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Protein Synthesis

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Protein Synthesis Transcription and Translation The Genetic Code Animations Translation Translation no sound, basic Summary Genetic information is encoded in the ... – PowerPoint PPT presentation

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Title: Protein Synthesis


1
Protein Synthesis
  • Transcription and Translation

2
The Central Dogma
  • The information encoded with the DNA nucleotide
    sequence of a double helix is transferred to a
    mRNA molecule.
  • The mRNA molecule travels out of the nucleus and
    attaches to a ribosome
  • Using the RNA nucleotide sequence and the genetic
    code, the ribosome assembles a protein

3
The Central Dogma (brief)
  • DNA is copied to mRNA
  • mRNA is used as blueprint to make protein

4
DNA ? Protein in 3 easy steps!
  1. Transcription
  2. RNA modification
  3. Translation

5
Genes and DNA
  • A gene is a specific sequence of DNA nucleotides
  • For each specific protein used by a cell, there
    is a specific DNA sequence (gene) located on a
    chromosome
  • 1 gene ? 1 polypeptide

6
RNA Structure
  • RNA (ribonucleic acid) are nucleotides very
    similar to DNA
  • Nitrogenous bases include Cytosine, Guanine,
    Adenine, and Uracil (instead of Thymine)
  • Form three basic structures
  • mRNA messenger RNA
  • rRNA ribosomal RNA
  • tRNA transfer RNA

7
RNA vs DNA
  • RNA has an oxygen on the 2 carbon of the ribose
    sugar

8
RNA vs DNA
  • RNA is single stranded, DNA is double stranded
  • GCAT vs CUGA

9
Types of RNA molecules
  • mRNA (messenger)
  • Relays DNA sequence information to ribosome
  • rRNA (ribosomal)
  • Combines with proteins to form ribosomes
  • tRNA (transfer)
  • Acts as bridge between nucleotide sequence and
    growing polypeptide chain

10
Transcription
  • The process by which the nucleotide base sequence
    of a DNA molecule is copied into a mRNA molecule
  • 3 steps
  • Initiation
  • Elongation
  • Termination
  • Proteins required
  • RNA polymerase
  • Transcription factors

11
RNA Polymerase
  • Creates a mRNA molecule complimentary to template
    strand of DNA
  • Works in the 5? 3 direction
  • Requires transcription factors to begin its work

12
Initiation
  • Proteins called transcription factors bind to DNA
    region upstream from gene
  • Proteins bind to region called promoter
  • RNA polymerase attaches to double helix at
    beginning of gene

13
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14
Elongation
  • RNA polymerase creates a mRNA molecule with bases
    complimentary to the template strand
  • Template strand Anti-sense strand

15
Termination
  • RNA polymerase reaches end of gene and detaches
    from double helix
  • mRNA transcript is released

16
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17
Animations
  • Transcription showing full complex
  • Transcription cool sounds

18
Sense or Anti-sense?
  • The sense strand of a gene has the same base
    sequence as the mRNA transcript
  • The anti-sense strand is used as the template

19
Transcript Modification
  • Before a mRNA transcript exits the nucleus it is
    modified in 3 three (tres) ways
  • Addition of 5 cap
  • Addition of poly-A tail
  • Removal of introns

20
5 cap and poly-A tail
  • Protective cap is placed on 5 end
  • A long repetitive sequence of adenine nucleotides
    are added to 3 end, also for protection

21
mRNA splicing
  • Not all of a transcribed DNA sequence will be
    translated
  • Genes are composed of introns and exons
  • Introns are removed from mRNA transcripts by
    splicosomes

22
Transcription Review
  1. How is RNA polymerase similar to DNA polymerase
    III? How are they different?
  2. Will the mRNA transcript have the same nucleotide
    sequence as the sense or anti-sense strand of
    DNA?
  3. How are RNA and DNA different?
  4. Name 3 things that happen during mRNA
    modification.

23
Translation
  • messenger RNA (mRNA) is decoded at a ribosome to
    produce a specific polypeptide according to the
    rules specified by the genetic code.
  • 4 steps
  • Activation
  • Initiation
  • Elongation
  • Termination
  • Requires
  • Ribosomes (rRNA proteins), mRNA, tRNA, and
    amino acids

24
Activation
  • Amino acid is joined with the correct tRNA
  • Reaction catalyzed by aminoacyl-tRNA-synthetase
  • Occurs continuously

25
tRNA - transfer
  • Specified amino acids are attached to tRNA
  • each anti-codon corresponds to the amino acid
    specified by the genetic code
  • Each tRNA has an anti-codon (3 nucleotides)
  • Anti-codon region base pairs with mRNA trascript

26
Initiation
  • Small ribosome subunit recognizes start sequence
    on mRNA and binds to it
  • Start codon, AUG, is recognized by tRNA carrying
    a Methionine amino acid
  • Large subunit completes the complex

27
Elongation
  • Ribosome moves down the mRNA in a 5? 3
    direction
  • Every three mRNA nucleotides another amino acid
    is added to the growing polypeptide
  • 3 steps
  • Codon recognition
  • Peptide bond formation
  • Translocation

28
Elongation Codon Recognition
  • When the appropriate tRNA anticodon H-bonds to a
    mRNA codon at the ribosomal complex

29
Elongation Peptide Bond Formation
  • A peptide bond is created between polypeptide
    chain and new amino acid
  • polypeptide is transferred to incoming tRNA

30
Elongation Translocation
  • Ribosome shifts 3 nucleotides (reading frame)
    down mRNA transcript
  • tRNA unattached to polypeptide is released

31
Elongation
Codon Recognition
Peptide Bond Formation
Translocation
32
Termination
  • The end of the mRNA coding sequence is reached
  • Stop codon is recognized by a release factor
  • Ribosome complex dissociates, protein is released

33
The Genetic Code
  • Each codon corresponds to a specific amino acid
  • Degenerate
  • 64 possible codons
  • only 20 amino acids
  • Several codons can code for the same amino acid
  • Ex. CCU, CCA, CCG, CCC Proline
  • Universal
  • The same genetic code is used by all living
    organisms

34
The Genetic Code
35
Animations
  • Translation
  • Translation no sound, basic

36
Summary
  • Genetic information is encoded in the sequence of
    the DNA double helix. To access this information,
    the DNA sequence must be copied, or
    "transcribed", by enzymes known as RNA
    polymerases. The resulting messenger RNA (mRNA)
    molecules carry the genetic information to the
    protein-synthesizing machinery, where it is used
    to define the amino-acid sequence, and therefore
    the structure and function, of proteins.

37
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