Chapter 19 The Organization and Control of Eukaryotic Genomes - PowerPoint PPT Presentation

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Chapter 19 The Organization and Control of Eukaryotic Genomes

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With so much DNA in a cell, how is it organized or packaged? ... A cylinder of tightly coiled nucleosomes 30 - nm in diameter. Looped Domains ... – PowerPoint PPT presentation

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Title: Chapter 19 The Organization and Control of Eukaryotic Genomes


1
Chapter 19The Organization and Control of
Eukaryotic Genomes
2
Human Genome
  • 3 billion base pairs.
  • 30,000 to 50,000 genes.
  • 3-5 active at any moment.

3
Questions?
  • With so much DNA in a cell, how is it organized
    or packaged?
  • How is the expression of the DNA controlled?

4
Movie DNA Packaging
5
Microscopic Levels
  • 1. Nucleosomes
  • 2. 30-nm Chromatin Fibers
  • 3. Looped Domains
  • 4. Chromosomes

6
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7
Nucleosomes
  • "Beads on a String.
  • DNA wound on a protein core.
  • Packaging for DNA.
  • Controls transcription.

8
Protein Core
  • Two molecules of four types of Histone proteins.
  • H1- 5th type of Histone protein attaches the DNA
    to the outside of the core.

9
30 - nm Chromatin Fibers
  • A cylinder of tightly coiled nucleosomes 30 - nm
    in diameter.

10
Looped Domains
  • Loops of 30 - nm chromatin.

Protein Scaffold
11
Chromosomes
  • Large units of DNA.
  • Similar to "Chapters" in the Book of Life.

12
Chromosome Regions
  • 1. Heterochromatin - highly condensed chromatin
    areas that are not transcribed.
  • 2. Euchromatin - less condensed chromatin areas
    of active transcription.

13
Molecular Level Organization
  • 1. Repetitive Sequences
  • 2. Satellite DNA
  • 3. Interspersed Repetitive DNA
  • 4. Multigene Families

14
Repetitive Sequences
  • Tandemly repeating units of 1-10 nucleotides.
  • 10 to 15 of total DNA.

15
Satellite DNA
  • Repetitive areas of DNA found at the
  • Tips of chromosomes.
  • Centromere regions.
  • Structural DNA.

16
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17
Result
  • Give regions of the DNA different densities.
  • Linked to some genetic disorders.
  • Ex. - Fragile X Syndrome
  • Huntingtons disease

18
Interspersed Repetitive DNA
  • 25 - 40 of DNA
  • Copies of repetitive units that are scattered
    among genes.
  • Often transcribed, but function not
    clear.
  • Ex. Alu elements.

19
Multigene Families
  • A collection of identical or very similar genes.
  • From a common ancestral gene.
  • May be clustered or dispersed in the genome.

20
Types
  • 1. Identical
  • 2. Nonidentical

21
Identical Families
  • Identical genes for the same protein.
  • Ex Ribosomal Protein and rRNA.
  • Result - Many copies of ribosomes possible.
  • Most common gene in DNA.

22
Identical Genes
23
Nonidentical Families
  • Related clusters of genes that are nearly
    identical in their base sequences.
  • Ex Globin Genes

24
Globin Gene Evolution
25
a - Globin Family
  • Found on chromosome 16.
  • Contains two copies of a globin, one
    fetal globin and four pseudogenes.

26
b - Globin Family
  • Found on chromosome 11.
  • Contains two copies of b globin, one
    embryo, two fetal and one pseudogene.

27
Pseudogene
  • Gene with sequences very similar to real genes,
    but lack promoter sites.
  • Are not transcribed into proteins.
  • Possible proof of transpositions ?

28
Genome Plasticity
  • Changes in the ways a gene can be expressed.
  • Seen only in somatic cells.
  • Have major effects on gene expression within
    particular cells and tissues.

29
Types
  • 1. Gene Amplification
  • 2. Selective Gene Loss
  • 3. Genomic Rearrangements

30
Gene Amplification
  • The selective replication of certain genes.
  • Ex rRNA genes in eggs
  • Result - many copies of rRNA for making
    ribosomes.

31
Selective Gene Loss
  • Loss of genes or chromosomes in some tissues
    during development.
  • Result - DNA (genes) lost and not expressed.

32
Genomic Rearrangements
  • Shuffling of DNA areas (not from Meiosis).
  • Ex Transposons retrotransposons antibody
    genes.

33
Transposons - Example
34
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35
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36
Result
  • Genes moved structurally within the genome.
  • Transcription control changed.

37
Control of Gene Expression
  • Complicated Process.
  • Many levels of control are possible.
  • Hint - students should be able to discuss several
    mechanisms of control.

38
Main Control Levels
  • 1. Nucleus - those inside the nuclear membrane.
  • 2. Cytoplasm - those that occur in the cytoplasm.

39
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40
Nucleus Level
  • 1. Extra-Cellular Signals
  • 2. Chromatin Modifications
  • 3. Transcriptional Control
  • 4. Posttranscriptional Control

41
Extra-Cellular Signal
  • Signal from outside the cells (usually a
    hormone).
  • Review specifics from Chapter 11.
  • Result - regions of DNA activated for
    transcription.

42
Chromatin Modifications
  • DNA Methylation.
  • Histone Acetylation.
  • Gene rearrangements.
  • Gene amplification.

43
DNA Methylation
  • Addition of methyl groups (-CH3) to DNA
    bases.
  • Result - long-term shut-down of DNA
    transcription.
  • Ex Barr bodies genomic imprinting

44
Histone Acetylation
  • Attachment of acetyl groups (-COCH3) to AAs in
    histones.
  • Result - DNA held less tightly to the
    nucleosomes, more accessible for transcription.

45
Transcriptional Control
  • Ex Enhancers, DNA-Binding
    Domains regulatory RNA.
  • Result - genes are more (or less) available
    for transcription.
  • Factors that affect the transcription of genes.

46
Movie Turning on a Gene
47
Enhancers
  • Areas of DNA that increase transcription.
  • May be widely separated from the gene
    (usually upstream).

48
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49
DNA-Binding Domains
  • Proteins that bind to DNA and regulate
    transcription.
  • Ex
  • Helix-turn-Helix
  • Zinc-Finger
  • Leucine Zipper

50
DNA Binding Domains
51
Regulatory RNA
  • Small RNA molecules that are not translated
  • Interact with DNA
  • Whole new area in gene regulation

52
Posttranscriptional Control
  • 1. RNA Processing Ex - introns
    and exons.
  • 2. RNA Transport - moving the mRNA into the
    cytoplasm.
  • 3. RNA Degradation - breaking down old mRNA.

53
Transcription Control
54
Movie RNA processing
55
Cytoplasm Level of Control
  • 1. Translation
  • 2. Polypeptide Changes

56
Movie Translation control
57
Translation Control
  • Regulated by the availability of initiation
    factors.
  • Availability of tRNAs, AAs and other protein
    synthesis factors. (review Chapter 17).

58
Polypeptide Changes
  • Changes to the protein structure after
    translation.
  • Ex Cleavage
  • Modifications
  • Activation
  • Transport
  • Degradation

59
Movie Protein Processing
60
Protein Degradation
  • By Proteosomes using Ubiquitin to mark the
    protein.

61
Gene Expression and Cancer
  • Cancer - loss of the genetic control of cell
    division.
  • Balance between growth-stimulating pathway
    (accelerator) and growth-inhibiting pathway
    (brakes).

62
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63
Proto-oncogenes
  • Normal genes for cell growth and cell division
    factors.
  • Genetic changes may turn them into oncogenes
    (cancer genes).
  • Ex Gene Amplification, Translocations,
    Transpositions, Point Mutations

64
Proto-oncogenes
65
Tumor-Suppressor Genes
  • Genes that inhibit cell division.
  • Ex - p53, p21

66
Cancer Examples
  • RAS - a G protein.
  • When mutated, causes an increase in cell division
    by over-stimulating protein kinases.
  • Several mutations known.

67
Cancer Examples
  • p53 - involved with several DNA repair genes and
    checking genes.
  • When damaged, cant inhibit cell division or
    cause damaged cells to apoptose.

68
Comment
  • p53 is known to be sensitive to cigarette smoke.
  • Damage by smoke often leads to lung cancer.
  • Over-activity of p53 causes problems too.

69
Carcinogens
  • Agents that cause cancer.
  • Ex radiation, chemicals
  • Most work by altering the DNA, or interfering
    with control or repair mechanisms.

70
Multiple Hit Hypothesis
  • Cancer is the result of several control
    mechanisms breaking down.
  • Ex Colorectal Cancer requires 4 to 5 mutations
    before cancer starts.

71
Colorectal Cancer
72
Summary
  • DNA packaging and gene expression are very
    complex with lots of opportunities for control
    points.
  • Be able to discuss how DNA is organized and
    packed.

73
Summary
  • Be able to discuss mechanisms for regulating DNA
    and protein synthesis (know several ways)
  • How control of DNA can lead to cancer.
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