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Messenger RNA

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Chapter 7 Messenger RNA 7.1 Introduction All three types of RNA are central players during the process of gene expression. 7.2 mRNA Is Produced by Transcription and ... – PowerPoint PPT presentation

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Title: Messenger RNA


1
Chapter 7
  • Messenger RNA

2
7.1 Introduction
  • All three types of RNA are central players during
    the process of gene expression.

Figure 7.01 Protein synthesis uses three types
of RNA.
3
7.2 mRNA Is Produced by Transcription and Is
Translated
  • Within a gene, only one of the two strands of DNA
    is transcribed into RNA.

Figure 7.02 Gene expression transcription
translation.
4
7.3 The Secondary Structure of Transfer RNA Is a
Cloverleaf
  • A tRNA has a sequence of 74 to 95 bases that
    folds into a cloverleaf secondary structure with
    four constant arms (and an additional arm in the
    longer tRNAs).
  • tRNA is charged to form aminoacyl-tRNA by forming
    an ester link from the 2' or 3' OH group of the
    adenylic acid at the end of the acceptor arm to
    the COOH group of the amino acid.

5
7.3 The Secondary Structure of Transfer RNA Is a
Cloverleaf
Figure 7.03 tRNA is an adaptor.
6
7.3 The Secondary Structure of Transfer RNA Is a
Cloverleaf
  • The sequence of the anticodon is solely
    responsible for the specificity of the
    aminoacyl-tRNA during translation.

7
7.3 The Secondary Structure of Transfer RNA Is a
Cloverleaf
Figure 7.05 The anticodon determines tRNA
specificity.
8
7.4 The Acceptor Stem and Anticodon Are at
Opposite Ends of the tRNA Tertiary Structure
  • The cloverleaf forms an L-shaped tertiary
    structure with the acceptor arm at one end and
    the anticodon arm at the other end.

9
7.4 The Acceptor Stem and Anticodon Are at
Opposite Ends of the tRNA Tertiary Structure
Figure 7.06 All tRNAs share a tertiary structure.
10
7.5 Messenger RNA Is Translated by Ribosomes
  • Ribosomes are characterized by their rate of
    sedimentation.
  • 70S for bacterial ribosomes and 80S for
    eukaryotic ribosomes.
  • A ribosome consists of a
  • large subunit (50S or 60S for bacteria and
    eukaryotes)
  • small subunit (30S or 40S)
  • The ribosome provides the environment in which
    aminoacyl-tRNAs add amino acids to the growing
    polypeptide chain in response to the
    corresponding triplet codons.
  • A ribosome moves along an mRNA from 5' to 3'.

11
7.5 Messenger RNA Is Translated by Ribosomes
Figure 7.08 Ribosomes dissociate into subunits.
12
7.6 Many Ribosomes Can Bind to One mRNA
  • An mRNA is simultaneously translated by several
    ribosomes.
  • Each ribosome is at a different stage of
    progression along the mRNA.

Figure 7.09 Each ribosome has a
polypeptidyl-tRNA and an aminoacyl-tRNA.
13
Figure 7.10 Hemoglobin is synthesized on
pentasomes.
Photo courtesy of Alexander Rich, Massachusetts
Institute of Technology
14
Figure 7.11 Ribosomes recycle for translation.
15
Figure 7.12 30 of bacterial dry mass is
concerned with gene expression.
16
7.7 The Cycle of Bacterial Messenger RNA
  • Transcription and translation occur
    simultaneously in bacteria.
  • Ribosomes begin translating an mRNA before its
    synthesis has been completed.
  • Bacterial mRNA is unstable and has a half-life of
    only a few minutes.

17
7.7 The Cycle of Bacterial Messenger RNA
Figure 7.13 Trancription - translation -
degradation.
18
7.7 The Cycle of Bacterial Messenger RNA
  • A bacterial mRNA may be polycistronic in having
    several coding regions that represent different
    genes.

Figure 7.15 Bacterial mRNA is polycistronic.
19
7.8 Eukaryotic mRNA Is Modified During or after
Its Transcription
  • A eukaryotic mRNA transcript is modified in the
    nucleus during or shortly after transcription.
  • The modifications include the addition of a
    methylated cap at the 5' end and a sequence of
    poly(A) at the 3' end.

20
7.8 Eukaryotic mRNA Is Modified During or after
Its Transcription
Figure 7.16 Eukaryotic mRNA is modified at both
ends.
21
7.8 Eukaryotic mRNA Is Modified During or after
Its Transcription
  • The mRNA is exported from the nucleus to the
    cytoplasm only after all modifications have been
    completed.

22
7.8 Eukaryotic mRNA Is Modified During or after
Its Transcription
Figure 7.17 Eukaryotic mRNA is modified and
exported.
23
7.9 The 5 End of Eukaryotic mRNA Is Capped
  • A 5' cap is formed by adding a G to the terminal
    base of the transcript via a 5'5' link.
  • One to three methyl groups are added to the base
    or ribose of the new terminal guanosine.

24
7.9 The 5 End of Eukaryotic mRNA Is Capped
Figure 7.18 Eukaryotic mRNA has a methylated 5'
cap.
25
7.10 The 3 Terminus of Eukaryotic mRNA Is
Polyadenylated
  • A length of poly(A) 200 nucleotides long is
    added to a nuclear transcript after
    transcription.
  • The poly(A) is bound by a specific protein
    (PABP).
  • The poly(A) stabilizes the mRNA against
    degradation.

26
7.11 Bacterial mRNA Degradation Involves Multiple
Enzymes
  • The overall direction of degradation of bacterial
    mRNA is 5'3'.
  • Degradation results from the combination of
    endonucleolytic cleavages followed by
    exonucleolytic degradation of the fragment from
    3'?5'.

27
7.11 Bacterial mRNA Degradation Involves Multiple
Enzymes
Figure 7.19 mRNA is degraded by exo- and endo-
nucleases.
28
7.12 Two Pathways Degrade Eukaryotic mRNA
  • The modifications at both ends of mRNA protect it
    against degradation by exonucleases.
  • Specific sequences within an mRNA may have
    stabilizing or destabilizing effects.
  • Destabilization may be triggered by loss of
    poly(A).

29
7.12 Two Pathways Degrade Eukaryotic mRNA
Figure 7.20 The structure and sequence of
eukaryotic mRNA determine stability.
30
Figure 7.21 An ARE in a 3 nontranslated region
initiates degradation of mRNA.
31
7.12 Two Pathways Degrade Eukaryotic mRNA
  • Degradation of yeast mRNA requires removal of the
    5' cap and the 3' poly(A).

Figure 7.22 Deadenylation allows decappaing to
occur, which leads
endonucleolytic cleavage from the 5 end.
32
7.12 Two Pathways Degrade Eukaryotic mRNA
  • One yeast pathway involves exonucleolytic
    degradation from 5'?3'.
  • Another yeast pathway uses a complex of several
    exonucleases that work in the 3'?5' direction.
  • The deadenylase of animal cells may bind directly
    to the 5' cap.
  • Either mutation causes slower degradation of
    mRNA, but loss of both pathways is lethal in
    yeast.

33
Figure 7.23 The 3'-5' pathway has three stages.
34
7.13 Nonsense Mutations Trigger a Surveillance
System
  • Nonsense mutations cause mRNA to be degraded.
  • Genes coding for the degradation system have been
    found in yeast and worms.

35
7.13 Nonsense Mutations Trigger a Surveillance
System
Figure 7.24 A surveillance system degrades
mutant mRNA.
36
Figure 7.25 Splicing junctions are marked by
proteins.
37
7.14 Eukaryotic RNAs Are Transported
  • RNA is transported through a membrane as a
    ribonucleoprotein particle.
  • All eukaryotic RNAs that function in the
    cytoplasm must be exported from the nucleus.
  • tRNAs and the RNA component of a ribonuclease are
    imported into mitochondria.
  • mRNAs can travel long distances between plant
    cells.

38
7.14 Eukaryotic RNAs Are Transported
Figure 7.26 Eukaryotic RNA can be transported
between cell compartments.
39
7.15 mRNA Can Be Localized Within A Cell
  • Yeast ASH1 mRNA forms a ribonucleoprotein that
    binds to a myosin motor.
  • A motor transports it along actin filaments into
    the daughter bud.
  • It is anchored and translated in the bud, so that
    the protein is found only in the bud.

40
7.15 mRNA Can Be Localized Within A Cell
Figure 7.27 ASH1 mRNA is connected to a motor.
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