Making Human (eukaryote) proteins in Bacteria (prokaryote) - PowerPoint PPT Presentation

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Making Human (eukaryote) proteins in Bacteria (prokaryote)

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Title: Transcription and Translation Author: Mitrick Johns Last modified by: Paul Feinstein Created Date: 4/2/2004 10:12:04 PM Document presentation format – PowerPoint PPT presentation

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Title: Making Human (eukaryote) proteins in Bacteria (prokaryote)


1
Making Human (eukaryote) proteins in Bacteria
(prokaryote)
2
Nucleus
3
Mitochondria
  • What keeps the mitochondria in dividing
    cells?most likely

4
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5
What keeps plasmids in dividing cells?
6
Tetracycline works by
7
Tetracycline resistance works by
8
What allows for DNA replication in plasmid?
Resistance gene
9
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10
What allows for mRNA production?
Resistance gene
11
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14
Now have an inducible system
Resistance gene
15
How does gene need to be formulated For
transcription to produce functional RNA occur in
prokaryotes?
Resistance gene
16
KozaK?
  • Kozak sequence gccaccATGg

17
Finding first AUG in Prokaryotes.
  • Shine-Delgarno sequence!

18
Add gene
Resistance gene
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20
We missing something?
Shine-Delgarno
gene
Resistance gene
21
Transcription Prokaryotes
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23
What should gene look like?
Shine-Delgarno
gene
Sigma Termination sequence
Resistance gene
24
What should gene look like?
Shine-Delgarno
gene
Sigma Termination sequence
Resistance gene
25
After Transcription
  • In prokaryotes, the RNA copy of a gene is
    messenger RNA, ready to be translated into
    protein. In fact, translation starts even before
    transcription is finished.
  • In eukaryotes, the primary RNA transcript of a
    gene needs further processing before it can be
    translated. This step is called RNA
    processing. Also, it needs to be transported out
    of the nucleus into the cytoplasm.
  • Steps in RNA processing
  • 1. Add a cap to the 5 end
  • 2. Add a poly-A tail to the 3 end
  • 3. splice out introns.

26
Capping
  • RNA is inherently unstable, especially at the
    ends. The ends are modified to protect it.
  • At the 5 end, a slightly modified guanine
    (7-methyl G) is attached backwards, by a 5 to
    5 linkage, to the triphosphates of the first
    transcribed base.
  • At the 3 end, the primary transcript RNA is cut
    at a specific site and 100-200 adenine
    nucleotides are attached the poly-A tail. Note
    that these As are not coded in the DNA of the
    gene.

27
hGH several versions of the gene in the genome
1
2
3
4
5
28
hGH several genes in the genome
29
Introns
  • Introns are regions within a gene that dont code
    for protein and dont appear in the final mRNA
    molecule. Protein-coding sections of a gene
    (called exons) are interrupted by introns.
  • The function of introns remains unclear. They
    may help is RNA transport or in control of gene
    expression in some cases, and they may make it
    easier for sections of genes to be shuffled in
    evolution. But , no generally accepted reason
    for the existence of introns exists.
  • There are a few prokaryotic examples, but most
    introns are found in eukaryotes.
  • Some genes have many long introns the dystrophin
    gene (mutants cause muscular dystrophy) has more
    than 70 introns that make up more than 99 of the
    genes sequence. However, not all eukaryotic
    genes have introns histone genes, for example,
    lack introns.

30
Intron Splicing
  • Introns are removed from the primary RNA
    transcript while it is still in the nucleus.
  • Introns are spliced out by RNA/protein hybrids
    called spliceosomes. The intron sequences are
    removed, and the remaining ends are re-attached
    so the final RNA consists of exons only.

31
Eukaryotes Splice Signals
32
Summary of RNA processing
  • In eukaryotes, RNA polymerase produces a primary
    transcript, an exact RNA copy of the gene.
  • A cap is put on the 5 end.
  • The RNA is terminated and poly-A is added to the
    3 end.
  • All introns are spliced out.
  • At this point, the RNA can be called messenger
    RNA. It is then transported out of the nucleus
    into the cytoplasm, where it is translated.

33
hGH1 has many isoforms derived from Alternate
splicing of the hnRNA
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Spliced and correct isoform of gene
Shine-Delgarno
spliced
Sigma Termination sequence
Resistance gene
39
Spliced gene needs ATG and STOP codons
  • The initiation process involves first joining the
    mRNA, the initiator methionine-tRNA, and the
    small ribosomal subunit. Several initiation
    factors--additional proteins--are also involved.
    The large ribosomal subunit then joins the
    complex.

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They did something extra clever.
Shine-Delgarno
spliced
Sigma Termination sequence
Resistance gene
42
They added a signal peptidetwo reasons
43
-secrete protein.to ease purification
-active form of hGH is a cleavage product
44
Use a signal peptide
45
Eukaryotic examples of signal peptides
46
E. Coli
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50
Signal Seq , Truncate Protein
Shine-Delgarno
spliced
Sigma Termination sequence
Resistance gene
51
Post-Translational Modification?
  • New polypeptides usually fold themselves
    spontaneously into their active conformation.
    However, some proteins are helped and guided in
    the folding process by chaperone proteins
  • Many proteins have sugars, phosphate groups,
    fatty acids, and other molecules covalently
    attached to certain amino acids. Most of this is
    done in the endoplasmic reticulum.

52
Mature protein is ready to be purified
53
David Foster will explain to class how to
biochemically purify protein )
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