Lecture 9 Gene Expression in Prokaryotes and Eukaryotes (2).pptx

Full Transcript

Recombina
nt DNA202
Gene
Expression:
Transcriptio
n

RDNA202

Cassie
[email protected]
GENE Expression in Prokaryotes and
Eukaryotes

Lecture 9: GENE Expression – Transcription

Lecture 10: GENE Expression – Translation

Lecture 11: DNA Mutation
 Learning Outcomes
Transcription Poly-A-Tail
In prokaryotes Intron
In Eukaryotes
Exon
Promotor
Steps in Transcription
RNA polymerase Initiation
Holoenzyme Elongation
Splicing Termination

Spliceosomes Pre-mRNA modification
 The Central Dogma
The process by which genetic information in the cell flows
from DNA to mRNA to Proteins

Process occurs in two stages:
1. Transcription
2. Translation
 Basic Principles of Transcription and
Translation
Instructions for protein synthesis comes from genes

RNA serves as the bridge between DNA and Protein synthesis
RNA contains Uracil not Thymine

DNA has A, C, G, or T

RNA has A, C, G, or U
 Transcription
Synthesis of mRNA
Uses genetic information encoded in
DNA
DNA strand serves as the template
strand for the synthesis of RNA
nucleotides (mRNA)

NOTE:
mRNA molecule will be
complementary to the DNA template

Identical to the non-template DNA (with
the exception of uracil)
 Which Strand of the DNA is copied?
DNA is double stranded… BUT
In any gene – only ONE strand is copied into RNA
 Stages of Transcription

3 Stages of Transcription:

1. Initiation

2. Elongation

3. Termination
 Transcription in Prokaryotes: Initiation
Promotor – DNA sequence where RNA Polymerase attaches &
initiates transcription
2 Sequences
Start point – the nucleotides where RNA polymerase begins
synthesising mRNA
RNA Polymerase
Separates 2 DNA strands
Joins together complementary RNA nucleotides to DNA template
strand
 Transcription in Prokaryotes: Initiation
Prokaryotic RNA Polymerases
The same RNA polymerase is used to
transcribe all the genes in prokaryotes
Comprises five polypeptide
subunits
1. β
2. β’
3. α
4. α
5. 
The enzyme that comprises all five
subunits - holoenzyme
 Transcription in Prokaryotes: Initiation
Each Subunit has a unique function
The β-subunit binds to the ribonucleoside triphosphate that will become
part of the new mRNA

The β’-subunit binds the DNA template strand

The two α-subunits are required to assemble the polymerase on the DNA

The -subunit is involved in transcription initiation
Causes the polymerase to synthesize mRNA from an appropriate
initiation site
 Transcription in Prokaryotes: Initiation
At the -10 and -35 regions upstream of the start point – there are
2 promoter consensus sequences
The 
-subunit attaches to the sequences for RNA synthesis to begin
RNA polymerase unwinds the DNA strand and initiates transcription
Once transcription has been initiated, 
-subunit dissociates from the
polymerase
 Transcription in Prokaryotes: Elongation
During elongation the 
-subunit is released from the
polymerase
Causes the enzyme to proceed with synthesizing mRNA in 5’-3’
direction
Adds RNA nucleotides to the 3’ end of the growing strand
 Transcription in Prokaryotes:
Termination
Prokaryotic polymerase needs to be instructed/signalled to
dissociate from the DNA template
Set free the newly made mRNA

The transcribed (produced) RNA sequence serves as the
termination signal
Causes RNA polymerase to detach from DNA & release transcript

The RNA transcript does not require further modification or
processing before translation
 Transcription in Eukaryotes: Initiation
Prokaryotic polymerase – can bind to DNA template on its own
Eukaryotic polymerase cannot bind to DNA template on its own
Eukaryotes require transcription factors
These first bind to the promotor region

Help recruit the appropriate polymerase

Both have similar sequences at the -10 region
TATAAA in eukaryotes
TATAAAT in prokaryotes
 Transcription in Eukaryotes:
Initiation
In the promotor region there is
a TATA box & Transcription
start point

Essential in forming initiation
transcription complex

The nucleotide position where RNA
polymerase begins RNA synthesis
 Transcription in Eukaryotes:
Initiation

Transcription factors (purple) bind to
DNA
RNA polymerase II can only bind to
promotor after transcription factors are
attached

RNA polymerase II is bound to
transcription factors on DNA
RNA polymerase separates DNA strands &
begins RNA synthesis
 Transcription in Eukaryotes: Elongation
As RNA polymerase moves along DNA –
untwists double helix

RNA polymerase adds RNA nucleotide
to 3’ end of growing RNA strand

Newly synthesized RNA molecule peels
away from DNA template as
transcription progresses
 Transcription in Eukaryotes:
Termination

RNA polymerase II transcribes a sequence on DNA –
Polyadenylation signal sequence
(AAUAAA)
Once these 6 nucleotides appear – bound to nucleus by certain
proteins
These proteins release the pre-mRNA
The pre-mRNA then undergoes processing
 Pre-mRNA Processing in Eukaryotes

Mechanism of transcription is similar in bacteria and
eukaryotes
But…
The flow of genetic information differs within the
cells
 Pre-mRNA Processing in Eukaryotes

In Bacteria: In Eukaryotes:
Bacteria do not have nuclei Do have nuclei
No nuclear membrane to Nuclear envelope separates
separate DNA & mRNA from
ribosomes transcription from translation
Translation of mRNA occurs Transcription – in nucleus
without additional processing mRNA must be transported to
Both occur in cytoplasm cytoplasm for translation
 Pre-mRNA Processing in Eukaryotes

Before RNA transcript (pre-mRNA) can leave nucleus
Must undergo processing to produce final mRNA

Transcription produces pre-mRNA

Further pre-mRNA processing results in finished
mRNA
Transported to cytoplasm for translation
 Pre-mRNA Processing in Eukaryotes
Three steps involved in pre-mRNA processing

1. Addition of stabilizing and signalling factors and 5’ and 3’ ends of
molecule
5’ capping
Poly-A-Tail

2. Removal of introns – mRNA splicing

3. mRNA transcripts can be edited after it is transcribed – in rare cases
 Pre-mRNA Processing in Eukaryotes
1. Addition of stabilizing and signalling factors at the 5’
and 3’ ends

5’ capping
A 7-methylguanosine cap (form of guanine nucleotide) –
added to 5’ end

Protects mRNA from degradation

During protein synthesis – factors recognise this cap to help
initiate translation
 Pre-mRNA Processing in Eukaryotes
1. Addition of stabilizing and signalling factors at the 5’ and 3’ ends

3’ Poly-A-Tail
Pre-mRNA is cut and released soon after the Poly-A-Tail appears

At 3’ end – enzyme (Poly A Polymerase) adds more adenine nucleotides
(50-250)

This protects pre-mRNA from degradation

Also serves as binding site for protein exporting processed mRNA into
cytoplasm
 Pre-mRNA Processing in Eukaryotes
2. Pre-mRNA splicing: The removal of introns
Process where large portions of RNA transcript are removed &
remaining portions re-connected

Intron: Non-coding sequence within primary transcript
Removed from transcript during RNA processing

Exon: Sequence within primary transcript
Remains in RNA after RNA processing

Pre-mRNA splicing is conducted by spliceosomes
 Pre-mRNA Processing in Eukaryotes
During pre-mRNA processing
Both ends of primary transcripts are altered/modified
Includes:
Cutting out of introns
Joining together Exons
Alteration of 5’ and 3’ ends
This stage of RNA processing is called RNA splicing
 Pre-mRNA Processing in Eukaryotes
How is Pre-mRNA splicing carried
out?
1. Spliceosomes recognise 5’ and 3’ end
of intron

2. Small RNAs in spliceosome pairs
with the nucleotide of the intron

3. Small RNAs catalyze cutting of the
pre-mRNA & joining of the exons
 Next
Lecture:
GENE EXPRESSION –
TRANSLATION