Biol1110 2022 Lecture 7 - Translation PDF

Summary

This document describes lecture notes on translation focusing on the process of converting genetic information into proteins. The lecture covers concepts such as codons, tRNA, mRNA, rRNA, and ribosomes. It also includes details on the process of transcription and evolution of the genetic code.

Full Transcript

Biol1110
Genes to Organisms

Translation

Lecture 7 – Translation
 Lecture outline
Codons – triplets of bases
Translating information from nucleotides into amino
acids (polypeptides)
Roles of mRNA, tRNA and rRNA
Ribosomes
Initiation, elongation and termination stages of
translation
Mutations

Lecture 7 – Translation
 Short revision
C G
A T

Pyrimidines: Cytosine & Thymine (in RNA: Uracil replaces Thymine)
(one ring)

Purines: Adenine & Guanine
(two rings)
 Flow of information

transcription translation

DNA RNA polypeptide

Translation is the synthesis of a polypeptide,
which occurs under the direction of mRNA
Ribosomes are the sites of translation

Lecture 7 – Translation
 Flow of information

transcription translation

DNA RNA polypeptide

Lecture 7 – Translation
 Translation

Conversion from nucleotides, the “language” of
mRNA, to amino acids, the “language” of proteins

Lecture 7 – Translation
 Codons:
triplets of bases
There are 20 amino acids, but
there are only four DNA
bases
The flow of information from
gene to protein is based on a
triplet code: a series of non-
overlapping, three-nucleotide
words (codons)
Therefore, 43 (= 64) codons to
specify amino acids
Lecture 7 – Translation
 Codons:
triplets of bases
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
One codon, AUG, is
the universal “start”
codon
Lecture 7 – Translation
 Codons:
triplets of bases

The genetic code is
redundant but not
ambiguous; no codon
specifies more than
one amino acid
Flexible base pairing
in the third codon
position is called
wobble

Lecture 7 – Translation
 DNA to protein
DNA sequence of coding
(sense, non-template) strand:
5’ – ATG TTA TAC CAC – 3’
RNA sequence:
5’ – AUG UUA UAC CAC – 3’
Amino acid sequence:

Met Leu Tyr His

Proteins are chains of amino acids that fold into a 3-D structure.
Lecture 7 – Translation
 Transcription
& translation
5’ ATGTTCAGTCCTAA 3’ DNA (coding strand)

3’ TACAAGTCAGGATT 5’ DNA (template strand)

exon intron exon
5’ AUGUUCAGUCCUAA 3’ pre-mRNA

5’ AUGUUCUAA 3’ mRNA (intron spliced out)

Met – Phe - Stop(t
(translated to polypeptide
using the table on the right)
right)

Lecture 7 – Translation
 Protein back to DNA
Create one possible DNA sequence (both
anti-parallel strands) for one combination
of the mRNA, which makes the below
protein sequence?
1) Create the mRNA sequences first
using the table.
2) Include the 5’ and 3’ ends of each
polynucleotide.
3) Create DNA sequence from the
mRNA sequence

Polypeptide chain of amino acids

Met Leu Tyr His Trp Glu Cys Stop

Lecture 7 – Translation
 Polypeptide to DNA
Met – Phe - Stop
Can be any of the mRNA sequences:
5’AUGUUCUAA3’
5’AUGUUCUAG3’
5’AUGUUCUGA3’
5’AUGUUUUAA3’
5’AUGUUUUAG3’
5’AUGUUUUGA3’
Introns?
Leave out the step with inserting intron(s) as we
have no information on this
Can be any of the DNA sequences (coding
strand):
5’ATGTTCTAA3’
5’ATGTTCTAG3’
5’ATGTTCTGA3’
5’ATGTTTTAA3’
5’ATGTTTTAG3’
5’ATGTTTTGA3’

Lecture 7 – Translation
 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
Lecture 7 – Translation
 RNA components
of translation

mRNA: A cell translates an mRNA message into
protein with the help of transfer RNA (tRNA)
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
rRNA: ribosomal RNAs combine with proteins to form
the site of translation - ribosome

Lecture 7 – Translation
 Transfer RNA
A tRNA molecule consists
of a single RNA strand that
is about 80 nucleotides
long

Contains an amino acid
attachment site and an
anticodon that recognizes
the complementary codon
on the mRNA
Lecture 7 – Translation
 Binding of
amino acids

Matching the correct
amino acid with a tRNA is
performed by proteins
called aminoacyl-tRNA
synthetases

There are 20 different
synthetases, one for each
amino acid
Lecture 7 – Translation
 rRNA

Like tRNA, rRNA is a
structural molecule
that folds on itself

rRNA is a
component of the
ribosome

Lecture 7 – Translation
 Ribosome

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)

Lecture 7 – Translation
 Ribosome

http://bass.bio.uci.edu/~hudel/bs9
9a/lecture22/ribosome70s_a.gif

http://bass.bio.uci.edu/~hudel/bs99a/lecture22/exit_tunnel.jpg

Lecture 7 – Translation
 Ribosome
A ribosome has three binding
sites for tRNA:
– The A site binds the tRNA
that carries the next amino
acid to be added to the
chain
– The P site holds the tRNA
that carries the growing
polypeptide chain
– The E site is the exit site,
where discharged tRNAs
leave the ribosome
tRNAs move through these
sites in the order A-P-E
Lecture 7 – Translation
Gene expression

Lecture 7 – Translation
Gene expression

Lecture 7 – Translation
 Translation
The three stages
of translation:
– Initiation
– Elongation
– Termination
All three stages
require protein
“factors” that aid
in the translation
process
Lecture 7 – Translation
 Initiation
The initiation stage of translation brings together mRNA,
an initiator tRNA with the first amino acid, and the two
ribosomal subunits – forms the initiation complex

Lecture 7 – Translation
 During the
Elongation
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
Lecture 7 – Translation
 Termination
Termination occurs when a stop codon in the mRNA reaches the A
site of the ribosome
The release factor causes the addition of a water molecule instead
of an amino acid

Lecture 7 – Translation
 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

Lecture 7 – Translation
 Transcription
& translation
Prokaryotes
e.g. in bacteria
Transcription
and translation both in
the cytoplasm
(transcription in convoy and
polyribosomes)

Lecture 7 – Translation
 Transcription
& translation
Eukaryotes

Transcription and
mRNA modification
in nucleus,
translation in
cytoplasm

Lecture 7 – Translation
 Functional protein

Folds
– amino acid
sequence
– has a 3D shape

Post-translational
modification

Lecture 7 – Translation
Mutations

Lecture 7 – Translation
 Lecture summary
Flow of information goes from DNA ➔ RNA ➔
Protein
Translation refers to the information in mRNA
converted to amino acids (protein)
Codons are triplets of nucleotides
The genetic code is redundant, but not ambiguous
Binding of a tRNA with the correct amino acid is
performed by aminoacyl-tRNA synthetases
The ribosome is a large complex of multiple proteins
and rRNA
Lecture 7 – Translation
 Lecture summary
Translation involves the addition of amino acids via
tRNAs that move through the A, P and E sites of
ribosomes
Amino acids are added to the carboxyl-end of the
amino acid chain (the amino end is at the start of the
polypeptide chain)
Transcription and translation can occur at the same
time in bacteria
Variety of mutations can occur

Lecture 7 – Translation