Molecular Biology Notes WK4 PDF

Summary

These notes cover DNA mutation and repair, including learning outcomes, types of mutations, and effects on proteins. They discuss spontaneous and induced mutations, replication errors, and repair mechanisms like mismatch and excision repair. The notes also touch upon CRISPR/Cas9 technology.

Full Transcript

DNA Mutation and Repair

Dr Jack Sunter
[email protected]
 Learning Outcomes
Explain the structure and
organisation of DNA and the
mechanisms of DNA replication and
repair.
Demonstrate an understanding of a
range of modern molecular biology
techniques.

2
 Peppered moth
Before the industrial revolution

After the industrial
revolution
London smog and 1956 Clean
Air Act
 Types of Mutations
Mutations change the sequence of DNA
Point mutation ATTGCAA ATTACAA

Insertion ATTGCAA ATTAGCAA

Deletion ATTGCAA ATTCAA

Transversion mutation:
– purine (AG) is replaced by a pyrimidine (TC)
– pyrimidine is replaced by a purine
Transition mutation:
– purine is replaced by a purine
– pyrimidine is replaced by a pyrimidine
 Mutation
Mutations can occur in:
Germ cells (sperm, eggs)
 Can cause heritable
defects
Somatic cells (adult cells apart from
germ cells)
 Can cause diseases such
as cancer
Cells in the developing embryo
 Can cause developmental
defects
 Mutation
Mutations can occur in:
Coding genes
Can affect protein
expression/structure
Non-coding RNAs (eg. rRNAs, tRNAs)
Can affect translation, transcription,
splicing etc.
Non transcribed regions (e.g. promoters,
enhancers)
 Can affect transcriptional
Mutations can occur
regulation
 Effects on proteins
1. Nonsense mutation – truncates
protein
2. Missense mutation – changes an
amino acid
3. Frameshift mutation – changes
No (silent) mutation
Nonsense Missense Silent
reading frame
AAG TAG AGG ACG AAA
4.
Lys
Silent mutation
STOP
– does
Arg
not
Thr
alter the
Lys
amino acid

Nucleophilic

Basic Basic
Conservativ Radical
e replaceme
substitution nt
 Silent mutations
No effect on amino acid sequence
But can affect transcription or
translation
No mutation Silent More than one codon can code
AAG AAA for a single amino acid
Lys Lys Some organisms favour a
particular codon for a given
amino acid
E.g. Of the four valine codons,
Basic
human genes use GTG four times
more than GTA
Known as codon bias
Presence of a non-favoured
codon (rare codon) can slow
 DNA Mutations
Mutations either:
– Spontaneous
– Induced
 Spontaneous Mutations
Mutations that occur during normal
cellular processes
Mutations are rare events and occur
at a background level for any
particular organism Mutations can be
caused by:
– Malfunction during DNA replication
causes the wrong base to be inserted
during DNA synthesis
– DNA bases are modified
 Replication errors
Wrong bases inserted at DNA
replication, or a DNA base is skipped
over
Errors are made by DNA polymerase
about one mutation every 105 to 106
base pairs
Corrected by proofreading activity of
DNA polymerase
Most replication errors are fixed by
proofreading activity of
polymerase
Rate of incorporation slows dow

using an 3’ - 5’ exonuclea

99% of mismatches fixed with
Replication errors - DNA
5’ slippage 3’

During replication, the
DNA polymerase and
newly synthesized DNA
strand complex
sometimes temporarily
dissociates from the
template DNA
In repetitive
sequences, the
polymerase may
reassociate with
the template
strand in a position
one or two repeats
ahead or behind
where it left off
Lead to
insertions or
http://www.sciencedirect.com/science/article/pii/
DNA slippage
Can lead to
expansion of
CAG in
huntingtin
gene
 What type of spontaneous base
modifications can occur?
Discuss in pairs
10 – 15 minutes
Report into google doc
– type of modification?
– what’s the consequence?

15
Antioxidants – protectors
against free radicals
Antioxidants donate an electron to free radicals,
thereby reducing their reactivity
 Damage in the DNA
template can lead to double
strand break (DSB)
formation during replication
‘Nick’ = break in
phosphodiester
bond from
oxidative damage Loss of DNA
or
translocatio
ns
 Double strand breaks can lead to
chromosome translocations

Chromosome
translocations -
piece of one
chromosome
become attached
to another
chromosome

Some spontaneous translocations can lead to
cancer progression
 Induced Mutations

DNA damage caused by
exogenous agents - mutagens

Discuss in pairs
10 – 15 minutes
Report into google doc
– type of damage/modification?
– what’s the consequence?
 Use of mutations in research
EMS (ethylmethane sulfonate) and ENU (N-Ethyl-N-
nitrosourea) are powerful mutagens (alkylating agents)
Animal models can be treated with ENU
Animals with a resulting phenotype can be isolated and the
mutated gene identified by classical genetics
Help identify genes involved with disease

Paul Potter’s work involves this

http://www.brc.riken.jp/lab/gsc/mouse/AboutUs/
Use of mutations in research
e.g. ENU

http://www.brc.riken.jp/lab/gsc/mouse/AboutUs/
 (N-ethyl-N-nitrosourea) - alkylating ag

Identify genes involved in disease
EMS mutagenesis on Caenorhabditis
elegans (cheap and quick to grow)

Treat C. elegans worms to 0.05 M EMS
at 20°C for 4 hours. Look at progeny:
Wild-type

small mutant (adults are
small)
Dumpy mutant (adult animals
are short and thick)
egg laying–defective mutant
(adult animals rarely lay
eggs, so embryos mature
and hatch inside the adult)
Identify genes involved in development – sequencing
 Use of mutations in therapy
Cancer cells divide more rapidly than most
other cells
DNA-damaging agents (radiotherapy, chemotherapy) have
more effect in cancer cells than in most healthy cells
Stop cancer cells from growing and spreading
Chemotherapy – many types, e.g. mustard gas derivatives
(alkylating agents)

Side effects of
chemotherapy or
radiotherapy =
induction of cancer

http://cancerhelp.cancerresearchuk.org/about-cancer/what-is-cancer/cells/
 DNA Repair
DNA damage can occur from various
sources, and if left unchecked will
have disastrous consequences for an
organism
Fortunately, there are several DNA
repair systems to maintain genetic
stability
There is far too much to cover in
one lecture (we could do a whole
Much of what
module on we
it!) know about
– extra DNA repair
reading…
has been obtained through studying the
 Repair of mismatches

Mismatches arise during DNA synthesis
Or caused by chemicals/oxidative
damage
99% of spontaneous replication errors
are repaired by proofreading by DNA
polymerase
this is the 3’ - 5’ exonuclease activity

most of the rest are repaired by mismatch
repair or excision repair
 Mismatch repair
Newly synthesised strand will commonly include
mismatch errors even after proofreading activity
Fixed by mismatch repair
GATC G GATC
In E. coli: T
DNA is normally methylated at GATC
sites on both strands
Just after replication, only one strand is
methylated
MutS specifically recognizes and binds
mismatch
MutL assembles with MutS and activates
MutH
MutH binds nearest methylated GATC,
differentiating between old strand and
new strand
Complex introduces a nick in the new
strand
Helicase displaces the nicked strand
 Mismatch repair in
humans
Similar process but with more layers of regulation

Eukaryotes have MutS and MutL genes (called
MSH and MLH genes – first studied in yeast)
MutS homologues
MSH1, MSH2….MSH5
MutL homologues
MLH1, MLH2 etc.

Eukaryotes don’t have MutH
Must have another enzyme for incision – still to be found
 Mismatch repair and colon
cancer
hereditary non-polyposis colon cancer is a
hereditary cancer (Lynch syndrome)
2% of all colon cancers
early onset (40s)
35% have a defect in MSH2
65% have a defect in MLH1

Mutations that arise in this condition are small
additions or deletions - resulting from ‘replication
slippage’
Hairpins in newly synthesized DNA are detected by
the mismatch repair system and removed
 Excision Repair
Involves excision of the damaged
region and replacement through the
use of the complementary DNA
strand as template
Two of the most common pathways
for repairing damaged DNA:
– Base excision repair
– Nucleotide excision repair
X = Damaged base Base excision repair
Apurinic/apyrimidine (AP)
E.g. Alkaylated bases (induced by endonuclease cuts phosphodiester
alkylating agents), Deaminated bond
bases (spontaneous or induced),
Oxidized bases (induced by
superoxide radicals)

Deoxyribose
removed by
dRpase

Repair Polymerase (such as PolI in E.
DNA coli or Pol b in mammals) fills gap
glycosylase and ligase seals DNA.
removes base

using undamaged strand as template
http://www.funpecrp.com.br/gmr/year2003/vol1-2/ NB This is in E. coli
 Nucleotide excision repair
Repairs large changes in DNA double helix, such as
‘bulky lesions’ caused by intercalating agents or
pyrimidine dimers
Multienzyme complex (in bacteria UvrA, B
and C) scans DNA for distortion

Enzyme complex cleaves DNA backbone
helicase on either side of distortion leaving a gap
of about 12 nucleotides in bacteria (30 in
humans)

DNA helicase peels away a single-
stranded oligonucleotide containing the
lesion

Large gap in the DNA is then repaired by
DNA polymerase (DNA PolI in bacteria)
 Xeroderma pigmentosum (XP)
- human repair defect

Severe sunburn after only a few minutes in the sun,
freckling in sun exposed areas - caused by defects in
nucleotide excision repair
Problems repairing UV-induced damage
~50% of patients die of cancer before age of 20
 DNA double-strand breaks
DNA double-strand breaks are much
more difficult to repair

Sequence information may be lost

Repaired by:
Homologous recombination (HR)
Non-homologous end-joining (NHEJ)
Non-homologous end-joining
In pairs identify the important
proteins required for HNEJ

5 minutes and report back
 Repair of double DNA is nibbled back by an exonuclease
strand breaks by
homologous Invasion of the
recombination homologous
sister
Recombination repair chromatid
Involves pairing
damaged DNA with a
homologous DNA
The invading
duplex, i.e. a template strand acts a
Process is very complex primer for DNA
Many proteins polymerase

accumulate at the site
ofNewly
damage
synthesised region
anneals to the DNA on the DNA pol fills the gaps
other side of the DSB
Ligase seals the nicks
Homologous Recombination
Can we take advantage of the
endogenous enzymes to recombine
homologous molecules via a double
stranded break in the target
chromosomal sequence?
Can we recombine in a desired
sequence?
 Basic idea of what we can use
homologous recombination for…
Homology arm Homology arm
construct
Genome before

Genome after

Can we introduce a double stranded break
anywhere we want in the genome?
 CRISPR/Cas9 system
CRISPR – clustered regularly interspaced short
palindromic repeat
Bacterial defence system – ‘immunological memory’
Bacteria cuts foreign DNA (red/pink) and
acquires it into CRISPR locus
Bacteria transcribes the CRISPR locus to
generate a guide RNA with a region, 20
nt, that is complementary to the foreign
DNA (red/pink)

Complementary region base pairs with
the target DNA
Cas9 endonuclease recognises this complex
and cuts the DNA to introduce a double
stranded break

Wiedenheft et al. 2012 Nature 482:331-338
To cut the genome at a
specific site
CRISPR uses ~20 nt
sequence of crRNA to
bind its complementary
sequence of exogenous
DNA
Additional trans-acting
RNA (trancrRNA)
recruits Cas9
endonuclease
Cas9and
crRNA cuts DNA
trancrRNA
can be synthesized
into a single chimeric
RNA - guide RNA
(gRNA)
https://www.thebestgene.com/CRISPRInfoPage
 Genome editing using
CRISPR/Cas9
Cas9

guide RNA

microinjection into embryo

Target genome e.g. Drosophila

Create a knock out mutant
Not just flies
http://trialanderror-scienceblog.com/?tag=cas9
 You can edit the genome of
Drosophila, cell lines and cats…..
What next?
DNA mutations: the bad and
good
Fewer than 1 in 1000 accidental base
changes in DNA results in a permanent
mutation
The bad: mutation in a proto-oncogene
can lead to cancer
The good: mutation confers
advantageous traits – drives evolution
Balance between evolution and
disease