A. Amino Acid and Protein Structure B. Formation of Aminoacyl tRNAs C. Ribosome structure D. Stages...

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A. Amino Acid and Protein Structure B. Formation of Aminoacyl tRNAs C. Ribosome structure D. Stages of Translation E. Relationship between DNA, mRNA, and Protein Sequences Translation and the Genetic Code

Transcript of A. Amino Acid and Protein Structure B. Formation of Aminoacyl tRNAs C. Ribosome structure D. Stages...

Page 1: A. Amino Acid and Protein Structure B. Formation of Aminoacyl tRNAs C. Ribosome structure D. Stages of Translation E. Relationship between DNA, mRNA, and.

A. Amino Acid and Protein StructureB. Formation of Aminoacyl tRNAsC. Ribosome structureD. Stages of TranslationE. Relationship between DNA, mRNA, and

Protein Sequences

Translation and the Genetic Code

Page 2: A. Amino Acid and Protein Structure B. Formation of Aminoacyl tRNAs C. Ribosome structure D. Stages of Translation E. Relationship between DNA, mRNA, and.

1. Amino acid structureFour different groups are attached to the

central carbon atom (α-carbon)Hydrogen atomAmino group (-N+H3)Carboxylic acid group (-COO-)Side chain group (“-R”): 20 different amino acids,

each with a different side chain, are encoded by codons on mRNA

A. Amino Acid and Protein Structure

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2. Peptides and ProteinsPeptides are formed when a covalent peptide

bond (an amide bond) is formed between the carboxylic acid group of one amino acid and the amino group of another amino acid.

A. Amino Acid and Protein Structure

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2. … Proteins are long peptides, over 50 amino acids

long and typically much longer (in the low 100s), and typically associated with some biological function

The peptide chain of a protein folds into a specific three-dimensional shape necessary for the activity of the protein.

The folding of the protein, and the chemistry of the protein’s active site, are dependent on the amino acid sequence of the protein.

A. Amino Acid and Protein Structure

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1. Amino acids are covalently attached to the 3’ end of the appropriate tRNAs. This is called the acceptor end.

2. The anticodon is a 3-base sequence on the anticodon loop of the tRNA. It is complementary to the sequence of the codon on the mRNA. The 5’ position is referred to as the “wobble base,” meaning that it may pair up with more that one partner.

3. The reaction is catalyzed by an aminoacyl tRNA synthase. Each tRNA has its own specific synthase enzyme.

B. Formation of Aminoacyl tRNAs

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4. This is the reaction:

Amino acid + ATP + tRNA aminoacyl tRNA + AMP +

PPi

B. Formation of Aminoacyl tRNAs

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5. tRNA has a distinctive 3-D structure, described as a “cloverleaf,” with hairpin loops and nonstandard bases

http://en.wikipedia.org/wiki/Transfer_RNA

B. Formation of Aminoacyl tRNAs

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1. Prokaryotic ribosomesLarge subunit: 50 SSmall subunit: 30 STotal size: 70 S

2. Eukaryotic ribosomesLarge subunit: 60 SSmall subunit: 40 STotal size: 80 S

http://en.wikipedia.org/wiki/Ribosome

C. Ribosome Structure

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1. Initiationa. Requires the aid of initiation factor proteinsb. The small ribosome subunit binds to the 5’

end of mRNA. The proper orientation is believed to be established by a sequence in the leader region called the Shine-Dalgarno sequence (in prokaryotes) or similar sequences.

c. An initiation codon (AUG) is oriented on the small ribosome subunit. AUG is the codon for the amino acid methionine. Please note: Sequences on mRNA are listed, by convention, in the 5’ 3’ direction

D. Stages of Translation

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1. …d. A molecule of methionyl tRNA (met-tRNA) binds to the

initiation codon through codon-anticodon base pairing. This step requires GTP as an energy source.

e. The large subunit binds to the small subunit to complete the initiation complex. All initiation factors are released.

f. Some interesting facts: In prokaryotes, the methionine on the initiating methionyl

tRNA is formylated (f-met-tRNA). In eukaryotes, it is not. Not every AUG codon can be an initiation codon. Sequences

in the mRNA leader seem to indicate which AUG codons are initiation codons.

The initial methionine may be removed after translation (posttranslational modification), so not every protein begins with a methionine.

D. Stages of Translation

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2. Elongationa. The ribosome/mRNA complex has two sites: the P

site (to which the growing peptide chain is attached) and the A site (where the next aminoacyl tRNA binds). At the beginning of elongation, the met-tRNA occupies the P site. The A site is ready to receive the next aminoacyl tRNA.

b. The next aminoacyl tRNA binds to the ribosome/mRNA complex at the A site.

c. An enzyme activity in the ribosome, peptidyl transferase, forms a peptide bond between the carboxyl end of the growing peptide (on the P site) and the amino end of the next amino acid (on the A site).

D. Stages of Translation

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2. … d. The tRNA on the P site, no longer attached to

an amino acid, is released.e. Another enzyme activity in the ribosome,

called translocase, moves the ribosome so that the peptidyl tRNA is transferred from the A site to the P site. This process requires a GTP molecule as an energy source.

f. Now the A site is ready to accept the next aminoacyl tRNA.

D. Stages of Translation

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3. Termination a. When the ribosome encounters a termination

codon on the mRNA (UAA, UAG, or UGA), elongation ceases.

b. Termination factors cause the ribosome, tRNA, and mRNA to dissociate from the nascent protein chain.

D. Stages of Translation

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Be certain that you can read the genetic code table.

E. Relationship between DNA, mRNA, and Protein Sequence: An Example

Sequence

Nontemplate DNA strand: 5’ ATG TTT GCT AAG GAC ATC TAA 3’

Template DNA strand: 3’ TAC AAA CGA TTC CTG TAG ATT 5’

mRNA sequence: 5’ AUG UUU GCU AAG GAC AUC UAA 3’

Amino Acid Sequence: (Amino end) Met Phe Ala Lys Asp Ile (Carboxyl end)

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Be certain that you can read the genetic code table.

E. Relationship between DNA, mRNA, and Protein Sequence: An Example