Gene structure, expression and regulation in prokaryotes
Descripción
Bachelors Degree (Gene structure, expression and regulation in prokaryotes) Biology Mapa Mental sobre Gene structure, expression and regulation in prokaryotes, creado por Natalina Laria el 28/05/2016.
Gene structure, expression and
regulation in prokaryotes
Bacterial genome
Circular chromosomal DNA
Typically a few million base pairs
long
Most bacterial species contain a
single type of chromosome
A few thousand different genes
are interspersed throughout the
chromosome, genes separated by
short, intergenic regions
One origin of replication is
required to initiate DNA replication
No nucleus
Haploid (one copy of every gene)
Small compact
and repetitive
Plasmids
Replicate independently
Can integrate into chromosome
Not essential for survival
Fewer genes
Gene organisation in Prokaryotes
Organised into operons
A set of genes encoding proteins
participating in the same metabolic
pathway
Transcribed as polycistronic mRNA
Several proteins under influence of
one promoter
Advantage:
timing and
amounts
Disadvantage:
mutations
inflexible
Transcription
and translation
Occur at the same time
in the “same cellular
compartment”
Translation of an mRNA may
begin before the mRNA is
completely transcribed
Transcription unit
Promoter
Important in
initiation
Conserved sequence of nucleotides in a
DNA strand that is a binding site for
RNA polymerase
Position and orientation of
the promoter determines
which strand is transcribed
and where transcription
starts
RNA coding
region
Terminator
Transcription
Copying of template DNA strands
Strands
grow in a
5' to 3'
direction
RNA
polymerases can
initiate strand
growth
DNA
polymerases
require a
primer
Occurs in 3 phases
Initiation
Sigma factors recognise the
promoter to initiate
transcription
Promoter recognition
Formation of
transcription bubble
Creation of bonds
between rNTPs Escape
from transcription
apparatus from
promoter
Elongation
Termination
Rho-independent
Characterised by
1.) inverted
repeats 2.) string
of adenines ->
slow down
polymerase ->
formation of
hairpin structure
followed by a
string of uracils
Rho-dependent 1.)
DNA region, that
slows polymerase
down 2.)
Unstructured
region -> binding
site for rho
protein, catches
up, helicase
activity
NO
HAIRPIN
STRUCTURE
Translation
Genetic code is read in
triplicate but can be read in
different frames
Genetic code
and mutations
Silent mutation: the
base change does not
result in a protein
change
Mis-sense mutation: a
single amino acid is
changed
Nonsense mutation: an
amino acid codon is
changed to a stop codon
Frameshift mutation:
insertion or deletion of a
number of nucleotides that
is not a multiple of three
Different phases
Charging of tRNA
Amino
acid links
to tRNA
tRNA then binds its codon in RNA
Net result = amino acid is selected for by its codon
Initiation
Requires
ribosomes
and initiation
factors
Complementary base-pairing between the
Shine-Dalgarno sequence on the mRNA and
the rRNA occurs
Small subunit binds to
Shine-Dalgarnonsequence with the help
of IF3
Then fMet-tRNA binds to initiation
codon with the help of IF1, IF2 and
GTP
This is called the 30s initiation complex
Then IFs are removed and large subunit is added
This is called the 70s initiation complex
In summary the ribosome has been assembled on the
mRNA and the first tRNA is attached to the initiation codon