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DNA and chromatin regulation | Biomolecules | MCAT | Khan Academy

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    So, the regulation of
    gene expression can be
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    modulated at virtually any
    step in the process, from
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    the initiation of
    transcription all the way to
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    post-translational
    modification of a protein,
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    and every step in between.
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    And it's the ability to regulate
    all these different steps
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    that helps the cell to have
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    the versatility and the adaptability of
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    an efficient ninja, so
    that it expends energy to
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    express the appropriate
    proteins only when needed.
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    Or, you can think of the cell as
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    a lazy couch potato that wants to expend
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    the least amount of energy as possible.
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    So, starting at the
    beginning of gene expression,
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    let's talk about gene regulation
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    as it pertains to DNA
    and chromatin regulation.
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    Let's talk about the structure of DNA.
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    DNA is packed into
    chromosomes in the form of
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    chromatin, also know as supercoiled DNA.
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    And so, chromatin is made up of DNA,
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    histone proteins, and
    non-histone proteins.
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    And there are repeating
    units in chromatin,
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    called nucleosomes, which are made up of
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    146 base pairs of double
    helical DNA that is
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    wrapped around a core of eight histones.
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    And there are four different
    types of histones within
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    this structure of eight
    that you should be aware of.
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    And they're named H2A, H2B, H3, and H4,
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    that's just the nomenclature
    they've been given.
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    Now, acetylation occurs at
    the amino terminal tails
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    of these histone proteins
    by an enzyme called
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    histone acetyltransferase,
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    which I'll just abbreviate as HAT.
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    And this is a reversible
    modification, so the
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    acetylation of histones
    is sort of kept in balance
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    by another enzyme that
    removes these acetyl groups,
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    which is called histone
    deacetylase, or HDAC.
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    The acetylation of histones leads to
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    uncoiling of this chromatin
    structure, and this
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    allows it be accessed by
    transcriptional machinery
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    for the expression of genes.
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    On the flip side of this,
    histone deacetylation leads to
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    a condensed, or closed
    structure of the chromatin,
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    and less transcription of those genes.
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    When these modifications that regulate
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    gene expression are inheritable,
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    they are referred to as
    epigenetic regulation.
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    So, when it comes to
    gene expression and DNA,
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    you can basically think of DNA
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    as coming in two flavors,
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    densely packed, and
    transcriptionally inactive DNA,
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    which is called heterochromatin,
    and then less dense,
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    transcriptionally active
    DNA, which is euchromatin.
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    And I like to think of
    heterochromatin as being
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    densely packed and hibernating,
    like heterochromatin
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    and hibernating both begin
    with H, kind of like a
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    bunch of densely packed bears that are
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    closed off in their cave for the winter,
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    whereas euchromatin is waiting there
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    with open arms, welcoming the
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    transcriptional machinery
    to transcribe away.
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    Now often you will see
    that histone deacetylation
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    is combined with another type of
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    DNA regulatory mechanism,
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    and that is DNA methylation, and
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    this occurs in a process
    called gene silencing.
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    And this is a more
    permanent method of sort of
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    down-regulating the
    transcription of genes.
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    And DNA methylation
    involves the addition of a
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    methyl group, which is a
    carbon with three hydrogens,
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    to the cytosine, DNA nucleotides,
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    by an enzyme appropriately
    called methyltransferase.
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    And this typically occurs in
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    cytosine-rich sequences
    called CpG islands.
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    Don't forget that cytosine
    pairs with g, guanine,
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    so that's why they're cg
    islands that you'll find.
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    DNA methylation stably alters
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    the expression of genes, and so
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    it occurs as cells
    divide and differentiate
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    from embryonic stem cells
    into specific tissues.
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    And so this is essential
    for normal development,
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    and is associated with
    other processes, such as
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    genomic imprinting, and
    x-chromosome inactivation,
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    topics for another discussion.
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    And abnormal DNA methylation has been
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    implicated in carcinogenesis, or the
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    development of cancer,
    so you can see how the
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    normal functioning of DNA methylation is
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    a critical regulatory
    mechanism for our cells.
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    Now, DNA methylation may effect
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    the transcription of genes in two ways.
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    First, the methylation of DNA itself
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    may physically impede the binding
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    of transcriptional proteins to the gene.
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    And second, and likely more important,
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    methylated DNA may be
    bound by proteins known as
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    methyl cpg-binding domain proteins,
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    or MBDs, for short.
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    Now MBD proteins can then
    recruit additional proteins
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    to the locus, or particular
    location in a chromosome,
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    certain genes, such as
    histone deacetylases,
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    and other chromatin
    remodeling proteins, and this
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    modifies the histones, forming condensed,
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    inactive heterochromatin that is
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    basically transcriptionally silent.
Title:
DNA and chromatin regulation | Biomolecules | MCAT | Khan Academy
Description:
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Video Language:
English
Team:
Khan Academy
Duration:
05:21

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