1. Chapter 17
From Gene to Protein 1

2. Overview: The Flow of Genetic Information
The information content of DNA is in the form of specific sequences of nucleotides
The DNA inherited by an organism leads to specific traits by dictating the synthesis of proteins
Proteins are the links between genotype and phenotype
Gene expression, the process by which DNA directs protein synthesis, includes two stages: transcription and translation
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3. Fig. 17-1
Figure 17.1 How does a single faulty gene result in the dramatic appearance of an albino deer? 3

4. Concept 17.1: Genes specify proteins via transcription and translation
How was the fundamental relationship between genes and proteins discovered?
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5. The Products of Gene Expression: A Developing Story
Some proteins aren’t enzymes, so researchers later revised the hypothesis: one gene–one protein
Many proteins are composed of several polypeptides, each of which has its own gene
Therefore, Beadle and Tatum’s hypothesis is now restated as the one gene–one polypeptide hypothesis
Note that it is common to refer to gene products as proteins rather than polypeptides
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6. Basic Principles of Transcription and Translation
RNA is the intermediate between genes and the proteins for which they code
Transcription is the synthesis of RNA under the direction of DNA
Transcription produces messenger RNA (mRNA)
Translation is the synthesis of a polypeptide, which occurs under the direction of mRNA
Ribosomes are the sites of translation
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7. In prokaryotes, mRNA produced by transcription is immediately translated without more processing
In a eukaryotic cell, the nuclear envelope separates transcription from translation
Eukaryotic RNA transcripts are modified through RNA processing to yield finished mRNA
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8. A primary transcript is the initial RNA transcript from any gene
The central dogma is the concept that cells are governed by a cellular chain of command: DNA → RNA → protein
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9. Fig. 17-3
DNA
TRANSCRIPTION
mRNA
Ribosome
TRANSLATION
Polypeptide
(a) Bacterial cell
Nuclear
envelope
DNA
TRANSCRIPTION
Pre-mRNA
RNA PROCESSING
Figure 17.3 Overview: the roles of transcription and translation in the flow of genetic information
mRNA
TRANSLATION
Ribosome
Polypeptide
(b) Eukaryotic cell 9

10. DNA TRANSCRIPTION mRNA
Fig. 17-3a-1
DNA
TRANSCRIPTION
mRNA
Figure 17.3 Overview: the roles of transcription and translation in the flow of genetic information
(a) Bacterial cell 10

11. DNA TRANSCRIPTION mRNA Ribosome TRANSLATION Polypeptide
Fig. 17-3a-2
DNA
TRANSCRIPTION
mRNA
Ribosome
TRANSLATION
Polypeptide
Figure 17.3 Overview: the roles of transcription and translation in the flow of genetic information
(a) Bacterial cell 11

12. Nuclear envelope DNA TRANSCRIPTION Pre-mRNA
Fig. 17-3b-1
Nuclear
envelope
DNA
TRANSCRIPTION
Pre-mRNA
Figure 17.3 Overview: the roles of transcription and translation in the flow of genetic information
(b) Eukaryotic cell 12

13. Nuclear envelope DNA TRANSCRIPTION Pre-mRNA mRNA
Fig. 17-3b-2
Nuclear
envelope
DNA
TRANSCRIPTION
Pre-mRNA
RNA PROCESSING
mRNA
Figure 17.3 Overview: the roles of transcription and translation in the flow of genetic information
(b) Eukaryotic cell 13

14. Nuclear envelope DNA TRANSCRIPTION Pre-mRNA mRNA
Fig. 17-3b-3
Nuclear
envelope
DNA
TRANSCRIPTION
Pre-mRNA
RNA PROCESSING
mRNA
Figure 17.3 Overview: the roles of transcription and translation in the flow of genetic information
TRANSLATION
Ribosome
Polypeptide
(b) Eukaryotic cell 14

15. How many bases correspond to an amino acid?
The Genetic Code
How are the instructions for assembling amino acids into proteins encoded into DNA?
There are 20 amino acids, but there are only four nucleotide bases in DNA
How many bases correspond to an amino acid?
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16. Codons: Triplets of Bases
The flow of information from gene to protein is based on a triplet code: a series of nonoverlapping, three-nucleotide words
These triplets are the smallest units of uniform length that can code for all the amino acids
Example: AGT at a particular position on a DNA strand results in the placement of the amino acid serine at the corresponding position of the polypeptide to be produced
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17. During transcription, one of the two DNA strands called the template strand provides a template for ordering the sequence of nucleotides in an RNA transcript
During translation, the mRNA base triplets, called codons, are read in the 5′ to 3′ direction
Each codon specifies the amino acid to be placed at the corresponding position along a polypeptide
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18. Each codon specifies the addition of one of 20 amino acids
Codons along an mRNA molecule are read by translation machinery in the 5′ to 3′ direction
Each codon specifies the addition of one of 20 amino acids
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19. Figure 17.4 The triplet code mRNA
Gene 2
DNA
molecule
Gene 1
Gene 3
DNA
template
strand
TRANSCRIPTION
Figure 17.4 The triplet code
mRNA
Codon
TRANSLATION
Protein
Amino acid 19

20. All 64 codons were deciphered by the mid-1960s
Cracking the Code
All 64 codons were deciphered by the mid-1960s
Of the 64 triplets, 61 code for amino acids; 3 triplets are “stop” signals to end translation
The genetic code is redundant but not ambiguous; no codon specifies more than one amino acid
Codons must be read in the correct reading frame (correct groupings) in order for the specified polypeptide to be produced
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21. Figure 17.5 The dictionary of the genetic code
Second mRNA base
First mRNA base (5′ end of codon)
Third mRNA base (3′ end of codon)
Figure 17.5 The dictionary of the genetic code 21

22. Evolution of the Genetic Code
The genetic code is nearly universal, shared by the simplest bacteria to the most complex animals
Genes can be transcribed and translated after being transplanted from one species to another
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23. (a) Tobacco plant expressing a firefly gene (b) Pig expressing a
Fig. 17-6
Figure 17.6 Expression of genes from different species
(a) Tobacco plant expressing
a firefly gene
(b) Pig expressing a
jellyfish gene 23

24. Concept 17.2: Transcription is the DNA-directed synthesis of RNA: a closer look
Transcription, the first stage of gene expression, can be examined in more detail
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25. Molecular Components of Transcription
RNA synthesis is catalyzed by RNA polymerase, which pries the DNA strands apart and hooks together the RNA nucleotides
RNA synthesis follows the same base-pairing rules as DNA, except uracil substitutes for thymine
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26. The stretch of DNA that is transcribed is called a transcription unit
The DNA sequence where RNA polymerase attaches is called the promoter; in bacteria, the sequence signaling the end of transcription is called the terminator
The stretch of DNA that is transcribed is called a transcription unit
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27. Fig. 17-7
Promoter
Transcription unit 5′ 3′ 3′ 5′
DNA
Start point
RNA polymerase 1
Initiation
Elongation
Nontemplate
strand of DNA
RNA nucleotides 5′ 3′
RNA
polymerase 3′ 5′
RNA
transcript
Template strand
of DNA
Unwound
DNA 3′ 2
Elongation
3′ end
Rewound
DNA 5′ 5′ 3′ 3′ 3′ 5′ 5′
Figure 17.7 The stages of transcription: initiation, elongation, and termination 5′
Direction of
transcription
(“downstream”)
RNA
transcript
Template
strand of DNA 3
Termination
Newly made
RNA 5′ 3′ 3′ 5′ 5′ 3′
Completed RNA transcript 27

28. Fig. 17-7a-1
Promoter
Transcription unit 5′ 3′ 3′ 5′
DNA
Start point
RNA polymerase
Figure 17.7 The stages of transcription: initiation, elongation, and termination 28

29. Fig. 17-7a-2
Promoter
Transcription unit 5′ 3′ 3′ 5′
DNA
Start point
RNA polymerase 1
Initiation 5′ 3′ 3′ 5′
RNA
transcript
Template strand
of DNA
Unwound
DNA
Figure 17.7 The stages of transcription: initiation, elongation, and termination 29

30. Fig. 17-7a-3
Promoter
Transcription unit 5′ 3′ 3′ 5′
DNA
Start point
RNA polymerase 1
Initiation 5′ 3′ 3′ 5′
RNA
transcript
Template strand
of DNA
Unwound
DNA 2
Elongation
Rewound
DNA 5′ 3′ 3′ 3′ 5′
Figure 17.7 The stages of transcription: initiation, elongation, and termination 5′
RNA
transcript 30

31. Fig. 17-7a-4
Promoter
Transcription unit 5′ 3′ 3′ 5′
DNA
Start point
RNA polymerase 1
Initiation 5′ 3′ 3′ 5′
RNA
transcript
Template strand
of DNA
Unwound
DNA 2
Elongation
Rewound
DNA 5′ 3′ 3′ 3′ 5′
Figure 17.7 The stages of transcription: initiation, elongation, and termination 5′
RNA
transcript 3
Termination 5′ 3′ 3′ 5′ 5′ 3′
Completed RNA transcript 31

32. Nontemplate Elongation strand of DNA RNA nucleotides RNA polymerase 3′
Fig. 17-7b
Elongation
Nontemplate
strand of DNA
RNA nucleotides
RNA
polymerase 3′
3′ end 5′
Figure 17.7 The stages of transcription: initiation, elongation, and termination 5′
Direction of
transcription
(“downstream”)
Template
strand of DNA
Newly made
RNA 32

33. Synthesis of an RNA Transcript
The three stages of transcription:
Initiation
Elongation
Termination
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34. RNA Polymerase Binding and Initiation of Transcription
Promoters signal the initiation of RNA synthesis
Transcription factors mediate the binding of RNA polymerase and the initiation of transcription
The completed assembly of transcription factors and RNA polymerase II bound to a promoter is called a transcription initiation complex
A promoter called a TATA box is crucial in forming the initiation complex in eukaryotes
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35. Several transcription factors must bind to the DNA before RNA
Fig. 17-8 1
A eukaryotic promoter
includes a TATA box
Promoter
Template 5′ 3′ 3′ 5′
TATA box
Start point
Template
DNA strand 2
Several transcription factors must
bind to the DNA before RNA
polymerase II can do so.
Transcription
factors 5′ 3′ 3′ 5′ 3
Additional transcription factors bind to
the DNA along with RNA polymerase II,
forming the transcription initiation complex.
Figure 17.8 The initiation of transcription at a eukaryotic promoter
RNA polymerase II
Transcription factors 5′ 3′ 3′ 5′ 5′
RNA transcript
Transcription initiation complex 35

36. Elongation of the RNA Strand
As RNA polymerase moves along the DNA, it untwists the double helix, 10 to 20 bases at a time
Transcription progresses at a rate of 40 nucleotides per second in eukaryotes
A gene can be transcribed simultaneously by several RNA polymerases
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37. Termination of Transcription
The mechanisms of termination are different in bacteria and eukaryotes
In bacteria, the polymerase stops transcription at the end of the terminator
In eukaryotes, the polymerase continues transcription after the pre-mRNA is cleaved from the growing RNA chain; the polymerase eventually falls off the DNA
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38. Concept 17.3: Eukaryotic cells modify RNA after transcription
Enzymes in the eukaryotic nucleus modify pre-mRNA before the genetic messages are dispatched to the cytoplasm
During RNA processing, both ends of the primary transcript are usually altered
Also, usually some interior parts of the molecule are cut out, and the other parts spliced together
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39. Alteration of mRNA Ends
Each end of a pre-mRNA molecule is modified in a particular way:
The 5′ end receives a modified nucleotide 5′ cap
The 3′ end gets a poly-A tail
These modifications share several functions:
They seem to facilitate the export of mRNA
They protect mRNA from hydrolytic enzymes
They help ribosomes attach to the 5′ end
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40. Protein-coding segment Polyadenylation signal 5′ 3′
Fig. 17-9
Protein-coding segment
Polyadenylation signal 5′ 3′ G P P P
AAUAAA
AAA …
AAA
5′ Cap
5′ UTR
Start codon
Stop codon
3′ UTR
Poly-A tail
Figure 17.9 RNA processing: addition of the 5′ cap and poly-A tail 40

41. Split Genes and RNA Splicing
Most eukaryotic genes and their RNA transcripts have long noncoding stretches of nucleotides that lie between coding regions
These noncoding regions are called intervening sequences, or introns
The other regions are called exons because they are eventually expressed, usually translated into amino acid sequences
RNA splicing removes introns and joins exons, creating an mRNA molecule with a continuous coding sequence
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42. exons spliced together Coding segment
Fig 5′
Exon
Intron
Exon
Intron
Exon 3′
Pre-mRNA
5′ Cap
Poly-A tail 1 30 31
104
105
146
Introns cut out and
exons spliced together
Coding
segment
mRNA
5′ Cap
Poly-A tail 1
146
Figure RNA processing: RNA splicing
5′ UTR
3′ UTR 42

43. In some cases, RNA splicing is carried out by spliceosomes
Spliceosomes consist of a variety of proteins and several small nuclear ribonucleoproteins (snRNPs) that recognize the splice sites
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44. RNA transcript (pre-mRNA) 5′ Exon 1 Intron Exon 2
Fig
RNA transcript (pre-mRNA) 5′
Exon 1
Intron
Exon 2
Protein
Other
proteins
snRNA
snRNPs
Figure The roles of snRNPs and spliceosomes in pre-mRNA splicing 44

45. RNA transcript (pre-mRNA) 5′ Exon 1 Intron Exon 2
Fig
RNA transcript (pre-mRNA) 5′
Exon 1
Intron
Exon 2
Protein
Other
proteins
snRNA
snRNPs
Spliceosome 5′
Figure The roles of snRNPs and spliceosomes in pre-mRNA splicing 45

46. RNA transcript (pre-mRNA) 5′ Exon 1 Intron Exon 2
Fig
RNA transcript (pre-mRNA) 5′
Exon 1
Intron
Exon 2
Protein
Other
proteins
snRNA
snRNPs
Spliceosome 5′
Figure The roles of snRNPs and spliceosomes in pre-mRNA splicing
Spliceosome
components
Cut-out
intron
mRNA 5′
Exon 1
Exon 2 46

47. Ribozymes
Ribozymes are catalytic RNA molecules that function as enzymes and can splice RNA
The discovery of ribozymes rendered obsolete the belief that all biological catalysts were proteins
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48. Three properties of RNA enable it to function as an enzyme
It can form a three-dimensional structure because of its ability to base pair with itself
Some bases in RNA contain functional groups
RNA may hydrogen-bond with other nucleic acid molecules
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49. The Functional and Evolutionary Importance of Introns
Some genes can encode more than one kind of polypeptide, depending on which segments are treated as exons during RNA splicing
Such variations are called alternative RNA splicing
Because of alternative splicing, the number of different proteins an organism can produce is much greater than its number of genes
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50. Exon shuffling may result in the evolution of new proteins
Proteins often have a modular architecture consisting of discrete regions called domains
In many cases, different exons code for the different domains in a protein
Exon shuffling may result in the evolution of new proteins
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51. Figure 17.12 Correspondence between exons and protein domains
Gene
DNA
Exon 1
Intron
Exon 2
Intron
Exon 3
Transcription
RNA processing
Translation
Domain 3
Figure Correspondence between exons and protein domains
Domain 2
Domain 1
Polypeptide 51

52. The translation of mRNA to protein can be examined in more detail
Concept 17.4: Translation is the RNA-directed synthesis of a polypeptide: a closer look
The translation of mRNA to protein can be examined in more detail
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53. Molecular Components of Translation
A cell translates an mRNA message into protein with the help of transfer RNA (tRNA)
Molecules of tRNA are not identical:
Each carries a specific amino acid on one end
Each has an anticodon on the other end; the anticodon base-pairs with a complementary codon on mRNA
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54. Figure 17.13 Translation: the basic concept tRNA
Amino
acids
Polypeptide
tRNA with
amino acid
attached
Ribosome
Trp
Phe
Gly
Figure Translation: the basic concept
tRNA
Anticodon 5′
Codons 3′
mRNA 54

55. The Structure and Function of Transfer RNA
A tRNA molecule consists of a single RNA strand that is only about 80 nucleotides long
Flattened into one plane to reveal its base pairing, a tRNA molecule looks like a cloverleaf A C C
For the Cell Biology Video A Stick and Ribbon Rendering of a tRNA, go to Animation and Video Files.
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56. Figure 17.14 The structure of transfer RNA (tRNA)3′
Amino acid
attachment site 5′
Hydrogen
bonds
Anticodon
(a) Two-dimensional structure 5′
Amino acid
attachment site 3′
Figure The structure of transfer RNA (tRNA)
Hydrogen
bonds 3′ 5′
Anticodon
Anticodon
(c) Symbol used
in this book
(b) Three-dimensional structure 56

57. Figure 17.14 The structure of transfer RNA (tRNA)
Fig a 3′
Amino acid
attachment site 5′
Hydrogen
bonds
Figure The structure of transfer RNA (tRNA)
Anticodon
(a) Two-dimensional structure 57

58. Figure 17.14 The structure of transfer RNA (tRNA) 3′ 5′
Fig b
Amino acid
attachment site 5′ 3′
Hydrogen
bonds
Figure The structure of transfer RNA (tRNA) 3′ 5′
Anticodon
Anticodon
(c) Symbol used
in this book
(b) Three-dimensional structure 58

59. tRNA is roughly L-shaped
Because of hydrogen bonds, tRNA actually twists and folds into a three-dimensional molecule
tRNA is roughly L-shaped
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60. Accurate translation requires two steps:
First: a correct match between a tRNA and an amino acid, done by the enzyme aminoacyl- tRNA synthetase
Second: a correct match between the tRNA anticodon and an mRNA codon
Flexible pairing at the third base of a codon is called wobble and allows some tRNAs to bind to more than one codon
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61. Fig
Aminoacyl-tRNA
synthetase (enzyme)
Amino acid P P P
Adenosine
ATP
Figure An aminoacyl-tRNA synthetase joining a specific amino acid to a tRNA 61

62. Fig
Aminoacyl-tRNA
synthetase (enzyme)
Amino acid P P P
Adenosine
ATP P
Adenosine P P i P i P i
Figure An aminoacyl-tRNA synthetase joining a specific amino acid to a tRNA 62

63. Fig
Aminoacyl-tRNA
synthetase (enzyme)
Amino acid P P P
Adenosine
ATP P
Adenosine
tRNA P P i
Aminoacyl-tRNA
synthetase P i P i
tRNA
Figure An aminoacyl-tRNA synthetase joining a specific amino acid to a tRNA P
Adenosine
AMP
Computer model 63

64. Fig
Aminoacyl-tRNA
synthetase (enzyme)
Amino acid P P P
Adenosine
ATP P
Adenosine
tRNA P P i
Aminoacyl-tRNA
synthetase P i P i
tRNA
Figure An aminoacyl-tRNA synthetase joining a specific amino acid to a tRNA P
Adenosine
AMP
Computer model
Aminoacyl-tRNA
(“charged tRNA”) 64

65. Ribosomes
Ribosomes facilitate specific coupling of tRNA anticodons with mRNA codons in protein synthesis
The two ribosomal subunits (large and small) are made of proteins and ribosomal RNA (rRNA)
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66. A ribosome has three binding sites for tRNA:
The P site holds the tRNA that carries the growing polypeptide chain
The A site holds the tRNA that carries the next amino acid to be added to the chain
The E site is the exit site, where discharged tRNAs leave the ribosome
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67. Building a Polypeptide
The three stages of translation:
Initiation
Elongation
Termination
All three stages require protein “factors” that aid in the translation process
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68. Ribosome Association and Initiation of Translation
The initiation stage of translation brings together mRNA, a tRNA with the first amino acid, and the two ribosomal subunits
First, a small ribosomal subunit binds with mRNA and a special initiator tRNA
Then the small subunit moves along the mRNA until it reaches the start codon (AUG)
Proteins called initiation factors bring in the large subunit that completes the translation initiation complex
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69. Figure 17.17 The initiation of translation Small ribosomal subunit
Large
ribosomal
subunit 3′ U C 5′ A
P site
Met 5′ A
Met U G 3′
Initiator
tRNA
GTP
GDP E A
mRNA 5′ 5′ 3′ 3′
Start codon
Figure The initiation of translation
Small
ribosomal
subunit
mRNA binding site
Translation initiation complex 69

70. Elongation of the Polypeptide Chain
During the elongation stage, amino acids are added one by one to the preceding amino acid
Each addition involves proteins called elongation factors and occurs in three steps: codon recognition, peptide bond formation, and translocation
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71. Figure 17.18 The elongation cycle of translation
Amino end
of polypeptide E 3′
mRNA P
site A
site 5′
Figure The elongation cycle of translation 71

72. Figure 17.18 The elongation cycle of translation
Amino end
of polypeptide E 3′
mRNA P
site A
site 5′
GTP
GDP E P A
Figure The elongation cycle of translation 72

73. Figure 17.18 The elongation cycle of translation
Amino end
of polypeptide E 3′
mRNA P
site A
site 5′
GTP
GDP E P A
Figure The elongation cycle of translation E P A 73

74. Figure 17.18 The elongation cycle of translation
Amino end
of polypeptide E 3′
mRNA
Ribosome ready for
next aminoacyl tRNA P
site A
site 5′
GTP
GDP E E P A P A
Figure The elongation cycle of translation
GDP
GTP E P A 74

75. Termination of Translation
Termination occurs when a stop codon in the mRNA reaches the A site of the ribosome
The A site accepts a protein called a release factor
The release factor causes the addition of a water molecule instead of an amino acid
This reaction releases the polypeptide, and the translation assembly then comes apart
Animation: Translation
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76. Figure 17.19 The termination of translation
Release
factor 3′ 5′
Stop codon
(UAG, UAA, or UGA)
Figure The termination of translation 76

77. Figure 17.19 The termination of translation
Release
factor
Free
polypeptide 3′ 3′ 2 5′ 5′
GTP
Stop codon
(UAG, UAA, or UGA)
2 GDP
Figure The termination of translation 77

78. Figure 17.19 The termination of translation
Release
factor
Free
polypeptide 5′ 3′ 3′ 3′ 2 5′ 5′
GTP
Stop codon
(UAG, UAA, or UGA)
2 GDP
Figure The termination of translation 78

79. Polyribosomes
A number of ribosomes can translate a single mRNA simultaneously, forming a polyribosome (or polysome)
Polyribosomes enable a cell to make many copies of a polypeptide very quickly
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80. Completed polypeptide Growing polypeptides Incoming ribosomal subunits
Fig
Completed
polypeptide
Growing
polypeptides
Incoming
ribosomal
subunits
Polyribosome
Start of
mRNA
(5′ end)
End of
mRNA
(3′ end)
(a)
Ribosomes
Figure Polyribosomes
mRNA
(b)
0.1 µm 80

81. Completing and Targeting the Functional Protein
Often translation is not sufficient to make a functional protein
Polypeptide chains are modified after translation
Completed proteins are targeted to specific sites in the cell
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82. Protein Folding and Post-Translational Modifications
During and after synthesis, a polypeptide chain spontaneously coils and folds into its three-dimensional shape
Proteins may also require post-translational modifications before doing their job
Some polypeptides are activated by enzymes that cleave them
Other polypeptides come together to form the subunits of a protein
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83. Targeting Polypeptides to Specific Locations
Two populations of ribosomes are evident in cells: free ribsomes (in the cytosol) and bound ribosomes (attached to the ER)
Free ribosomes mostly synthesize proteins that function in the cytosol
Bound ribosomes make proteins of the endomembrane system and proteins that are secreted from the cell
Ribosomes are identical and can switch from free to bound
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84. Polypeptide synthesis always begins in the cytosol
Synthesis finishes in the cytosol unless the polypeptide signals the ribosome to attach to the ER
Polypeptides destined for the ER or for secretion are marked by a signal peptide
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85. A signal-recognition particle (SRP) binds to the signal peptide
The SRP brings the signal peptide and its ribosome to the ER
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86. Figure 17.21 The signal mechanism for targeting proteins to the ER
Ribosome
mRNA
Signal
peptide ER
membrane
Signal
peptide
removed
Signal-
recognition
particle (SRP)
Protein
CYTOSOL
Translocation
complex
Figure The signal mechanism for targeting proteins to the ER
ER LUMEN
SRP
receptor
protein 86

87. Mutations are changes in the genetic material of a cell or virus
Concept 17.5: Point mutations can affect protein structure and function
Mutations are changes in the genetic material of a cell or virus
Point mutations are chemical changes in just one base pair of a gene
The change of a single nucleotide in a DNA template strand can lead to the production of an abnormal protein
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88. Wild-type hemoglobin DNA Mutant hemoglobin DNA 3′ C T T 5′ 3′ C A T 5′
Fig
Wild-type hemoglobin DNA
Mutant hemoglobin DNA 3′ C T T 5′ 3′ C A T 5′ 5′ G A A 3′ 5′ G T A 3′
mRNA
mRNA 5′ G A A 3′ 5′ G U A 3′
Figure The molecular basis of sickle-cell disease: a point mutation
Normal hemoglobin
Sickle-cell hemoglobin
Glu
Val 88

89. Types of Point Mutations
Point mutations within a gene can be divided into two general categories
Base-pair substitutions
Base-pair insertions or deletions
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90. Figure 17.23 Types of point mutations
Wild-type
DNA template strand 3′ 5′ 5′ 3′
mRNA 5′ 3′
Protein
Stop
Amino end
Carboxyl end
A instead of G
Extra A 3′ 5′ 3′ 5′ 5′ 3′ 5′ 3′
U instead of C
Extra U 5′ 3′ 5′ 3′
Stop
Stop
Silent (no effect on amino acid sequence)
Frameshift causing immediate nonsense (1 base-pair insertion)
T instead of C
missing 3′ 5′ 3′ 5′ 5′ 3′ 5′ 3′
A instead of G
missing 5′ 3′ 5′ 3′
Stop
Figure Types of point mutations
Missense
Frameshift causing extensive missense (1 base-pair deletion)
A instead of T
missing 3′ 5′ 3′ 5′ 5′ 3′ 5′ 3′
U instead of A
missing 5′ 3′ 5′ 3′
Stop
Stop
Nonsense
No frameshift, but one amino acid missing (3 base-pair deletion)
(a) Base-pair substitution
(b) Base-pair insertion or deletion 90

91. Silent (no effect on amino acid sequence)
Fig a
Wild type
DNA template
strand 3′ 5′ 5′ 3′
mRNA 5′ 3′
Protein
Stop
Amino end
Carboxyl end
A instead of G 3′ 5′ 5′ 3′
Figure Types of point mutations
U instead of C 5′ 3′
Stop
Silent (no effect on amino acid sequence) 91

92. Wild type DNA template strand 3′ 5′ 5′ 3′ mRNA 5′ 3′ Protein Stop
Fig b
Wild type
DNA template
strand 3′ 5′ 5′ 3′
mRNA 5′ 3′
Protein
Stop
Amino end
Carboxyl end
T instead of C 3′ 5′ 5′ 3′
Figure Types of point mutations
A instead of G 5′ 3′
Stop
Missense 92

93. Wild type DNA template strand 3′ 5′ 5′ 3′ mRNA 5′ 3′ Protein Stop
Fig c
Wild type
DNA template
strand 3′ 5′ 5′ 3′
mRNA 5′ 3′
Protein
Stop
Amino end
Carboxyl end
A instead of T 3′ 5′ 5′ 3′
Figure Types of point mutations
U instead of A 5′ 3′
Stop
Nonsense 93

94. Frameshift causing immediate nonsense (1 base-pair insertion)
Fig d
Wild type
DNA template
strand 3′ 5′ 5′ 3′
mRNA 5′ 3′
Protein
Stop
Amino end
Carboxyl end
Extra A 3′ 5′ 5′ 3′
Figure Types of point mutations
Extra U 5′ 3′
Stop
Frameshift causing immediate nonsense (1 base-pair insertion) 94

95. Frameshift causing extensive missense (1 base-pair deletion)
Fig e
Wild type
DNA template
strand 3′ 5′ 5′ 3′
mRNA 5′ 3′
Protein
Stop
Amino end
Carboxyl end
missing 3′ 5′ 5′ 3′
Figure Types of point mutations
missing 5′ 3′
Frameshift causing extensive missense (1 base-pair deletion) 95

96. Wild type DNA template strand 3′ 5′ 5′ 3′ mRNA 5′ 3′ Protein Stop
Fig f
Wild type
DNA template
strand 3′ 5′ 5′ 3′
mRNA 5′ 3′
Protein
Stop
Amino end
Carboxyl end
missing 3′ 5′ 5′ 3′
Figure Types of point mutations
missing 5′ 3′
Stop
No frameshift, but one amino acid missing (3 base-pair deletion) 96

97. Substitutions
A base-pair substitution replaces one nucleotide and its partner with another pair of nucleotides
Silent mutations have no effect on the amino acid produced by a codon because of redundancy in the genetic code
Missense mutations still code for an amino acid, but not necessarily the right amino acid
Nonsense mutations change an amino acid codon into a stop codon, nearly always leading to a nonfunctional protein
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98. Insertions and Deletions
Insertions and deletions are additions or losses of nucleotide pairs in a gene
These mutations have a disastrous effect on the resulting protein more often than substitutions do
Insertion or deletion of nucleotides may alter the reading frame, producing a frameshift mutation
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99. Mutagens are physical or chemical agents that can cause mutations
Spontaneous mutations can occur during DNA replication, recombination, or repair
Mutagens are physical or chemical agents that can cause mutations
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100. Concept 17.6: While gene expression differs among the domains of life, the concept of a gene is universal
Archaea are prokaryotes, but share many features of gene expression with eukaryotes
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101. Comparing Gene Expression in Bacteria, Archaea, and Eukarya
Bacteria and eukarya differ in their RNA polymerases, termination of transcription and ribosomes; archaea tend to resemble eukarya in these respects
Bacteria can simultaneously transcribe and translate the same gene
In eukarya, transcription and translation are separated by the nuclear envelope
In archaea, transcription and translation are likely coupled
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102. Figure 17.24 Coupled transcription and translation in bacteria
RNA polymerase
DNA
mRNA
Polyribosome
Direction of
transcription
0.25 µm
RNA
polymerase
DNA
Figure Coupled transcription and translation in bacteria
Polyribosome
Polypeptide
(amino end)
Ribosome
mRNA (5′ end)
102

103. What Is a Gene? Revisiting the Question
The idea of the gene itself is a unifying concept of life
We have considered a gene as:
A discrete unit of inheritance
A region of specific nucleotide sequence in a chromosome
A DNA sequence that codes for a specific polypeptide chain
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103

104. Fig
DNA
TRANSCRIPTION 3′
Poly-A
RNA
polymerase 5′
RNA
transcript
RNA PROCESSING
Exon
RNA transcript
(pre-mRNA)
Intron
Aminoacyl-tRNA
synthetase
Poly-A
NUCLEUS
Amino
acid
AMINO ACID ACTIVATION
CYTOPLASM
tRNA
mRNA
Growing
polypeptide
Cap 3′ A
Activated
amino acid
Poly-A P
Ribosomal
subunits
Figure A summary of transcription and translation in a eukaryotic cell E
Cap 5′
TRANSLATION E A
Anticodon
Codon
Ribosome
104

105. In summary, a gene can be defined as a region of DNA that can be expressed to produce a final functional product, either a polypeptide or an RNA molecule
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106. Transcription unit Promoter 5′ 3′ 3′ 3′ 5′ 5′ Template strand of DNA
Fig. 17-UN1
Transcription unit
Promoter 5′ 3′ 3′ 3′ 5′ 5′
Template strand
of DNA
RNA polymerase
RNA transcript
106

107. Fig. 17-UN2
Pre-mRNA
Cap
Poly-A tail
mRNA
107

108. Fig. 17-UN3
mRNA
Ribosome
Polypeptide
108

109. Fig. 17-UN4
109

110. Fig. 17-UN5
110

111. Fig. 17-UN6
111

112. Fig. 17-UN7
112

113. Fig. 17-UN8
113

114. You should now be able to:
Describe the contributions made by Garrod, Beadle, and Tatum to our understanding of the relationship between genes and enzymes
Briefly explain how information flows from gene to protein
Compare transcription and translation in bacteria and eukaryotes
Explain what it means to say that the genetic code is redundant and unambiguous
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115. Include the following terms in a description of transcription: mRNA, RNA polymerase, the promoter, the terminator, the transcription unit, initiation, elongation, termination, and introns
Include the following terms in a description of translation: tRNA, wobble, ribosomes, initiation, elongation, and termination
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