Post on 01-Jan-2016
description
chapter 17 from gene to protein
A A A A
A A A A A
G
G
G
G
G
G G
G
GT T T
T T T T T
T
C C
C C
C C C
C C
The connection
between genes and proteins• A = Adenine = Base• TACCGCCTAA = Sequence of bases on
DNA• The above sequence of bases is arranged,
not by chance but because it specifies a particular gene
From gene protein …overview
• Transcription: Template strand of DNA is copied/transcribed into another sequence of bases (similar language. Instead of T, U [Uracil] RNA [mRNA])
AUGGCGGAUU This is complimentary,
but not identical to the template DNA
strand
From gene protein …overview
• Translation: Translate DNA/RNA language into a whole new language—amino acid lingo
Translated into triplet code. Each 3 bases is a codon.AUG GCG GAU U….
Each codon specifies a particular amino acid (20
different amino acids)
AUG = “start codon”—specifies amino
acid methionine
AA + AA + AA + AA = polypeptide
polypeptide + polypeptide = protein!!!
• DNA RNA Protein– It’s these proteins
that make us look different
– On the flip side, it’s also a common thread between all living organisms
• DNA is the universal life language– Organisms can
express foreign DNA (E. Coli & insulin; tobacco plant & firefly gene)
Fig. 17-6
(a) Tobacco plant expressing a firefly gene
(b) Pig expressing a jellyfish gene
• Protein Synthesis is slightly different in Prokaryotes–No nucleus—
processes are not separated by space and time as they are in Eukaryotes
BioFlix: Protein Synthesis
From gene protein … the details
DNA RNAA piece of RNA is made or
copied from the template strand of DNA (transcription unit)
A. Initiation 1. Starts at Promoter—
determines which DNA strand will be template and indicates where to begin
- TATA box (upstream)—specific DNA sequence
2. Transcription factors (proteins) and other proteins help bind RNA polymerase to DNA template strand
I. Transcription
Fig. 17-7a-1Promoter Transcription unit
DNAStart point
RNA polymerase
553
3
Fig. 17-7a-2Promoter Transcription unit
DNAStart point
RNA polymerase
553
3
Initiation
33
1
RNAtranscript
5 5
UnwoundDNA
Template strandof DNA
Fig. 17-7a-3Promoter Transcription unit
DNAStart point
RNA polymerase
553
3
Initiation
33
1
RNAtranscript
5 5
UnwoundDNA
Template strandof DNA
2 Elongation
RewoundDNA
5
5 5 3 3 3
RNAtranscript
Fig. 17-7a-4Promoter Transcription unit
DNAStart point
RNA polymerase
553
3
Initiation
33
1
RNAtranscript
5 5
UnwoundDNA
Template strandof DNA
2 Elongation
RewoundDNA
5
5 5 3 3 3
RNAtranscript
3 Termination
5
5 5 33
3Completed RNA transcript
transcription in action
Fig. 17-7b
Elongation
RNApolymerase
Nontemplatestrand of DNA
RNA nucleotides
3 end
Direction oftranscription(“downstream”) Template
strand of DNA
Newly madeRNA
3
5
5
Fig. 17-8A eukaryotic promoterincludes a TATA box
3
1
2
3
Promoter
TATA box Start point
Template
TemplateDNA strand
535
Transcriptionfactors
Several transcription factors mustbind to the DNA before RNApolymerase II can do so.
5533
Additional transcription factors bind tothe DNA along with RNA polymerase II,forming the transcription initiation complex.
RNA polymerase IITranscription factors
55 53
3
RNA transcript
Transcription initiation complex
From gene protein … the details
Transcription factors + RNA polymerase
+ promoter(all bound together)
= Transcription Initiation Complex
RNA polymerase can unwind DNA strand and add RNA nucleotides to 3’ end.
B. Elongation RNA polymerase adds
RNA nucleotides. DNA is open 10-20 bases—reforms as transcript peels away
- can occur one transcript at a time
- or many RNA polymerases following each other down the DNA transcribing more for the production of more RNA and thus, more protein
From gene protein … the details
C. Termination RNA polymerase transcribes a DNA sequence called
the Terminator Eukaryotes – RNA polymerase continues for about
10-35 more bases before transcript separates from RNA polymerase
Prokaryotes – Stop immediately after terminator
From gene protein … the details
Step one in protein synthesisTranscription
Transcription intro
RNA ProcessingIn Eukaryotes – the initial transcript (primary transcript or
pre- mRNA)must be modified prior to leaving the nucleus. it becomes finished mRNA.
1. 5’ end is capped (5’ cap) with a modified guanine nucleotide- protects mRNA from degradation- notifies ribosome where to attach (5’ end)- Facilitates export from the nucleus
2. Poly A tail added to 3’ end (30-200 adenines)- inhibits degradation- helps ribosomes attach to the 5’ end- facilitates export from the nucleus
Fig. 17-9
Protein-coding segment Polyadenylation signal3
3 UTR5 UTR
5
5 Cap Start codon Stop codon Poly-A tail
G P PP AAUAAA AAA AAA…
RNA Processing
3. RNA splicing Original transcript may have 8000 nucleotides – only need about
1200. (avg. polypeptide is 400 amino acids long) – must cut out unneeded RNA- intervening sequences / introns = non-coding sequences of nucleotides- exons = coding regions – will be expressed
*exception- leader and trailer regions – aren’t coding sequences, but aren’t cut out.
Fig. 17-10
Pre-mRNA
mRNA
Codingsegment
Introns cut out andexons spliced together
5 Cap
Exon Intron5
1 30 31 104
Exon Intron
105
Exon
146
3Poly-A tail
Poly-A tail5 Cap
5 UTR 3 UTR1 146
RNA ProcessingSmall nuclear ribonucleoproteins
(snRNPs or “snurps”) recognize specific sites flanking introns
SnRNPs + additional proteins Spliceosome
1. Spliceosome interacts with splice site
2. Cuts out intron 3. Releases intron 4. Joins exons together
Fig. 17-11-1RNA transcript (pre-mRNA)
Exon 1 Exon 2Intron
ProteinsnRNA
snRNPs
Otherproteins
5
Fig. 17-11-2RNA transcript (pre-mRNA)
Exon 1 Exon 2Intron
ProteinsnRNA
snRNPs
Otherproteins
5
5
Spliceosome
Fig. 17-11-3RNA transcript (pre-mRNA)
Exon 1 Exon 2Intron
ProteinsnRNA
snRNPs
Otherproteins
5
5
Spliceosome
Spliceosomecomponents
Cut-outintronmRNA
Exon 1 Exon 25
Ribozymes• Ribozymes are catalytic RNA
molecules; act as enzymes – can splice RNA
• Their discovery disproved the idea that all enzymes are proteins
• Three properties of RNA enable it to function as an enzyme– It can form 3-D 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
**Why introns…….• - have sequences that
control gene activity• - can regulate passage of
mRNA into cytoplasm• - genes can code for 2+
different proteins based on what’s left in and what’s not
•separate exons which may code for different parts of a protein•Organisms can produce more proteins than there are genes•increase chance of crossing over & recombination = increase variation•Exon shuffling may result in the evolution of new proteins
II. TranslationRNA Protein or Codons Amino Acids**Very specific sequences =
DNA RNA amino acids = primary structure
Primary structure determines secondary through quaternary (protein from and function)
DNA TAC GCC CAT
RNA AUG CGG GUA
Amino Acid MET (start)
ARG VAL
MET + ARG + VAL = Polypeptide
Translation and tRNA• tRNA – carries
specific amino acids to site of protein synthesis. How does it know what order to go in?
• Anticodon at the bottom of tRNA is complimentary to a particular mRNA codon (H bond)
• - If mRNA codon is AUG then anticodon is UAC
Fig. 17-14
Amino acidattachment site
3
5
Hydrogenbonds
Anticodon
(a) Two-dimensional structure
Amino acidattachment site
5
3
Hydrogenbonds
3 5AnticodonAnticodon
(c) Symbol used in this book(b) Three-dimensional structure
Translation and tRNA• 61 mRNA codons –
only 45 tRNAs – complimentary binding on 3rd nucleotide isn’t strict= wobble
• - Some have inosine (modified base)– can bind with any base
II. Translation cont..Before tRNA can
shuttle over amino acids, it needs to have the right amino acid attached to it
- Amino acids are joined to correct tRNA by enzyme aminoacyl-tRNA synthetase
- 20 different enzymes for each amino acid
Heading off to the Ribosomes!
• mRNA is made and modified
• tRNA has a correct amino acid…all we need now are ribosomes and then a polypeptide can be made!!!!
Heading to the ribosomes….
~Ribosomes – sites of proteins synthesis; join tRNA and mRNA
- consist of a large and small subunit
- made of rRNA and protein
- 3 main sitesBinding site – where mRNA binds1. P site (peptidyl tRNA) – holds tRNA with growing polypeptide chain2. A site (aminoacyl tRNA) – holds tRNA with new, incoming amino acid3. E site (exit) – empty tRNAs leave from here
Fig. 17-16bP site (Peptidyl-tRNAbinding site) A site (Aminoacyl-
tRNA binding site)E site(Exit site)
mRNAbinding site
Largesubunit
Smallsubunit
(b) Schematic model showing binding sites
Next amino acidto be added topolypeptide chain
Amino end Growing polypeptide
mRNAtRNA
E P A
E
Codons
(c) Schematic model with mRNA and tRNA
5
3
Fig. 17-16a
Growingpolypeptide Exit tunnel
tRNAmolecules
Largesubunit
Smallsubunit
(a) Computer model of functioning ribosome
mRNA
E P A
5 3
Process of TranslationA. Initiation
1. Small ribosomal subunit attaches onto leader sequence of mRNA (5’ end), 5’ cap “tells” ribosome where to bind2. Downstream – AUG = start translation3. tRNA with methionine amino acid attaches to initiation codon AUG – tRNA is in the P site. *All of these together (initiation complex) triggers the attachment of the large ribosomal subunit- initiation factors = proteins that bring them all together
Process of TranslationB. ElongationAmino acids are added and connected with the help
of proteins, elongation factors1.Codon recognition
-Incoming tRNA to A site -Anti-codon + codon complementarily – H bonding2.Peptide bond formation -rRNA molecule in ribosome (ribozyme) – catalyzes the formation of a peptide bond -bond forms between last amino acid of pp chain in the p site and new amino acid in a site -tRNA from p site becomes detached from polypeptide chain
3. Translocation
Fig. 17-18-1
Amino endof polypeptide
mRNA
5
3E
Psite
Asite
Fig. 17-18-2
Amino endof polypeptide
mRNA
5
3E
Psite
Asite
GTP
GDP
E
P A
Fig. 17-18-3
Amino endof polypeptide
mRNA
5
3E
Psite
Asite
GTP
GDP
E
P A
E
P A
Fig. 17-18-4
Amino endof polypeptide
mRNA
5
3E
Psite
Asite
GTP
GDP
E
P A
E
P A
GDPGTP
Ribosome ready fornext aminoacyl tRNA
E
P A
Translation
Process of Translation
C. Termination-Stop codon in a site (UAA, UAG, UGA)-Protein release factor binds to stop codon in A site
Adds water to pp chain – hydrolysis between pp chain and tRNA in P site-Polypeptide chain detaches-Subunits and mRNA come apart
Fig. 17-19-1
Releasefactor
3
5Stop codon(UAG, UAA, or UGA)
Fig. 17-19-2
Releasefactor
3
5Stop codon(UAG, UAA, or UGA)
5
32
Freepolypeptide
2 GDP
GTP
Fig. 17-19-3
Releasefactor
3
5Stop codon(UAG, UAA, or UGA)
5
32
Freepolypeptide
2 GDP
GTP
5
3
Fig. 17-13
Polypeptide
Ribosome
Aminoacids
tRNA withamino acidattached
tRNA
Anticodon
Trp
Phe Gly
Codons 35
mRNA
Translation in Action
And…. ACTION!!
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
Copyright © 2008 Pearson Education Inc., publishing as Pearson Benjamin Cummings
Comparing Gene Expression in Bacteria, Archaea, and Eukarya
• Bacteria and eukarya differ in – their RNA polymerases– termination of transcription– ribosomes
• Archaea & eukarya are simlilar in these respects
• Bacteria simultaneously transcribe & translate the same gene
• In eukarya, transcription & translation are separated (Why?)
• In archaea, transcription and translation are likely coupled
Variations on translation:• Single transcribed mRNA can be used to
make many polypeptides at the same time = polyribosomes
• Bacterial Cells – Translate while transcribing
Fig. 17-24RNA polymerase
DNA
Polyribosome
mRNA
0.25 µmDirection oftranscription
DNA
RNApolymerase
Polyribosome
Polypeptide(amino end)
Ribosome
mRNA (5 end)
Fig. 17-20
Growingpolypeptides
Completedpolypeptide
Incomingribosomalsubunits
Start ofmRNA(5 end)
Polyribosome
End ofmRNA(3 end)
(a)
Ribosomes
mRNA
(b) 0.1 µm
• Free=proteins for cell – remain in cytosol• Bound= proteins of endomembrane system – destined for
export• Translation begins in cytosol• Proteins destined for export have a signal peptide (20 AA
at leading end)• Signal recognition particle (SRP) recognizes signal peptide
SRP brings ribosome to ER for the remainder of protein synthesis
-Free ribosomes vs. bound
Fig. 17-21
Ribosome
mRNA
Signalpeptide
Signal-recognitionparticle (SRP)
CYTOSOL Translocationcomplex
SRPreceptorprotein
ER LUMEN
Signalpeptideremoved
ERmembrane
Protein
Translation in action! More fun than the movies!!!
Mistakes• Mistakes made on
DNA can be good or bad
• Bad: wrong bases=wrong amino acid = wrong protein=lethal
• Good: mutation by accident can lead to advantageous proteins = (lead to variations)
Fig. 17-22
Wild-type hemoglobin DNA
mRNA
Mutant hemoglobin DNA
mRNA
33
3
3
3
3
55
5
55
5
C CT T TTG GA A AA
A A AGG U
Normal hemoglobin Sickle-cell hemoglobin
Glu Val
Point Mutation – Mutation on a single nucleotide
Point mutations – mutations made on the DNA level
1.Substitutions:replacement of one nucleotide
-some are silent – may code for the same amino acid
-some can change aa, but the particular substituted amino acid may not effect quaternary structure
-missense mutation –still codes for an amino acid, but it’s the wrong one
-nonsense mutation – can change an amino acid into a stop codon – short protein
Ex: Sickle Cell Anemia
2.Insertions / Deletions -Frameshift mutation – due to the addition or deletion of a nucleotide, the amino acids making up codons are grouped improperly
(codes are read in 3’s)
THE FAT CAT SAT insert a letter, delete a
letter
All of the above are spontaneous
mutations. There are also mutations
caused by mutagens
Fig. 17-23a
Wild type
3DNA templatestrand
3
355
5mRNA
Protein
Amino end
Stop
Carboxyl end
A instead of G
33
3
U instead of C
55
5
Stop
Silent (no effect on amino acid sequence)
Fig. 17-23b
Wild type
DNA templatestrand
35
mRNA
Protein
5
Amino end
Stop
Carboxyl end
53
3
T instead of C
A instead of G
33
3
5
5
5
Stop
Missense
Fig. 17-23cWild type
DNA templatestrand
35
mRNA
Protein
5
Amino end
Stop
Carboxyl end
53
3
A instead of T
U instead of A
33
3
5
5
5
Stop
Nonsense
Fig. 17-23d
Wild type
DNA templatestrand
35
mRNA
Protein
5
Amino end
Stop
Carboxyl end
53
3
Extra A
Extra U
33
3
5
5
5
Stop
Frameshift causing immediate nonsense (1 base-pair insertion)
Fig. 17-23e
Wild type
DNA templatestrand
35
mRNA
Protein
5
Amino end
Stop
Carboxyl end
53
3
missing
missing
33
3
5
5
5
Frameshift causing extensive missense (1 base-pair deletion)
Fig. 17-23fWild type
DNA templatestrand
35
mRNA
Protein
5
Amino end
Stop
Carboxyl end
53
3
missing
missing
33
3
5
5
5
No frameshift, but one amino acid missing (3 base-pair deletion)
Stop
Fig. 17-23Wild-type
3DNA template strand
5
5
53
3
Stop
Carboxyl endAmino end
Protein
mRNA
33
3
55
5
A instead of G
U instead of C
Silent (no effect on amino acid sequence)
Stop
T instead of C
33
3
55
5
A instead of G
Stop
Missense
A instead of T
U instead of A
33
3
5
5
5
Stop
Nonsense No frameshift, but one amino acid missing (3 base-pair deletion)
Frameshift causing extensive missense (1 base-pair deletion)
Frameshift causing immediate nonsense (1 base-pair insertion)
5
5
533
3
Stop
missing
missing
3
3
3
5
55
missing
missing
Stop
5
5533
3
Extra U
Extra A
(a) Base-pair substitution (b) Base-pair insertion or deletion
You should now be able to:
1. Describe the contributions made by Garrod, Beadle, and Tatum to our understanding of the relationship between genes and enzymes
2. Briefly explain how information flows from gene to protein
3. Compare transcription and translation in bacteria and eukaryotes
4. Explain what it means to say that the genetic code is redundant and unambiguous
Copyright © 2008 Pearson Education Inc., publishing as Pearson Benjamin Cummings
5. Include the following terms in a description of transcription: mRNA, RNA polymerase, the promoter, the terminator, the transcription unit, initiation, elongation, termination, and introns
6. Include the following terms in a description of translation: tRNA, wobble, ribosomes, initiation, elongation, and termination
Copyright © 2008 Pearson Education Inc., publishing as Pearson Benjamin Cummings