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The twisting tale of DNA - Judith Hauck

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    Geckos and grasshoppers, worms and watermelons,
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    elephants and Escherichia Coli,
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    man and mushroom. All so different in form and function,
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    but amazingly the same in how their form and function are determined.
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    First, all these organisms are made of one or more cells,
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    and every cell of every living thing on earth
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    contains all the information it takes
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    to create and duplicate and make variations of itself.
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    That information is stored in a very long but quite simple
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    double molecule called DNA,
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    or Deoxyribonucleic Acid.
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    And the DNA of every living organism is made of chains of four smaller molecules
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    called nucleotides. What dictates the difference between a man and a mushroom
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    is the sequence of these nucleotides in the long DNA chain.
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    The four differing nucleotide parts, called bases,
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    are made of a few carbon, oxygen, hydrogen, nitrogen and phosphorus atoms,
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    and the molecules look like this.
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    And each of these four bases is attached to an identical backbone molecule,
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    a sugar called deoxyribose - the "D" in DNA - and a phosphate group.
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    Let's simplify these nucleotides and show them like this.
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    So, a single sequence of nucleotides joined by their common sugars would look like this.
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    And the DNA molecule where such sequences are stored looks like this.
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    But how does a simple molecule dictate the form and function of millions of different living things?
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    You can think of DNA as a great library of information,
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    information that is used to do one thing and one thing only:
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    direct the building of different protein molecules.
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    And it's the proteins that build the cells and keep them functioning
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    and changing and reproducing. Here's where the familiar word 'gene' comes in.
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    If your DNA is a library of information, a gene is a book in that library.
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    A gene is a segment of the DNA molecule.
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    Let's say your body needs a particular protein, like insulin.
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    To get it, some of your cells send a protein signal through the bloodstream
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    to the cells in your pancreas, where insulin is made.
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    That signal protein tells other proteins in the cell's nuclei
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    to open up a part of the DNA double helix, the insulin gene,
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    and start making insulin proteins.
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    As soon as enough insulin has been produced,
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    another signal protein comes to the pancreas' cells that tells them to stop making insulin.
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    It's like looking up a book in the DNA library about insulin,
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    and then putting it back when you're done.
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    There are genes in DNA for visible and invisible things that make up your body,
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    like genes for eye color, protein pigments, for skin color,
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    for hair color, for stopping and starting bone growth,
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    for your blood type, for how many fingers or arms and legs you have,
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    for proteins that influence how long you live.
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    Your DNA probably contains between 25 thousand and 40 thousand genes,
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    while the DNA of a worm or a plant or a fruit fly
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    contains about 12 thousand to 20 thousand genes.
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    Some of those genes have quite different sequences of nucleotides than yours,
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    and some are similar to yours.
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    Though it happens infrequently,
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    our own nucleotide sequences can change
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    as the result of spontaneous or environmental damage
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    which might remove or shift a nucleotide position.
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    This changes the gene involved, and can then change the protein.
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    Most of these changes, called mutations,
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    have very little effect on the organism or its descendants.
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    some are mildly damaging,
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    and a few can make the organism better-suited to its environment.
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    It is these tiny changes in DNA gene sequences, happening over millions of years,
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    that create the differences among living organisms, from geckos to grasshoppers.
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    worms to watermelons, elephants to Escherichia Coli, and man to mushroom.
Title:
The twisting tale of DNA - Judith Hauck
Description:

View full lesson on ed.ted.com http://ed.ted.com/lessons/the-twisting-tale-of-dna-judith-hauck

What do a man, a mushroom, and an elephant have in common? A very long and simple double helix molecule makes us more similar and much more different than any other living thing. But, how does a simple molecule determine the form and function of so many different living things?

Lesson by Judith Hauck, animation by Cameron Slayden.
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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
04:27
Bedirhan Cinar approved English subtitles for The twisting tale of DNA - Judith Hauck
Bedirhan Cinar accepted English subtitles for The twisting tale of DNA - Judith Hauck
tom carter edited English subtitles for The twisting tale of DNA - Judith Hauck
tom carter added a translation

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