1. Control of Gene Expression in Eukaryotes
Benjamin A. Pierce
GENETICS
A Conceptual Approach
FOURTH EDITION
CHAPTER 17
Control of Gene Expression in Eukaryotes
© 2012 W. H. Freeman and Company 1

2. Chapter 17 Outline
17.1 Eukaryotic Cells and Bacteria Have Many Features of Gene Regulation in Common, but They Differ in Several Important Ways, 460
17.2 Changes in Chromatin Structure Affect the Expression of Genes, 460
17.3 Epigenetic Effects Often Result from Alterations in Chromatin Structure, 463
17.4 The Initiation of Transcription Is Regulated by Transcription Factors and Transcriptional Regulator Proteins, 465

3. Chapter 17 Outline
17.5 Some Genes Are Regulated by RNA Processing and Degradation, 470
17.6 RNA Interference Is an Important Mechanism of Gene Regulation, 472
17.7 Some Genes Are Regulated by Processes That Affect Translation or by Modification of Proteins, 474

4. Anopheles mosquitoes transmit Plasmodium falciparum, one of the protozoan parasites that causes malaria. The parasite survives in humans by altering the expression of its surface proteins through gene regulation, thereby evading the human immune defenses. [Dr. Dennis Kunkel/Visuals Unlimited.]

5. 17.1 Eukaryotic Cells and Bacteria Have Many Features of Gene Regulation in Common, but They Differ in Several Important Ways
Each structural gene has its own promoter, and is transcribed separately.
DNA must unwind from the histone proteins before transcription.
Transcription and translation are separated in time and space.

6. 17.2 Changes in Chromatin Structure Affect the Expression of Genes
DNase I hypersensitivity
DNase I hypersensitive sites: more open chromatin configuration site, upstream of the transcription start site
Histone modification
Addition of methyl groups to the histone protein tails
Addition of acetyl groups to histone proteins

7. Figure 17.2 The acetylation of histone proteins alters chromatin structure and permits some transcription factors to bind to DNA.

8. Figure 17.2 The acetylation of histone proteins alters chromatin structure and permits some transcription factors to bind to DNA.

9. 17.2 Changes in Chromatin Structure Affect the Expression of Genes
Acetylation of histones controls flowering in Arabidopsis
Flowering locus C (FLC) gene
Flowering locus D (FLD) gene

10. Figure Flowering in Arabidopsis is controlled in part by FLD, a gene that encodes a deacetylase enzyme. This enzyme removes acetyl groups from histone proteins in chromatin surrounding FLC, a gene that suppresses flowering. The removal of the acetyl groups from the histones restores chromatin structure and represses the transcription of FLC, thereby allowing the plant to flower.

11. Figure Flowering in Arabidopsis is controlled in part by FLD, a gene that encodes a deacetylase enzyme. This enzyme removes acetyl groups from histone proteins in chromatin surrounding FLC, a gene that suppresses flowering. The removal of the acetyl groups from the histones restores chromatin structure and represses the transcription of FLC, thereby allowing the plant to flower.

12. 17.2 Changes in Chromatin Structure Affect the Expression of Genes
Chromatin remodeling
Chromatin-remodeling complexes: bind directly to DNA sites and reposition nucleosomes
DNA Methylation
DNA methylation of cytosine bases adjacent to guanine nucleotides (CpG)–CpG islands

13. 17.3 Epigenetic Effects Often Result from Alterations in Chromatin Structure
Changes induced by maternal behavior
Effects caused by prenatal exposure
Effects in monozygotic twins
Molecular Mechanisms of Epigenetic Changes
DNA methylation is maintained from generation to generation

14. Figure 17.4 DNA methylation is stably maintained through DNA replication

15. Figure 17.4 DNA methylation is stably maintained through DNA replication

16. Figure 17.4 DNA methylation is stably maintained through DNA replication

17. Figure 17.4 DNA methylation is stably maintained through DNA replication

18. Figure 17.4 DNA methylation is stably maintained through DNA replication

19. Figure 17.4 DNA methylation is stably maintained through DNA replication

20. 17.3 Epigenetic Effects Often Result from Alterations in Chromatin Structure
The Epigenome
Overall pattern of chromatin modification possessed by an individual organsim

21. Concept Check 1 What is not a mechanism for epigenetic change?.
DNA methylation
Alteration of a DNA sequence in a promoter
Histone acetylation
Nucleosome repositioning

22. Concept Check 1 What is not a mechanism for epigenetic change?.
DNA methylation
Alteration of a DNA sequence in a promoter
Histone acetylation
Nucleosome repositioning

23. 17.4 The Initiation of Transcription Is Regulated by Transcription Factors and Transcriptional Activator Proteins
Transcriptional Activators and Coactivators
Stimulate and stabilize basal transcription apparatus at core promoter
Mediator
Regulation of galactose metabolism through GAL4

24. Figure 17.5 Transcriptional activator proteins bind to sites on DNA and stimulate transcription. Most act by stimulating or stabilizing the assembly of the basal transcription apparatus.

25. Figure 17.5 Transcriptional activator proteins bind to sites on DNA and stimulate transcription. Most act by stimulating or stabilizing the assembly of the basal transcription apparatus.

26. Figure The consensus sequences in the promoters of three eukaryotic genes illustrate the principle that different sequences can be mixed and matched in different combinations. A different transcriptional activator protein binds to each consensus sequence, and so each promoter responds to a unique combination of activator proteins

27. Figure 17.7 Transcription is activated by GAL4 in response to galactose. GAL4 binds to the UASG site and controls the transcription of genes in galactose metabolism.

28. Figure 17.7 Transcription is activated by GAL4 in response to galactose. GAL4 binds to the UASG site and controls the transcription of genes in galactose metabolism.

29. 17.4 The Initiation of Transcription Is Regulated by Transcription Factors and Transcriptional Regulator Proteins
Transcriptional Repressors
Bind to silencers
Enhancers and Insulators
Enhancer: DNA sequence stimulating transcription from a distance away from promoter
Insulator: DNA sequence that blocks or insulates the effect of enhancers

30. Figure An insulator blocks the action of an enhancer on a promoter when the insulator lies between the enhancer and the promoter.

31. Figure An insulator blocks the action of an enhancer on a promoter when the insulator lies between the enhancer and the promoter.

32. Concept Check 2
Most transcriptional activator proteins affect transcription by interacting with
introns
the basal transcription apparatus
DNA polymerase
nucleosomes

33. Concept Check 2
Most transcriptional activator proteins affect transcription by interacting with
introns
the basal transcription apparatus
DNA polymerase
nucleosomes

34. Figure 17.9 Multiple response elements (MREs) are found in the upstream region of the metallothionein gene. The basal transcription apparatus binds near the TATA box. In response to heavy metals, activator proteins bind to several MREs and stimulate transcription. The TRE response element is the binding site for transcription factor AP1, which is stimulated by phorbol esters. In response to glucocorticoid hormones, steroid-receptor proteins bind to the GRE response element located approximately 250 nucleotides upstream of the metallothionein gene and stimulate transcription.

35. Figure 17.9 Multiple response elements (MREs) are found in the upstream region of the metallothionein gene. The basal transcription apparatus binds near the TATA box. In response to heavy metals, activator proteins bind to several MREs and stimulate transcription. The TRE response element is the binding site for transcription factor AP1, which is stimulated by phorbol esters. In response to glucocorticoid hormones, steroid-receptor proteins bind to the GRE response element located approximately 250 nucleotides upstream of the metallothionein gene and stimulate transcription.

36. 17.4 The Initiation of Transcription Is Regulated by Transcription Factors and Transcriptional Regulator Proteins
Regulation of Transcriptional Stalling and Elongation
E.g. heat shock proteins

37. 17.4 The Initiation of Transcription Is Regulated by Transcription Factors and Transcriptional Regulator Proteins
Regulation of Transcriptional Stalling and Elongation
Heat shock proteins
Coordinated gene regulation
Response elements: common regulatory elements upstream of the start sites of a collective group of genes in response to a common environmental stimulus

39. 17.5 Some Genes Are Regulated by RNA Processing and Degradation
Gene regulation through RNA splicing
Alternative splicing in the T-antigen gene
Alternative splicing in Drosophilia sexual
development

40. Figure Alternative splicing leads to the production of the small t antigen and the large T antigen in the mammalian virus SV40.

41. Figure Alternative splicing leads to the production of the small t antigen and the large T antigen in the mammalian virus SV40.

42. Figure 17.11 Alternative splicing controls sex determination in Drosophila.

43. Figure 17.11 Alternative splicing controls sex determination in Drosophila.

44. Figure 17.11 Alternative splicing controls sex determination in Drosophila.

45. Figure 17.11 Alternative splicing controls sex determination in Drosophila.

46. Figure 17.11 Alternative splicing controls sex determination in Drosophila.

47. Figure 17.11 Alternative splicing controls sex determination in Drosophila.

48. Figure 17. 12 Alternative splicing of tra pre-mRNA
Figure Alternative splicing of tra pre-mRNA.Two alternative 3′ splice sites are present.

49. Figure 17. 12 Alternative splicing of tra pre-mRNA
Figure Alternative splicing of tra pre-mRNA.Two alternative 3′ splice sites are present.

50. Figure 17. 12 part 1 Alternative splicing of tra pre-mRNA
Figure part 1 Alternative splicing of tra pre-mRNA.Two alternative 3′ splice sites are present.

51. Figure 17. 12 part 1 Alternative splicing of tra pre-mRNA
Figure part 1 Alternative splicing of tra pre-mRNA.Two alternative 3′ splice sites are present.

52. Figure 17. 12 part 2 Alternative splicing of tra pre-mRNA
Figure part 2 Alternative splicing of tra pre-mRNA.Two alternative 3′ splice sites are present.

53. Figure 17. 12 part 2 Alternative splicing of tra pre-mRNA
Figure part 2 Alternative splicing of tra pre-mRNA.Two alternative 3′ splice sites are present.

54. 17.5 Some Genes Are Regulated by RNA Processing and Degradation
The Degradation of RNA
5′-cap removal
Shortening of the poly(A) tail
Degradation of 5′ UTR, coding sequence, and 3′ UTR

55. 17.6 RNA Interference Is an Important Mechanism of Gene Regulation
Small interfering RNAs and microRNAs
Dicer
RISC: RNA-induced silencing complex

56. Figure RNA silencing leads to the degradation of mRNA or to the inhibition of translation or transcription. (a) Small interfering RNAs (siRNAs) degrade mRNA by cleavage

57. Figure RNA silencing leads to the degradation of mRNA or to the inhibition of translation or transcription. (a) Small interfering RNAs (siRNAs) degrade mRNA by cleavage.

58. Figure RNA silencing leads to the degradation of mRNA or to the inhibition of translation or transcription. (a) Small interfering RNAs (siRNAs) degrade mRNA by cleavage

59. Figure RNA silencing leads to the degradation of mRNA or to the inhibition of translation or transcription. (b) MicroRNAs (miRNAs) lead to the inhibition of translation.

60. Figure RNA silencing leads to the degradation of mRNA or to the inhibition of translation or transcription. (b) MicroRNAs (miRNAs) lead to the inhibition of translation

61. Figure RNA silencing leads to the degradation of mRNA or to the inhibition of translation or transcription. (c) Some small interfering RNAs (siRNAs) methylate histone proteins or DNA, inhibiting transcription.

62. Figure RNA silencing leads to the degradation of mRNA or to the inhibition of translation or transcription. (c) Some small interfering RNAs (siRNAs) methylate histone proteins or DNA, inhibiting transcription.

63. 17.6 RNA Interference Is an Important Mechanism of Gene Regulation
Mechanisms of Gene Regulation by RNA interference
RNA cleavage: RISC containing an siRNA, pair with mRNA molecules and cleavage to the mRNA
Inhibition of translation
Transcriptional silencing: altering chromatin structure
Silencer-independent degradation of mRNA

64. 17.6 RNA Interference Is an Important Mechanism of Gene Regulation
The Control of Development by RNA Interference

65. Concept Check 3
In RNA silencing, siRNAs and miRNAs usually bind to which part of the mRNA molecules that they control?
5’ UTR
Segment that encodes amino acids
3’ poly (A) tail
3’ UTR

66. Concept Check 3
In RNA silencing, siRNAs and miRNAs usually bind to which part of the mRNA molecules that they control?
5’ UTR
Segment that encodes amino acids
3’ poly (A) tail
3’ UTR

67. 17.7 Some Genes Are Regulated by Processes That Affect Translation or by Modification of Proteins
Proteins bind 5’UTR
Affect availability of translational machinery

68. Figure The expression of some eukaryotic genes is regulated by the availability of components required for translation. In this example, exposure to an antigen stimulates an increased availability of initiation factors and a subsequent increase in protein synthesis, leading to T-cell proliferation.

69. Figure The expression of some eukaryotic genes is regulated by the availability of components required for translation. In this example, exposure to an antigen stimulates an increased availability of initiation factors and a subsequent increase in protein synthesis, leading to T-cell proliferation.

70. Figure (part 1) The expression of some eukaryotic genes is regulated by the availability of components required for translation. In this example, exposure to an antigen stimulates an increased availability of initiation factors and a subsequent increase in protein synthesis, leading to T-cell proliferation.

71. Figure (part 1) The expression of some eukaryotic genes is regulated by the availability of components required for translation. In this example, exposure to an antigen stimulates an increased availability of initiation factors and a subsequent increase in protein synthesis, leading to T-cell proliferation.

72. Figure (part 2) The expression of some eukaryotic genes is regulated by the availability of components required for translation. In this example, exposure to an antigen stimulates an increased availability of initiation factors and a subsequent increase in protein synthesis, leading to T-cell proliferation.

73. Figure (part 2) The expression of some eukaryotic genes is regulated by the availability of components required for translation. In this example, exposure to an antigen stimulates an increased availability of initiation factors and a subsequent increase in protein synthesis, leading to T-cell proliferation.