1. Regulation of Gene Expression Chapter 18

4. Gene expression Flow of genetic information Genotype to phenotype
Genes to proteins
Proteins not made at random
Specific purposes
Appropriate times

5. Control of gene expression
Selective expression of genes
All genes are not expressed at the same time
Expressed at different times

6. Prokaryote regulation

7. Control of gene expression
Regulate at transcription
Gene expression responds to
Environmental conditions
Type of nutrients
Amounts of nutrients
Rapid turn over of proteins

8. (a) Regulation of enzyme activity (b) Regulation of enzyme production
Fig. 18-2
Precursor
Feedback
inhibition
trpE gene
Enzyme 1
trpD gene
Regulation
of gene
expression
Enzyme 2
trpC gene
trpB gene
Enzyme 3
trpA gene
Tryptophan
(a) Regulation of enzyme
activity
(b) Regulation of enzyme
production

9. Prokaryote Anabolism: Building up of a substance Catabolism:
Breaking apart a substance

10. Prokaryote Operon Section of DNA Enzyme-coding genes Promoter Operator
Sequence of nucleotides
Overlaps promoter site
Controls RNA polymerase access to the promoter

12. Prokaryote Multiple genes are expressed in a single gene expression
trp operon
Trytophan
Synthesis
Lac operon
Lactose
Degradation

13. Prokaryote trp Operon: Control system to make tryptophan
Several genes that make tryptophan
Regulatory region

14. Polypeptide subunits that make up enzymes for tryptophan synthesis
Fig. 18-3a
trp operon
Promoter
Genes of operon
trpE
trpD
trpC
trpB
trpA
Operator
Start codon
Stop codon
mRNA 5
mRNA
RNA
polymerase 5 E D C B A
Polypeptide subunits that make up
enzymes for tryptophan synthesis

15. Prokaryote ⇧tryptophan present Bacteria will not make tryptophan
Genes are not transcribed
Enzymes will not be made
Repression

16. Prokaryote Repressors Proteins Bind regulatory sites (operator)
Prevent RNA polymerase attaching to promoter
Prevent or decrease the initiation of transcription

17. Prokaryote Repressors Allosteric proteins Changes shape
Active or inactive

18. Prokaryote ⇧tryptophan Tryptophan binds the trp repressor
Repressor changes shape
Active shape
Repressor fits DNA better
Stops transcription
Tryptophan is a corepressor

19. (b) Tryptophan present, repressor active, operon off
Fig. 18-3b-2
DNA
No RNA made
mRNA
Protein
Active
repressor
Tryptophan
(corepressor)
(b) Tryptophan present, repressor active, operon off

21. Prokaryote ⇩tryptophan Nothing binds the repressor Inactive shape
RNA polymerase can transcribe

22. Polypeptide subunits that make up enzymes for tryptophan synthesis
Fig. 18-3a
trp operon
Promoter
Promoter
Genes of operon
DNA
trpR
trpE
trpD
trpC
trpB
trpA
Regulatory
gene
Operator
Start codon
Stop codon 3
mRNA 5
mRNA
RNA
polymerase 5 E D C B A
Protein
Inactive
repressor
Polypeptide subunits that make up
enzymes for tryptophan synthesis
(a) Tryptophan absent, repressor inactive, operon on

24. Prokaryote Lactose Sugar used for energy
Enzymes needed to break it down
Lactose present
Enzymes are synthesized
Induced

25. Prokaryote lac Operon Promoter Operator Genes to code for enzymes
Metabolize (break down) lactose

26. Prokaryote Lactose is present Repressor released Genes expressed
Lactose absent
Repressor binds DNA
Stops transcription

28. Prokaryote Allolactose: Binds repressor Repressor releases from DNA
Inducer
Transcription begins
Lactose levels fall
Allolactose released from repressor
Repressor binds DNA blocks transcription

29. (b) Lactose present, repressor inactive, operon on
Fig. 18-4b
lac operon
DNA
lacI
lacZ
lacY
lacA
RNA
polymerase 3
mRNA
mRNA 5 5
-Galactosidase
Permease
Transacetylase
Protein
Allolactose
(inducer)
Inactive
repressor
(b) Lactose present, repressor inactive, operon on

30. (a) Lactose absent, repressor active, operon off
Fig. 18-4a
Regulatory
gene
Promoter
Operator
DNA
lacI
lacZ No
RNA
made 3
mRNA
RNA
polymerase 5
Active
repressor
Protein
(a) Lactose absent, repressor active, operon off

33. Prokaryote Lactose & tryptophan metabolism Adjustment by bacteria
Regulates protein synthesis
Response to environment
Negative control of genes
Operons turned off by active repressors
Tryptophan repressible operon
Lactose inducible operon

34. Prokaryote

35. Prokaryote Activators: Bind DNA Stimulate transcription
Involved in glucose metabolism
lac operon

36. Prokaryote Activator: Catabolite activator protein (CAP)
Stimulates transcription of operons
Code for enzymes to metabolize sugars
cAMP helps CAP
cAMP binds CAP to activate it
CAP binds to DNA (lac Operon)

37. Prokaryote Glucose elevated cAMP low cAMP not available to bind CAP
Does not stimulate transcription
Bacteria use glucose
Preferred sugar over others.

39. Prokaryote lac operon Regulated by positive & negative control
Low lactose
Repressor blocks transcription
High lactose
Allolactose binds repressor
Transcription happens

40. Prokaryote lac operon Glucose also present CAP unable to bind
Transcription will proceed slowly
Glucose absent
CAP binds promoter
Transcription goes quickly

42. Eukaryote gene expression
All cells in an organism have the same genes
Some genes turned on
Others remain off
Leads to development of specialized cells
Cellular differentiation

43. Eukaryote gene expression
Gene expression assists in regulating development
Homeostasis
Changes in gene expression in one cell helps entire organism

44. Control of gene expression
Chromosome structure
Transcriptional control
Posttranscriptional control

45. Fig. 18-6 Signal NUCLEUS Chromatin Chromatin modification DNA
Gene available
for transcription
Gene
Transcription
RNA
Exon
Primary transcript
Intron
RNA processing
Tail
Cap
mRNA in nucleus
Transport to cytoplasm
CYTOPLASM
mRNA in cytoplasm
Degradation
of mRNA
Translation
Polypeptide
Protein processing
Active protein
Degradation
of protein
Transport to cellular
destination
Cellular function

46. Eukaryotes 1. DNA is organized into chromatin
2. Transcription occurs in nucleus
3. Each gene has its own promoter

48. Chromatin structure DNA is tightly packaged Heterochromatin:
Tightly packed
Euchromatin:
Less tightly packed
Influences gene expression
Promoter location
Modification of histones

49. Chromatin structure Histone acetylation Acetyl groups (-COCH3)
Attach to Lysines in histone tails
Loosen packing
Histone methylation
Methyl groups (-CH3)
Tightens packing

50. (a) Histone tails protrude outward from a nucleosome
Fig. 18-7
Histone
tails
Amino
acids
available
for chemical
modification
DNA
double helix
(a) Histone tails protrude outward from a
nucleosome
Unacetylated histones
Acetylated histones
(b) Acetylation of histone tails promotes loose
chromatin structure that permits transcription

51. Chromatin structure Methylation of bases (cytosine)
Represses transcription
Embryo development

52. Eukaryotes Epigenetic change: Chromatin modifications
Change in gene expression
Passed on to the next generation
Not a DNA sequence change

53. Transcription control
RNA polymerase must bind DNA
Proteins regulate by binding DNA
RNA polymerase able to bind or not
Stimulates transcription or blocks it

54. (distal control elements)
Fig
Poly-A signal
sequence
Enhancer
(distal control elements)
Proximal
control elements
Termination
region
Exon
Intron
Exon
Intron
Exon
DNA
Upstream
Downstream
Promoter
Transcription
Primary RNA
transcript
Exon
Intron
Exon
Intron
Exon
Cleaved 3 end
of primary
transcript 5
RNA processing
Intron RNA
Poly-A
signal
Coding segment
mRNA 3
Start
codon
Stop
codon
5 Cap
5 UTR
3 UTR
Poly-A
tail

55. Eukaryotes Transcription RNA Polymerase
Transcription factors (regulatory proteins)
General transcription factors (initiation complex)
Specific transcription factors

56. Eukaryotes Initiation of transcription Activator proteins
Activator binds the enhancers
Enhancers (DNA sequences)
Interacts with the transcription factors
Binds to the promoter
RNA polymerase binds and transcription begins

57. Promoter Activators Gene DNA Enhancer
Fig
Promoter
Activators
Gene
DNA
Distal control
element
Enhancer
TATA
box
General
transcription
factors
DNA-bending
protein
Group of
mediator proteins

58. Promoter Activators Gene DNA Enhancer
Fig
Promoter
Activators
Gene
DNA
Distal control
element
Enhancer
TATA
box
General
transcription
factors
DNA-bending
protein
Group of
mediator proteins
RNA
polymerase II
RNA
polymerase II
Transcription
initiation complex
RNA synthesis

60. Eukaryotes
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61. Enhancer Promoter Albumin gene Control elements Crystallin gene
Fig
Enhancer
Promoter
Albumin gene
Control
elements
Crystallin gene
LIVER CELL
NUCLEUS
LENS CELL
NUCLEUS
Available
activators
Available
activators
Albumin gene
not expressed
Figure Cell type–specific transcription
Albumin gene
expressed
Crystallin gene
not expressed
Crystallin gene
expressed
(a) Liver cell
(b) Lens cell

62. Post transcriptional control
RNA processing
Primary transcript:
Exact copy of the entire gene
RNA splicing
Introns removed from the mRNA
snRNP’s (small nuclear ribonulceoproteins)

65. Post transcriptional control
Splicing plays a role in gene expression
Exons can be spliced together in different ways.
Leads to different polypeptides
Originated from same gene

66. Post transcriptional control
Example in humans
Calcitonin & CGRP
Hormones released from different organs
Derived from the same transcript

67. Exons DNA Troponin T gene Primary RNA transcript RNA splicing mRNA or
Fig
Exons
DNA
Troponin T gene
Primary
RNA
transcript
Figure Alternative RNA splicing of the troponin T gene
RNA splicing
mRNA or

68. Post transcriptional control
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69. Post transcriptional control
Transport of transcript
Passes through nuclear pores
Active transport
Cannot pass until all splicing is done

70. Post transcriptional control
mRNA degradation
Life span
Some can last hours, a few weeks
mRNA for hemoglobin survive awhile
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71. Post transcriptional control
Translation of RNA
Translation factors are necessary
Regulate translation
Translation repressor proteins
Stop translation
Bind transcript
Prevents it from binding to the ribosome

72. Post transcriptional control
Ferritin (iron storage)
Aconitase:
Translation repressor protein
Binds ferritin mRNA
Iron will bind to aconitase
Aconitase releases the mRNA
Ferritin production increases

73. Post transcriptional control
Protein modification
Phosphorylation
Other alterations can affect the activity of protein
Insulin
Starts out as a larger molecule
Cut into more active sections

74. Post transcriptional control
Protein modification
Degradation
Protein is marked by small protein
Protein complex then breaks down proteins
Proteasomes

75. Post transcriptional control
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76. Protein processing and degradation
Fig. 18-UN4
Chromatin modification
Transcription
• Genes in highly compacted
chromatin are generally not
transcribed.
• Regulation of transcription initiation:
DNA control elements bind specific
transcription factors.
• Histone acetylation seems to
loosen chromatin structure,
enhancing transcription.
Bending of the DNA enables activators to
contact proteins at the promoter, initiating
transcription.
• DNA methylation generally
reduces transcription.
• Coordinate regulation:
Enhancer for
liver-specific genes
Enhancer for
lens-specific genes
Chromatin modification
Transcription
RNA processing
• Alternative RNA splicing:
RNA processing
Primary RNA
transcript
mRNA
degradation
Translation
mRNA or
Protein processing
and degradation
Translation
• Initiation of translation can be controlled
via regulation of initiation factors.
mRNA degradation
• Each mRNA has a
characteristic life span,
determined in part by
sequences in the 5 and
3 UTRs.
Protein processing and degradation
• Protein processing and
degradation by proteasomes
are subject to regulation.

77. Post transcriptional control
Most gene regulation-transcription
New discovery
Small RNA’s
21-28 nucleotides long
Play a role in gene expression
New transcript before leaving the nucleus

78. Post transcriptional control
RNA interference
RNA forming double stranded loops from newly formed mRNA
Loops are formed
Halves have complementary sequences
Loops inhibit expression of genes
Where double RNA came from

79. Post transcriptional control
Dicer:
Cuts double stranded RNA into smaller RNA’s called
microRNA (miRNA)
Small interfering RNA (siRNA’s)

80. (b) Generation and function of miRNAs
Fig
Hairpin
miRNA
Hydrogen
bond
Dicer
miRNA
miRNA-
protein
complex 5 3
(a) Primary miRNA transcript
Figure Regulation of gene expression by miRNAs
mRNA degraded
Translation blocked
(b) Generation and function of miRNAs

81. Post transcriptional control
miRNA’s bind mRNA
Prevents translation
siRNA’s breaks apart mRNA before it’s translated

82. Post transcriptional control
siRNAs play a role in heterochromatin formation
Block large regions of the chromosome
Small RNAs may also block transcription of specific genes

83. Chromatin modification
Fig. 18-UN5
Chromatin modification
• Small RNAs can promote the formation of
heterochromatin in certain regions, blocking
transcription.
Chromatin modification
Transcription
Translation
RNA processing
• miRNA or siRNA can block the translation
of specific mRNAs.
mRNA
degradation
Translation
Protein processing
and degradation
mRNA degradation
• miRNA or siRNA can target specific mRNAs
for destruction.

84. Embryonic development
Zygote gives rise to many different cell types
Cells →tissues →
organs → organ systems
Gene expression
Orchestrates developmental programs of animals

85. (a) Fertilized eggs of a frog
Fig a
Figure From fertilized egg to animal: What a difference four days makes
(a) Fertilized eggs of a frog

88. Embryonic development
Zygote to adult results
Cell division
Cell differentiation:
Cells become specialized in structure & function
Morphogenesis:
“creation of from”
Body arrangement

89. (a) Fertilized egg (b) Four-cell stage (c) Early blastula
Fig. 47-6
(a) Fertilized egg
Figure 47.6 Cleavage in an echinoderm embryo
(b) Four-cell stage
(c) Early blastula
(d) Later blastula

90. Fig. 47-1
Figure 47.1 How did this complex embryo form from a single cell?
1 mm

91. (a) 5 weeks (b) 14 weeks (c) 20 weeks Fig. 46-17
Figure Human fetal development
(a) 5 weeks
(b) 14 weeks
(c) 20 weeks

92. Embryonic development
All cells same genome
Differential gene expression
Genes regulated differently in each cell type

93. Enhancer Promoter Albumin gene Control elements Crystallin gene
Fig
Enhancer
Promoter
Albumin gene
Control
elements
Crystallin gene
LIVER CELL
NUCLEUS
LENS CELL
NUCLEUS
Available
activators
Available
activators
Albumin gene
not expressed
Figure Cell type–specific transcription
Albumin gene
expressed
Crystallin gene
not expressed
Crystallin gene
expressed
(a) Liver cell
(b) Lens cell

94. Embryonic development
Specific activators
Materials in egg cytoplasm
Not homogeneous
Set up gene regulation
Carried out as cells divide

95. Embryonic development
Cytoplasmic determinants
Maternal substances in the egg
Influence early development
Zygote divides by mitosis
Cells contain different cytoplasmic determinants
Leads to different gene expression

96. (a) Cytoplasmic determinants in the egg
Fig a
Unfertilized egg cell
Sperm
Nucleus
Fertilization
Two different
cytoplasmic
determinants
Zygote
Mitotic
cell division
Figure Sources of developmental information for the early embryo
Two-celled
embryo
(a) Cytoplasmic determinants in the egg

97. Embryonic development
Environment around cell influences development
Induction:
Signals from nearby embryonic cells
Cause transcriptional changes in target cells
Interactions between cells induce differentiation of specialized cell types

98. (b) Induction by nearby cells
Fig b
NUCLEUS
Early embryo
(32 cells)
Signal
transduction
pathway
Signal
receptor
Figure Sources of developmental information for the early embryo
Signal
molecule
(inducer)
(b) Induction by nearby cells

99. G:\Chapter_18\A_PowerPoint_Lectures\18_Lecture_Presentation\1815bbCellSignalingA.html

100. Embryonic development
Determination:
Observable differentiation of a cell
Commits a cell to its final fate
Cell differentiation is marked by the production of tissue-specific proteins
Gives cell characteristic structure & function

101. Embryonic development
Myoblasts:
Produce muscle-specific proteins
Form skeletal muscle cells
MyoD
One of several “master regulatory genes”
Produces proteins
Commit cells to becoming skeletal muscle

102. Embryonic development
MyoD protein
Transcription factor
Binds to enhancers of various target genes
Causes expression

103. Master regulatory gene myoD Other muscle-specific genes
Fig
Nucleus
Master regulatory gene myoD
Other muscle-specific genes
DNA
Embryonic
precursor cell
OFF
OFF
Figure Determination and differentiation of muscle cells

104. MyoD protein (transcription Myoblast factor) (determined) Nucleus
Fig
Nucleus
Master regulatory gene myoD
Other muscle-specific genes
DNA
Embryonic
precursor cell
OFF
OFF
mRNA
OFF
MyoD protein
(transcription
factor)
Myoblast
(determined)
Figure Determination and differentiation of muscle cells

105. (fully differentiated cell)
Fig
Nucleus
Master regulatory gene myoD
Other muscle-specific genes
DNA
Embryonic
precursor cell
OFF
OFF
mRNA
OFF
MyoD protein
(transcription
factor)
Myoblast
(determined)
Figure Determination and differentiation of muscle cells
mRNA
mRNA
mRNA
mRNA
Myosin, other
muscle proteins,
and cell cycle–
blocking proteins
MyoD
Another
transcription
factor
Part of a muscle fiber
(fully differentiated cell)

106. Embryonic development
Pattern formation:
Development of spatial organization of tissues & organs
Begins with establishment of the major axes
Positional information:
Molecular cues control pattern formation
Tells a cell its location relative to the body axes & neighboring cells

107. Fruit fly Unfertilized egg contains cytoplasmic determinants
Determines the axes before fertilization
After fertilization,
Embryo develops into a segmented larva with three larval stages

108. Head Thorax Abdomen 0.5 mm Dorsal Right BODY AXES Anterior Posterior
Fig a
Head
Thorax
Abdomen
0.5 mm
Dorsal
Right
BODY
AXES
Anterior
Posterior
Figure Key developmental events in the life cycle of Drosophila
Left
Ventral
(a) Adult

109. (b) Development from egg to larva
Fig b
Follicle cell 1
Egg cell
developing within
ovarian follicle
Nucleus
Egg
cell
Nurse cell 2
Unfertilized egg
Egg
shell
Depleted
nurse cells
Fertilization
Laying of egg 3
Fertilized egg
Embryonic
development
Figure Key developmental events in the life cycle of Drosophila 4
Segmented
embryo
0.1 mm
Body
segments
Hatching 5
Larval stage
(b) Development from egg to larva

110. Fruit fly Homeotic genes:
Control pattern formation in late embryo,larva and adult

111. Eye Leg Antenna Wild type Mutant Fig. 18-18
Figure Abnormal pattern formation in Drosophila
Wild type
Mutant

112. Fruit fly Maternal effect genes: Encode for cytoplasmic determinants
Initially establish the axes of the body of Drosophila
Egg-polarity genes:
Maternal effect genes
Control orientation of the egg
Consequently the fly

113. Fruit Fly Bicoid gene Maternal effect gene
Affects the front half of the body
An embryo whose mother has a mutant bicoid gene
Lacks the front half of its body
Duplicate posterior structures at both ends

114. EXPERIMENT Tail Head Wild-type larva Tail Tail Mutant larva (bicoid)
Fig a
EXPERIMENT
Tail
Head A8 T1 T2 T3 A7 A1 A6 A2 A3 A4 A5
Wild-type larva
Tail
Tail
Figure Is Bicoid a morphogen that determines the anterior end of a fruit fly? A8 A8 A7 A7 A6
Mutant larva (bicoid)