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Ch. 19

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Ch. 19 Eukaryotic Genomes 2 challenges of eukaryotic genome expression Volume of genome 50,000 100,000 genes 20 x prokaryote Organized around proteins – PowerPoint PPT presentation

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Title: Ch. 19


1
Ch. 19 Eukaryotic Genomes
  • 2 challenges of eukaryotic genome expression
  • Volume of genome
  • 50,000 100,000 genes
  • 20 x prokaryote
  • Organized around proteins
  • Cell specialization
  • Lots of DNA do not RNA/ protein
  • Gene disruption/placement can lead to cancers

2
Structure of Chromatin
  • chromatin structure is based on successive
    levels of DNA packing
  • Prokaryotic DNA associated with proteins and
    looped in orderly manner
  • Eukaryotic DNA see diagram on next slide and
    pg. 345
  • DNA double helix sequence of nucleotides with
    covalent bonds
  • histone proteins 50/50 with DNA mass,
    arginine lysine
  • Nucleosomes beads
  • chromatin - fibers
  • looped domains compaction of chromatin in
    mitotic cells
  • chromosomes

3
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4
Genome Organization on the DNA
  • Genes are a small portion of the genome (97 does
    NOT code for a protein!!)
  • Regulatory sequences
  • Lots not understood
  • Introns
  • Repetitive DNA, some of which is satellite
  • Tandem and interspersed
  • YOU NEVER HEARD THIS IN BIOLOGY ?

5
Vocabulary
  • Introns interrupt coding stretches of DNA and
    are excised from the final mRNA, are not
    expressed as protein, but are within protein
    coding zones
  • Tandemly Repetitive DNA present in many, many
    copies, not within genes. In mammals 10-15 of
    the DNA is tandemly repetitive DNA
  • GTTACGTTACGTTACGTTACGTTAC
  • 10 base pairs
  • Repeated up to 100,000 times
  • Different density in a centrifuge (banding)
  • DNA fingerprinting
  • Genetic disorders
  • Mostly found at telomeres and centromeres
    suggesting a structural role

6
more
  • Interspersed repetitive DNA
  • Not harmful
  • Does code???
  • Lots is found at transposons
  • Multigene families
  • Genes present in more than one copy per haploid
    set
  • Identical or very close nucleotide sequences
  • Likely evolved from one ancestral gene
  • Clustered or dispersed
  • 100-1000 copies of rRNA gene
  • Nonidentical sequences can be clustered because
    all parts are need for a particular protein (a
    and b hemoglobin)

7
Errors ????
  • Gene families all arose from the same ancestor
    either by duplication, chromosome errors,
    transposons or recombination ---- is it a
    mistake or not a mistake.
  • Also regions called pseudogenes that are very
    similar in sequence to functional genes but lack
    regulatory genes or have regions of noncoding DNA

8
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9
Genetic Disorders
  • Huntingtons Disease
  • CAG is translated into string of glutamines
  • Fragile x syndrome
  • Form of mental retardation that is most commonly
    linked to genetic inheritance
  • 11500 males, 12500 females
  • X chromosome looks different
  • More common when fragile x is inherited from
    mother
  • Normal allele - 5 region of nontranslating exon
    GGG 30x
  • Syndrome allele GGG is repeated 100s 1000s
    x and hang off the end of the X chromosome.
  • Triplet repeat disorders
  • Affect the nervous system
  • Length of sequence impacts both age of onset and
    severity
  • Accumulate over generations

10
Genes can be amplified, rearranged or lost
altering a CELLS genome
  • Amplification
  • Extra copies of genes (like those for RNA) can be
    beneficial in the embryo
  • Conversely it is also observed in cancer cells
  • Rearrangement
  • Transposons regions of DNA that can move from
    one location to anotherposition effects this
    impact.
  • 10 of human genome, 50 in some plants
  • Retrotransposons move with help of RNA/reverse
    transcriptionase
  • Cell differentiation.production of
    immunoglobulins
  • Loss

11
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12
Control of Gene Expression
  • Best example see arrangement/rearrangement of
    sequences to create antibodies
  • 3-5 of genome expressed at any given moment,
    especially in differentiated/specialized cells of
    multicellular organisms
  • Chromatin modifications make DNA available for
    transcription
  • DNA methylation genomic imprinting
  • Histone acetylation
  • Transcription initiation interactions with
    other genes (enzymes)
  • Transcription factors, activators, enhancers,
    coordinate control .

13
Lots of big words
  • Transcription initiation complex resembles a
    prok promoter by being upstream
  • Control elements segments of noncoding DNA that
    regulate transcription by binding transcription
    factors
  • Enhancers help bend DNA for transcription
    factors, can be far from gene, even downstream
  • Activators help to position the initiation
    complex
  • Silencers act like prok repressors, probably
    modify chromatin
  • Coordinately controlled genes collections of
    genes, that are related, are usually all
    expressed or all repressed, and are all
    transcribed together, even if they are not near
    on the chromosome.

14
Alternative splicing
  • Regulation of gene expression after transcription
  • Different mRNA can be produced depending on which
    introns are removed
  • mRNA degradation after translation regulates
    amount of a protein produced
  • Leader strands on mRNA means it may not all fit
    into ribosomes for immediate translation
  • Proteins associated with ribosomes may provide a
    means of control in developing embryos where
    everything is on at once

15
proteases
  • Some proteins, like cyclins, need to be degraded
    after they are used..
  • Giant proteins called proteases act like
    shredders for this information.
  • Mutations in this mechanism may leave some cells
    permanently ON and create cancerous situations.

16
Cancer and Molecular Biology
  • Mutagens
  • Chemical carcinogens, physical mutagens
  • Estimate that viruses are involved in about 15
    of cancers
  • 15 of colon and 10 of breast cancer have
    inherited factors
  • Have discovered markers for BRCA I and BRCA II
  • Oncogenes
  • Genes that may cause cancer (trigger cell
    division)
  • Proto-oncogenes
  • Code for proteins that regulate normal cell
    division
  • Tumor suppressor genes
  • Genes whose job it is to control unwanted cell
    division
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