
of a phosphate, a sugar, and a nitrogen-containing
base.
DNA has the sugar deoxyribose and four different
bases adenine (A), thymine (T), guanine (G), and
cytosine (C).

91
One pair of bases
92

Watson and Crick showed that DNA is a double
helix in which A is paired with T and G is paired
with C.
This is called complementary base pairing because
a purine is always paired with a pyrimidine.

When the DNA double helix unwinds, it resembles a
ladder.
The sides of the ladder are the sugar-phosphate
backbones, and the rungs of the ladder are the
complementary paired bases.
The two DNA strands are anti-parallel they run
in opposite directions.

94
DNA double helix
95
Replication of DNA

DNA replication occurs during chromosome
duplication an exact copy of the DNA is produced
with the aid of DNA polymerase.
Hydrogen bonds between bases break and enzymes
unzip the molecule.
Each old strand of nucleotides serves as a
template for each new strand.

New nucleotides move into complementary positions
are joined by DNA polymerase.
The process is semiconservative because each new
double helix is composed of an old strand of
nucleotides from the parent molecule and one
newly-formed strand.
Some cancer treatments are aimed at stopping DNA
replication in rapidly-dividing cancer cells.

97
Ladder configuration and DNA replication
98
Gene Expression

A gene is a segment of DNA that specifies the
amino acid sequence of a protein.
Gene expression occurs when gene activity leads
to a protein product in the cell.
A gene does not directly control protein
synthesis instead, it passes its genetic
information on to RNA, which is more directly
involved in protein synthesis.

99
RNA

RNA (ribonucleic acid) is a single-stranded
nucleic acid in which A pairs with U (uracil)
while G pairs with C.
Three types of RNA are involved in gene
expression messenger RNA (mRNA) carries genetic
information to the ribosomes, ribosomal RNA
(rRNA) is found in the ribosomes, and transfer
RNA (tRNA) transfers amino acids to the
ribosomes, where the protein product is
synthesized.

100
Structure of RNA
101

Two processes are involved in the synthesis of
proteins in the cell
Transcription makes an RNA molecule complementary
to a portion of DNA.
Translation occurs when the sequence of bases of
mRNA directs the sequence of amino acids in a
polypeptide.

102
The Genetic Code

DNA specifies the synthesis of proteins because
it contains a triplet code every three bases
stand for one amino acid.
Each three-letter unit of an mRNA molecule is
called a codon.
Most amino acids have more than one codon there
are 20 amino acids with a possible 64 different
triplets.
The code is nearly universal among living
organisms.

103
Messenger RNA codons
104
Central Concept

The central concept of genetics involves the
DNA-to-protein sequence involving transcription
and translation.
DNA has a sequence of bases that is transcribed
into a sequence of bases in mRNA.
Every three bases is a codon that stands for a
particular amino acid.

105
Transcription

During transcription in the nucleus, a segment
of DNA unwinds and unzips, and the DNA serves as
a template for mRNA formation.
RNA polymerase joins the RNA nucleotides so that
the codons in mRNA are complementary to the
triplet code in DNA.

106
Transcription and mRNA synthesis
107
Processing of mRNA

DNA contains exons and introns.
Before mRNA leaves the nucleus, it is processed
and the introns are excised so that only the
exons are expressed.
The splicing of mRNA is done by ribozymes,
organic catalysts composed of RNA, not protein.
Primary mRNA is processed into mature mRNA.

108
Function of introns
109
Translation

Translation is the second step by which gene
expression leads to protein synthesis.
During translation, the sequence of codons in
mRNA specifies the order of amino acids in a
protein.
Translation requires several enzymes and two
other types of RNA transfer RNA and ribosomal
RNA.

110
Transfer RNA

During translation, transfer RNA (tRNA) molecules
attach to their own particular amino acid and
travel to a ribosome.
Through complementary base pairing between
anticodons of tRNA and codons of mRNA, the
sequence of tRNAs and their amino acids form the
sequence of the polypeptide.

111
Transfer RNA amino acid carrier
112
Ribosomal RNA

Ribosomal RNA, also called structural RNA, is
made in the nucleolus.
Proteins made in the cytoplasm move into the
nucleus and join with ribosomal RNA to form the
subunits of ribosomes.
A large subunit and small subunit of a ribosome
leave the nucleus and join in the cytoplasm to
form a ribosome just prior to protein synthesis.

113

A ribosome has a binding site for mRNA as well as
binding sites for two tRNA molecules at a time.
As the ribosome moves down the mRNA molecule, new
tRNAs arrive, and a polypeptide forms and grows
longer.
Translation terminates once the polypeptide is
fully formed the ribosome separates into two
subunits and falls off the mRNA.
Several ribosomes may attach and translate the
same mRNA, therefore the name polyribosome.

114
Polyribosome structure and function
115
Translation Requires Three Steps

During translation, the codons of an mRNA
base-pair with tRNA anticodons.
Protein translation requires these steps
Chain initiation
Chain elongation
Chain termination.
Enzymes are required for each step, and the first
two steps require energy.

116
Chain Initiation

During chain initiation, a small ribosomal
subunit, the mRNA, an initiator tRNA, and a large
ribosomal unit bind together.
First, a small ribosomal subunit attaches to the
mRNA near the start codon.
The anticodon of tRNA, called the initiator RNA,
pairs with this codon.
Then the large ribosomal subunit joins.

117
Initiation
118
Chain Elongation

During chain elongation, the initiator tRNA
passes its amino acid to a tRNA-amino acid
complex that has come to the second binding site.
The ribosome moves forward and the tRNA at the
second binding site is now at the first site, a
sequence called translocation.
The previous tRNA leaves the ribosome and picks
up another amino acid before returning.

119
Elongation
120
Chain Termination

Chain termination occurs when a stop-codon
sequence is reached.
The polypeptide is enzymatically cleaved from the
last tRNA by a release factor, and the ribosome
falls away from the mRNA molecule.
A newly synthesized polypeptide may function
along or become part of a protein.

121
Termination
122
Review of Gene Expression

DNA in the nucleus contains a triplet code each
group of three bases stands for one amino acid.
During transcription, an mRNA copy of the DNA
template is made.
The mRNA is processed before leaving the nucleus.
The mRNA joins with a ribosome, where tRNA
carries the amino acids into position during
translation.

123
Gene Mutations

A gene mutation is a change in the sequence of
bases within a gene.
Frameshift Mutations
Frameshift mutations involve the addition or
removal of a base during the formation of mRNA
these change the genetic message by shifting the
reading frame.

124
Point Mutations

The change of just one nucleotide causing a codon
change can cause the wrong amino acid to be
inserted in a polypeptide this is a point
mutation.
In a silent mutation, the change in the codon
results in the same amino acid.

125

If a codon is changed to a stop codon, the
resulting protein may be too short to function
this is a nonsense mutation.
If a point mutation involves the substitution of
a different amino acid, the result may be a
protein that cannot reach its final shape this
is a missense mutation.
An example is Hbs which causes sickle-cell
disease.

126
Sickle-cell disease in humans
127
Cause and Repair of Mutations

Mutations can be spontaneous or caused by
environmental influences called mutagens.
Mutagens include radiation (X-rays, UV
radiation), and organic chemicals (in cigarette
smoke and pesticides).
DNA polymerase proof reads the new strand against
the old strand and detects mismatched pairs,
reducing mistakes to one in a billion nucleotide
pairs replicated.

128
Transposons Jumping Genes

Transposons are specific DNA sequences that move
from place to place within and between
chromosomes.
These so-called jumping genes can cause a
mutation to occur by altering gene expression.
It is likely all organisms, including humans,
have transposons.

129
Cancer A Failure of Genetic Control

Cancer is a genetic disorder resulting in a
tumor, an abnormal mass of cells.
Carcinogenesis, the development of cancer, is a
gradual process.
Cancer cells lack differentiation, form tumors,
undergo angiogenesis and metastasize.
Cancer cells fail to undergo apoptosis, or
programmed cell death.

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Structure of DNA

two polynucleotide chains
hydrogen bonds hold nitrogenous bases together
bases pair specifically (A-T and C-G)
forms a helix
DNA wrapped about histones forms chromosomes

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RNA Molecules

Messenger RNA (mRNA) -
delivers genetic information from nucleus to the
cytoplasm
single polynucleotide chain
formed beside a strand of DNA
RNA nucleotides are complementary to DNA
nucleotides (exception no thymine in RNA
replaced with uracil)
making of mRNA is transcription

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RNA Molecules