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Nucleic Acids and Protein Synthesis
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Before we begin on the notes:
Write your first and last name on each page Remove the top page Give one of us the other two pages
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I. DNA= deoxyribonucleic acid
A. Contains Genes = specific locations on DNA. Genes specify proteins and traits (eye color, disease, etc)
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DNA is bundled into structures called chromosomes.
If the DNA in a person was stretched out it would reach to the sun and back 600 times. It is an extremely long molecule that coils really tight.
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B. The Structure of DNA Rosalind Franklin and Maurice Wilkins Produced X-ray diffraction photograph of DNA. Showed that: DNA is a double helix.
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James Watson and Francis Crick (1953)
Used Franklin’s info to build DNA model Model= double helix of repeating nucleotide monomers
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` 1953 2003
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c. Nucleotides have three parts:
Deoxyribose Sugar Phosphate Group Nitrogen Base (4 kinds) Purines = Adenine (A) & Guanine (G) Pyrimidines = Thymine (T) & Cytosine (C)
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How do the nitrogen bases bind?
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d.Sugar-phosphate molecules on outside of ladder; paired bases on inside.
e.Purines paired to pyrimidines. A is hydrogen-bonded to T G is hydrogen-bonded to C f. Watson and Crick - Nobel Prize in 1954 for their model of DNA.
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Stop End of day 1
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II. DNA Replication = process of duplicating a molecule of DNA
Begins at a specific sequence of nucleotides DNA is unzipped by DNA Helicase enzyme. Helicase breaks the hydrogen bonds between nitrogen bases. Free floating nucleotides bind with complementary bases.
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II. DNA Replication = process of duplicating a molecule of DNA
E. DNA polymerase enzyme catalyzes the bonding of sugar and phosphates F. Results in 2 new strands of DNA G. Each new DNA molecule has one old and one new strand (semi-conservative replication) H. Special Enzymes (DNA polymerase) “proofread” and repair any mistakes I. If repairs are not made, the mutations may cause cancer.
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I. Replication Errors Do Occur
Ability to mutate is requirement for genetic material. Only one error per billion nucleotides.
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J. The newly synthesized strand always forms from 5’ to 3’.
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Animation of DNA Replication
~ 15 minutes
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STOP End of day 2
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III. Ribonucleic Acid (RNA) = makes proteins
DNA ultimately determines amino acid sequence of proteins. DNA molecule cannot directly control the sequence of amino acids. DNA is restricted to nucleus. Go-between is ribonucleic acid (RNA).
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The Structure of RNA Polymer of nucleotides (ribose sugar, Nitrogen base, PO 4 group 2. Unlike DNA, RNA : a) Single-stranded b) Contains the sugar ribose c) Contains the nitrogen base uracil instead of thymine. No “T” in RNA A-U
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There are three major classes of RNA.
Messenger RNA (mRNA)- takes a message from DNA in nucleus to ribosomes in cytoplasm. Ribosomal RNA (rRNA)- and proteins make up ribosomes where proteins are synthesized. Transfer RNA (tRNA)- transfers a particular amino acid to a ribosome.
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IV. Central Dogma of Molecular Biology
DNA undergoes transcription to mRNA mRNA undergoes translation to a protein.
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V. Transcription =process in which mRNA is made according to the sequence of bases in DNA
Occurs in the nucleus. Begins when RNA polymerase (enzyme) binds to a DNA molecule. (Unzips the DNA) Complementary RNA nucleotides pair with DNA nucleotides. RNA polymerase joins the RNA nucleotides together. Terminator sequence causes RNA polymerase to stop. DNA strands rejoin.
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VI. Translation = assembling proteins from “info” encoded in mRNA
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Takes place in cytoplasm.
One language (nucleic acids) is translated into another language (protein). How Genes Code for Amino Acids DNA serves as a template to build RNA mRNA contains the genetic code in the form of codons.
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Codons 3 sequential nucleotide bases of mRNA. (43=64) Each codes for an amino acid. There are 64 triplets to code for 20 amino acids. The Code Is Universal AUG is universal start codon. There are three stop codons.
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Ribosome attaches to a start codon(AUG).
tRNA transfers Amino Acids to the ribosome. tRNA is a single-stranded ribonucleic acid that doubles back on itself to create a cloverleaf structure. At one end it binds to amino acid; at other end it has an anticodon that binds to mRNA codon. Brings the correct amino acid to the codon.
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Ribosome moves to next codon and a new tRNA brings next amino acid.
A peptide bond is formed between amino acids. Process continues until ribosomes hits a stop codon. Polypeptide (protein) is formed.
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