DNA Damage and Repair Mechanism 2024 Dr. Liu.pdf

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DNA Damage and Repair Mechanisms

Bindong Liu, PhD
Professor, Microbiology and Immunology
Email: [email protected]; Tel: 615-327-6877

June 2024
 Learning Objectives

❑ Describe endogenous and exogenous sources of DNA damage and
the types of lesions that they cause

❑ Explain the consequences of different forms of DNA damage

❑ Outline the basic steps of different DNA repair systems

❑ Identify diseases associated with DNA repair defects
Maintaining genetic stability is critical for life

Genetic stability is necessary for life

o Extremely accurate mechanism for replication of DNA

o Highly efficient DNA repair

Tens of thousands of mutations are repaired every day

Less than 0.02% accumulate as a permanent mutation in
the human DNA genome

Defects in DNA repair links many human diseases
e.g., BRCA1 and BRCA2 mutations cause homologous recombination
defects leading to breast and ovarian cancer
 Source of DNA damage/mutations

▪ Endogenous/spontaneous - Mutant cells that arise in nature
(e.g., polymerase mistakes)

▪ Exogenous/induced - Mutant cells that arise as a result of
exposure to a mutagen (an agent that causes mutations)

❖ Caused by physical or chemical mutagens
Endogenous/spontaneous DNA damage

Red arrow: oxidative damage
Green arrow: methylation
Blue arrow: hydrolytic attack
The width of arrow= frequency

Molecular Biology of the Cell (© Garland Science 2015)

Although highly stable, DNA is still susceptible to spontaneous changes

Depurination: loses purine bases (adenine and guanine)

Deamination: the removal of an amino group from nucleotide
 Depurination and Deamination

▪ If not repaired

Deaminated C:

U will pair with A and cause G
to A mutation.

Depurinated A:

DNA replication “skip” to cause
deletion

Molecular Biology of the Cell (© Garland Science 2015)
 Exogenous/induced DNA damage

▪ Chemical or physical agents that induce mutations

▪Alter the primary sequence of DNA

▪Promotes errors in replication or repair of DNA
 Three classes of Chemical Mutagens

▪ Nucleotide-base analogs
5-bromouracil (5-BrU) leads to mispairing and DNA replication mistakes

▪ Frameshift mutagens

Ethidium bromide (EB) insert between the bases causes addition or deletion

▪ DNA-reactive chemicals

Nitrous acid (HNO2) changes the chemical structure of the base pair abnormally
 Chemical Mutagens:
Nucleotide-base analogs

▪ 5-bromouracil (5-BrU) structure
similar to thymine

▪ 5-BrU replaces thymine (T)

▪ 5-BrU pair with guanine (G) or
adenine (A)
(https://www.biologyonline.com)
▪ Cause A:T to G:C mutation
 Chemical Mutagens:
Frameshift/Intercalating mutagens

▪ Proflavin, acridine, ethidium bromide (EB) flat molecules

▪ Insert into DNA duplex

▪ Cause “stretching” of DNA duplex

▪ Insertion or deletion
 Chemical Mutagens:
DNA-reactive chemicals

▪ Nitrous Acid (HNO2) cause
deamination

▪ Convert:

Cytosine to Uracil
Adenine to Hypoxanthine

▪ Cause mutation
(https://www.mun.ca/biology/)
 Physical Mutagens:

▪ Radiation was the first mutagens known,
reported 1920’s

▪ Two types of radiations

Electromagnetic radiations:

UV radiation

Ionizing radiations:

X- and gamma-rays
Physical Mutagens:
Electromagnetic radiations:

▪ Nonionizing

▪ UV radiation reacts with DNA
and other biological molecules

▪ UV radiation forms TT dimer or
CC dimer
 Physical Mutagens:
Electromagnetic radiations:

UV radiation cause pyrimidine dimers

▪ Most TT or CC dimers will be
The dimers initiate nucleotide excision repair corrected

▪ TT dimer gets read correctly

▪ CC often misread as TT
If the dimers is not fixed:

❖ TT will be read normally (no mutations) ▪ CC to TT shows up in p53
tumor suppressor gene skin
cancers.

❖ CC misread as TT

(Copyright © 2022 The Bumbling Biochemist)
 Physical Mutagens:
Ionizing radiations:

▪ X- and gamma-rays

▪ Produce reactive ions (charged
atoms or molecules)

▪ Damage:
base and sugar
single strand break
double-strand break

▪ Severity depends upon the dose
received
Signal Transduction and Targeted Therapy volume 5, 60 (2020)
 DNA Repair

It is the interplay between various substrates, enzymes and co-factors
etc., to correct/repair the errors. Includes several different processes

DNA repair has a remarkable efficiency

Diminished capacity for DNA repair in humans has been linked to many
human diseases

DNA double helix is the foundation for DNA repair

o Each strand stores a separate copy of the information. Lesions
(mutations) can, therefore, be cut out, and a correct strand
resynthesized from information on the undamaged strand

o All cells use dsDNA except a few small viruses
 Types of DNA Repair

Strand-directed mismatch repair (MMR)
Base excision repair (BER)
Nucleotide excision repair (NER)
Non-homologous end joining (NHEJ)
Homologous recombination (HR)
 Strand-Directed Mismatch Repair

Corrects mismatched bases

Also called DNA Mismatch Repair

Single base or 2-5 bases small loops
CGGUTTACGGTAA
| || || || | ||||
Steps: GCCGAATGCCATT
Scan newly made strand
Endonuclease cuts backbone
Exonuclease removes bases to mutation
Fill in the gap with usual replication enzymes like
ligase, polymerase,
 Strand-Directed Mismatch Repair

MutS binds specifically to a
mismatched base pair

MutL scans the nearby DNA for a
nick

MutL triggers the degradation of the
nicked strand

Nicked strand is degraded all the
way back through the mismatch,
and replication errors are
selectively removed

Fill in the gap with usual replication
enzymes like Ligase, polymerase
Molecular Biology of the Cell (© Garland Science 2015)
Human disease related to DNA-Mismatch-Repair

Hereditary non-polyposis colon cancer (HNPCC)

an autosomal dominant disease

the most common caused by mutations in hMLH1
(MutL) or hMSH2 (MutS)
 Excision Repair Mechanisms

Damage is excised, and the original DNA sequence is restored using
the undamaged strand as its template.

Excision repair mechanisms are very common

Two kinds- Base-Excision Repair and Nucleotide-Excision Repair
 Base Excision Repair
Used to replace chemically modified bases

AP Site (apurinic/apyrimidinic site): a location in DNA
that has neither a purine nor a pyrimidine base
Four-step process

Glycosylase – removes altered base (not the entire
nucleotide)

AP endonuclease and Phosphodiesterase–
removes the remainder of the nucleotide

Polymerization – fills the empty spot
Molecular Biology of the Cell
(© Garland Science 2015)
Ligation – seals the nick in the DNA backbone
 Nucleotide Excision Repair

Recognizes general distortions caused by bulky
Thymine Dimer
chemical adducts –up to 30 bases long

Bulky lesions/adducts include
Pyrimidine dimers due to UV
Radiation, chemotherapy, strand breaks,
crosslink across chains
DNA- protein crosslinks
Covalent reaction of DNA bases with
large hydrocarbons (such as the
carcinogen benzopyrene)
Molecular Biology of the Cell (© Garland Science 2015)
Exonuclease cuts out the defect, bases are
restored, and the backbone is ligated
In eukaryotes: 25+ enzymes
 Nucleotide Excision Repair

Exonuclease cuts out the defect, bases
are restored, and the backbone is
ligated

In E. coli, UvrA, UvrB and UvrC remove
the dimer induced by UV light

In yeast, the proteins similar to Uvr's are
named RADxx ("RAD" stands for
"radiation"), such as RAD3 RAD10.

Molecular Biology of the Cell (© Garland Science 2015) In eukaryotes, usually more than 25
enzymes are involved in this repair
 Nucleotide Excision Repair mechanism related
disease

Human disease: Xeroderma Pigmentosum

Rare autosomal recessive disorder

DNA of skin cells damaged by UV light cannot be repaired

Some cancers and neurologic problems can be life-threatening

Lack of excision repair mechanism

o XPA (DNA Damage Recognition and Repair Factor) gene defective mutation

▪ XPA protein binds to the damaged DNA

▪ XPA protein recruits other proteins to perform nucleotide excision repair
 Double-Strand Break (DSB)

Especially dangerous type of DNA damage

Caused by Ionizing radiation, replication errors, oxidizing agents, and other
metabolites produced in the cell cause breaks of this type

Un-repaired DSBs will cause the breakdown of chromosomes into smaller
fragments

Two mechanisms to repair Double-Strand Break

Non-homologous end joining (NHEJ)

Homologous recombination (HR)

Non-homologous end joining predominates in humans

Homologous recombination is used only during and shortly after DNA
replication when sister chromatids are available to serve as templates
 Non-homologous End-joining (NHEJ)

Three-step repair

- Break is recognized by Ku heterodimers

- The protein complex holds the broken end together
and trims the ends of the breaks

- The blunted ends are ligated

A “quick and dirty” solution usually causes
deletions

Common in mammalian somatic cells

An acceptable solution since so little of
the mammalian genome is essential for
life.
Molecular Biology of the Cell (© Garland Science 2015)
Chance to cause aberrant chromosomes
- with two centromeres or no centromeres
Homologous Recombination

Exchange of DNA strands
between a pair of homologous
duplex DNA, which may be
identical or similar
HR occurs just during or right after
DNA replication when two
daughter DNA molecules lie close
together, and one of them serves
as a template
One stretch of duplex DNA acts as
a template to restore lost or
damaged information on the
second duplex stretch
https://www.bartleby.com/
HR accurately repairs DSB
Facilitates chromosomal crossover
 HR repair DSB

Nuclease digests the broken strands
to release single-strand 3’ end
Strand exchange/invasion: one of
the single-strand 3’ ends worms its
way into the template duplex and
anneals to the complementary region
Polymerase synthesizes DNA using
the unbroken strands as a template
to restore the damaged region
Strand displacement: the invading
strand is released, DNA synthesized
and ligated to restore the two original
DNA double helices.
HR exploits a complementary strand
from a separate DNA duplex
Molecular Biology of the Cell (© Garland Science 2015)
 HR is crucial for Meiosis

Deliberately exchange of material
between different chromosomes to
generate novel combinations of genes

HR produces chromosome crossing-
over, resulting in hybrid chromosomes
that contain genetic information from
both the maternal and paternal
homologs

This exchanging of DNA is an important
Molecular Biology of the Cell (© Garland Science 2015)
source of the genomic variation seen
among offspring
 Human diseases related to defective HR

❖ Brca1 regulates an early step in broken-end processing; without it, such
ends are not processed correctly for homologous recombination and instead
are repaired inaccurately by the non-homologous end-joining pathway

❖ Brca2 binds to the Rad51 protein, preventing its polymerization on DNA,
and thereby maintaining it in an inactive form until it is needed

❖ Brca1 and Brca2 protein mutations lead to a greatly increased frequency
of breast and ovarian cancer
Other Human Diseases

Table 5-2 Molecular Biology of the Cell (© Garland Science 2015)
Study questions
1. True or False: HR is the predominant mechanism for repairing double-strand breaks in human
cells since it is more accurate than NHEJ.

2. True or False: Xeroderma pigmentosum is a disease caused by defects in base excision repair
mechanisms.

3. True or False: BRCA1 and BRCA2 mutations are associated with an increased risk of breast and
ovarian cancer due to their role in homologous recombination.

4. True or False: UV radiation primarily causes DNA damage by forming pyrimidine dimers, such as
thymine-thymine (TT) or cytosine-cytosine (CC) dimers.

5. True or False: Homologous recombination (HR) can only occur during meiosis and is not used for
DNA repair in somatic cells.

Answers: 1: F; 2: F; 3: T; 4: T; 5: F.