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Published byStephany Anderson Modified over 7 years ago
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DNA is one of the strangest molecules known to science.
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For one thing, the DNA molecule is incredibly complex.
atoms
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Also, DNA is incredibly long – the longest molecule we have ever discovered.
Lebron James – 6’8” Lebron James’ DNA – 9’8”
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How the (@#$^* does that all fit inside the nucleus of a cell?
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Even when DNA is not condensed into chromosomes, it is coiled to allow it to fit into the nucleus of a cell.
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Look at it this way: you have 23 feet of intestines, coiled inside your abdominal cavity.
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Also, DNA is the only molecule we know of that contains instructions for making other molecules.
R group R group R group R group R group R group R group R group DNA Molecule Amino Acids Protein
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Most diagrams of DNA look like this:
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However, we can see the molecule more clearly if we un-twist it:
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Looking at it this way, we can see that the DNA molecule is actually double-stranded.
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Furthermore, we can see that the DNA molecule is made from smaller, repeating molecules which are labeled A, T, C, and G.
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DNA Nucleic acid R group R group R group R group Long, double-stranded, polymer molecule that tells ribosomes how to arrange amino acids into protein. L D P R A A P
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The DNA polymer is made from nucleotides.
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Nucleotide Monomer of DNA and another nucleic acid, RNA. New page M D
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There are 4 nucleotides in DNA: adenine, thymine, cytosine, and guanine.
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Nucleotides can join together in any order.
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The order of nucleotides in DNA determines the protein that is made (the “genetic code.”)
ATTACGACA = AGCGGATAT= GCCATAAGC= O P C
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Most diagrams of DNA are highly simplified.
If this is a molecule, where are the bonds? We can see that DNA is made from nucleotides… but what are the nucleotides made from?
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In reality, DNA looks more like this:
3 parts nucleotide Strand #1 Strand #2 Bond Bond
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Diagram of a Nucleotide
DNA = deoxyribose Diagram of a Nucleotide Phosphate group Nitrogenous base (contains phosphorus) (contains nitrogen) Deoxyribose (a 5-carbon sugar)
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Nucleotides join together to form a strand.
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DNA, column 3: Each DNA strand is held together by bonds between the deoxyribose and phosphate groups of each nucleotide. S B D P N “sugar -phosphate backbone”
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Sugar-phosphate backbone Sugar-phosphate backbone
Genetic code
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What holds the 2 strands together?
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The two strands are held together by bonds between the nitrogenous bases.
“Base pair” N B
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Sugar-phosphate backbone Sugar-phosphate backbone
Base pair A T Base pair G C T A
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In DNA, A always bonds with T, and C always bonds with G; this is called the rule of base-pairing.
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There are two types of bonds in the DNA molecule.
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The covalent bonds in the backbone are very strong, to prevent the genetic code from changing.
Hydrogen bond (weak)
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The hydrogen bonds holding the base pairs together are relatively weak…
Covalent bond (strong) Hydrogen bond (weak)
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…which allows the two strands to separate during replication.
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The 4 nucleotides have different nitrogenous bases.
Adenine Cytosine Guanine Thymine
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Looks more like a pyramid
A and G are purines (base has 2 rings). C and T are pyrimidines (base has 1 ring). P P Adenine Cytosine Looks more like a pyramid Guanine Thymine Purines Pyrimidines
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Purines always form base pairs with pyramidines.
Pyrimidine Purine Pyrimidine Purine Purine Pyrimidine Purine Pyrimidine
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The two strands in DNA are not identical
The two strands in DNA are not identical. Instead, they are complementary to each other (opposite). I O Pyrimidine Purine Pyrimidine Purine Purine Pyrimidine Purine Pyrimidine
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Complimentary: Complementary:
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If you know one DNA strand, you can figure out the complementary strand using base-pairing rules.
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Now you know the structure of DNA: two long, complementary strands of nucleotides, held together in the middle by weak hydrogen bonds.
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There’s one last thing you need to know about DNA structure…
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The two strands of DNA form a double helix.
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Double helix Shape of the DNA molecule; formed by two parallel strands that twist around each other. M T S T
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Single helix Double helix
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Nucleic acids are twisted molecules because the covalent bonds in their backbones are bent.
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Bent bonds = spiral shape
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