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Can we cure genetic diseases by rewriting DNA?

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    The most important gift
    your mother and father ever gave you
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    was the two sets
    of three billion letters of DNA
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    that make up your genome.
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    But like anything
    with three billion components,
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    that gift is fragile.
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    Sunlight, smoking, unhealthy eating,
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    even spontaneous mistakes
    made by your cells,
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    all cause changes to your genome.
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    The most common kind of change in DNA
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    is the simple swap of one letter,
    or base, such as C,
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    with a different letter,
    such as T, G or A.
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    In any day, the cells in your body
    will collectively accumulate
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    billions of these single-letter swaps,
    which are also called "point mutations."
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    Now, most of these
    point mutations are harmless.
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    But every now and then,
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    a point mutation disrupts
    an important capability in a cell
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    or causes a cell to misbehave
    in harmful ways.
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    If that mutation were inherited
    from your parents
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    or occurred early enough
    in your development,
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    then the result would be
    that many or all of your cells
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    contain this harmful mutation.
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    And then you would be one
    of hundreds of millions of people
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    with a genetic disease,
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    such as sickle cell anemia or progeria
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    or muscular dystrophy
    or Tay-Sachs disease.
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    Grievous genetic diseases
    caused by point mutations
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    are especially frustrating,
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    because we often know
    the exact single-letter change
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    that causes the disease
    and, in theory, could cure the disease.
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    Millions suffer from sickle cell anemia
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    because they have
    a single A to T point mutations
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    in both copies of their hemoglobin gene.
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    And children with progeria
    are born with a T
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    at a single position in their genome
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    where you have a C,
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    with the devastating consequence
    that these wonderful, bright kids
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    age very rapidly and pass away
    by about age 14.
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    Throughout the history of medicine,
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    we have not had a way
    to efficiently correct point mutations
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    in living systems,
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    to change that disease-causing
    T back into a C.
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    Perhaps until now.
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    Because my laboratory recently succeeded
    in developing such a capability,
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    which we call "base editing."
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    The story of how we developed base editing
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    actually begins three billion years ago.
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    We think of bacteria
    as sources of infection,
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    but bacteria themselves are also
    prone to being infected,
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    in particular, by viruses.
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    So about three billion years ago,
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    bacteria evolved a defense mechanism
    to fight viral infection.
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    That defense mechanism
    is now better known as CRISPR.
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    And the warhead in CRISPR
    is this purple protein
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    that acts like molecular
    scissors to cut DNA,
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    breaking the double helix into two pieces.
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    If CRISPR couldn't distinguish
    between bacterial and viral DNA,
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    it wouldn't be a very useful
    defense system.
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    But the most amazing feature of CRISPR
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    is that the scissors can be
    programmed to search for,
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    bind to and cut
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    only a specific DNA sequence.
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    So when a bacterium encounters
    a virus for the first time,
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    it can store a small snippet
    of that virus's DNA
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    for use as a program
    to direct the CRISPR scissors
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    to cut that viral DNA sequence
    during a future infection.
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    Cutting a virus's DNA messes up
    the function of the cut viral gene,
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    and therefore disrupts
    the virus's life cycle.
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    Remarkable researchers including
    Emmanuelle Charpentier, George Church,
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    Jennifer Doudna and Feng Zhang
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    showed six years ago how CRISPR scissors
    could be programmed
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    to cut DNA sequences of our choosing,
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    including sequences in your genome,
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    instead of the viral DNA sequences
    chosen by bacteria.
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    But the outcomes are actually similar.
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    Cutting a DNA sequence in your genome
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    also disrupts the function
    of the cut gene, typically,
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    by causing the insertion and deletion
    of random mixtures of DNA letters
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    at the cut site.
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    Now, disrupting genes can be very
    useful for some applications.
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    But for most point mutations
    that cause genetic diseases,
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    simply cutting the already-mutated gene
    won't benefit patients,
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    because the function of the mutated gene
    needs to be restored,
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    not further disrupted.
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    So cutting this
    already-mutated hemoglobin gene
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    that causes sickle cell anemia
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    won't restore the ability of patients
    to make healthy red blood cells.
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    And while we can sometimes introduce
    new DNA sequences into cells
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    to replace the DNA sequences
    surrounding a cut site,
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    that process, unfortunately, doesn't work
    in most types of cells,
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    and the disrupted gene outcomes
    still predominate.
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    Like many scientists,
    I've dreamed of a future
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    in which we might be able to treat
    or maybe even cure
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    human genetic diseases.
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    But I saw the lack of a way
    to fix point mutations,
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    which cause most human genetic diseases,
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    as a major problem standing in the way.
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    Being a chemist, I began
    working with my students
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    to develop ways on performing chemistry
    directly on an individual DNA base,
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    to truly fix, rather than disrupt,
    the mutations that cause genetic diseases.
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    The results of our efforts
    are molecular machines
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    called "base editors."
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    Base editors use the programmable
    searching mechanism of CRISPR scissors,
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    but instead of cutting the DNA,
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    they directly convert
    one base to another base
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    without disrupting the rest of the gene.
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    So if you think of naturally occurring
    CRISPR proteins as molecular scissors,
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    you can think of base editors as pencils,
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    capable of directly rewriting
    one DNA letter into another
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    by actually rearranging
    the atoms of one DNA base
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    to instead become a different base.
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    Now, base editors don't exist in nature.
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    In fact, we engineered
    the first base editor, shown here,
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    from three separate proteins
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    that don't even come
    from the same organism.
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    We started by taking CRISPR scissors
    and disabling the ability to cut DNA
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    while retaining its ability to search for
    and bind a target DNA sequence
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    in a programmed manner.
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    To those disabled CRISPR
    scissors, shown in blue,
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    we attached a second protein in red,
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    which performs a chemical reaction
    on the DNA base C,
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    converting it into a base
    that behaves like T.
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    Third, we had to attach
    to the first two proteins
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    the protein shown in purple,
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    which protects the edited base
    from being removed by the cell.
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    The net result is an engineered
    three-part protein
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    that for the first time
    allows us to convert Cs into Ts
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    at specified locations in the genome.
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    But even at this point,
    our work was only half done.
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    Because in order to be stable in cells,
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    the two strands of a DNA double helix
    have to form base pairs.
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    And because C only pairs with G,
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    and T only pairs with A,
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    simply changing a C to a T
    on one DNA strand creates a mismatch,
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    a disagreement between the two DNA strands
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    that the cell has to resolve
    by deciding which strand to replace.
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    We realized that we could further engineer
    this three-part protein
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    to flag the nonedited strand
    as the one to be replaced
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    by nicking that strand.
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    This little nick tricks the cell
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    into replacing the nonedited G with an A
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    as it remakes the nicked strand,
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    thereby completing the conversion
    of what used to be a C-G base pair
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    into a stable T-A base pair.
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    After several years of hard work
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    led by a former post doc
    in the lab, Alexis Komor,
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    we succeeded in developing
    this first class of base editor,
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    which converts Cs into Ts and Gs into As
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    at targeted positions of our choosing.
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    Among the more than 35,000 known
    disease-associated point mutations,
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    the two kinds of mutations
    that this first base editor can reverse
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    collectively account for about 14 percent
    or 5,000 or so pathogenic point mutations.
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    But correcting the largest fraction
    of disease-causing point mutations
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    would require developing
    a second class of base editor,
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    one that could convert
    As into Gs or Ts into Cs.
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    Led by Nicole Gaudelli,
    a former post doc in the lab,
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    we set out to develop
    this second class of base editor,
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    which, in theory, could correct up to
    almost half of pathogenic point mutations,
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    including that mutation that causes
    the rapid-aging disease progeria.
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    We realized that we could
    borrow, once again,
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    the targeting mechanism of CRISPR scissors
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    to bring the new base editor
    to the right site in a genome.
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    But we quickly encountered
    an incredible problem;
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    namely, there is no protein
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    that's known to convert
    A into G or T into C
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    in DNA.
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    Faced with such a serious stumbling block,
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    most students would probably
    look for another project,
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    if not another research advisor.
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    (Laughter)
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    But Nicole agreed to proceed with a plan
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    that seemed wildly ambitious at the time.
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    Given the absence
    of a naturally occurring protein
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    that performs the necessary chemistry,
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    we decided we would evolve
    our own protein in the laboratory
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    to convert A into a base
    that behaves like G,
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    starting from a protein
    that performs related chemistry on RNA.
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    We set up a Darwinian
    survival-of-the-fittest selection system
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    that explored tens of millions
    of protein variants
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    and only allowed those rare variants
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    that could perform the necessary
    chemistry to survive.
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    We ended up with a protein shown here,
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    the first that can convert A in DNA
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    into a base that resembles G.
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    And when we attached that protein
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    to the disabled CRISPR
    scissors, shown in blue,
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    we produced the second base editor,
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    which converts As into Gs,
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    and then uses the same
    strand-nicking strategy
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    that we used in the first base editor
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    to trick the cell into replacing
    the nonedited T with a C
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    as it remakes that nicked strand,
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    thereby completing the conversion
    of an A-T base pair to a G-C base pair.
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    (Applause)
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    Thank you.
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    (Applause)
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    As an academic scientist in the US,
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    I'm not used to being
    interrupted by applause.
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    (Laughter)
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    We developed these
    first two classes of base editors
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    only three years ago
    and one and a half years ago.
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    But even in that short time,
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    base editing has become widely used
    by the biomedical research community.
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    Base editors have been sent
    more than 6,000 times
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    at the request of more than
    1,000 researchers around the globe.
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    A hundred scientific research papers
    have been published already,
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    using base editors in organisms
    ranging from bacteria
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    to plants to mice to primates.
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    While base editors are too new
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    to have already entered
    human clinical trials,
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    scientists have succeeded in achieving
    a critical milestone towards that goal
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    by using base editors in animals
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    to correct point mutations
    that cause human genetic diseases.
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    For example,
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    a collaborative team of scientists
    led by Luke Koblan and Jon Levy,
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    two additional students in my lab,
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    recently used a virus to deliver
    that second base editor
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    into a mouse with progeria,
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    changing that disease-causing
    T back into a C
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    and reversing its consequences
    at the DNA, RNA and protein levels.
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    Base editors have also
    been used in animals
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    to reverse the consequence of tyrosinemia,
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    beta thalassemia, muscular dystrophy,
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    phenylketonuria, a congenital deafness
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    and a type of cardiovascular disease --
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    in each case, by directly
    correcting a point mutation
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    that causes or contributes to the disease.
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    In plants, base editors have been used
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    to introduce individual
    single DNA letter changes
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    that could lead to better crops.
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    And biologists have used base editors
    to probe the role of individual letters
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    in genes associated
    with diseases such as cancer.
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    Two companies I cofounded,
    Beam Therapeutics and Pairwise Plants,
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    are using base editing
    to treat human genetic diseases
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    and to improve agriculture.
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    All of these applications of base editing
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    have taken place in less
    than the past three years:
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    on the historical timescale of science,
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    the blink of an eye.
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    Additional work lies ahead
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    before base editing can realize
    its full potential
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    to improve the lives of patients
    with genetic diseases.
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    While many of these diseases
    are thought to be treatable
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    by correcting the underlying mutation
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    in even a modest fraction
    of cells in an organ,
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    delivering molecular machines
    like base editors
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    into cells in a human being
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    can be challenging.
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    Co-opting nature's viruses
    to deliver base editors
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    instead of the molecules
    that give you a cold
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    is one of several promising
    delivery strategies
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    that's been successfully used.
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    Continuing to develop
    new molecular machines
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    that can make all of the remaining ways
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    to convert one base pair
    to another base pair
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    and that minimize unwanted editing
    at off-target locations in cells
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    is very important.
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    And engaging with other scientists,
    doctors, ethicists and governments
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    to maximize the likelihood
    that base editing is applied thoughtfully,
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    safely and ethically,
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    remains a critical obligation.
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    These challenges notwithstanding,
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    if you had told me
    even just five years ago
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    that researchers around the globe
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    would be using laboratory-evolved
    molecular machines
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    to directly convert
    an individual base pair
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    to another base pair
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    at a specified location
    in the human genome
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    efficiently and with a minimum
    of other outcomes,
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    I would have asked you,
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    "What science-fiction novel
    are you reading?"
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    Thanks to a relentlessly dedicated
    group of students
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    who were creative enough to engineer
    what we could design ourselves
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    and brave enough
    to evolve what we couldn't,
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    base editing has begun to transform
    that science-fiction-like aspiration
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    into an exciting new reality,
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    one in which the most important gift
    we give our children
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    may not only be
    three billion letters of DNA,
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    but also the means to protect
    and repair them.
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    Thank you.
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    (Applause)
  • 15:58 - 15:59
    Thank you.
Title:
Can we cure genetic diseases by rewriting DNA?
Speaker:
David R. Liu
Description:

more » « less
Video Language:
English
Team:
closed TED
Project:
TEDTalks
Duration:
16:12

English subtitles

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