Of complexes and
maintenance of genome
stability
Marek Sebesta, PhD


marek.sebesta@ceitec.muni.cz


CSB, Ceitec, MU
22-Apr-21
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Content
1. What is maintenance of genome stability?
2. What are the challenges to the genome stability?
3. How do cells know the genome stability has been compromised?
4. How do cells maintain the genome stability?
5. How to study the genome stability maintenance?


(Case study on Homologous recombination)
3
What is the maintenance of genome stability?
4
Genome stability
What is the maintenance of genome stability?
4
Genome stability
DNA damage
response
What is the maintenance of genome stability?
4
Genome stability
DNA damage
response
What is the maintenance of genome stability?
DNA repair
4
Genome stability
DNA damage
response
What is the maintenance of genome stability?
DNA repair DNA damage


tolerance
4
Genome stability
DNA damage
response
What is the maintenance of genome stability?
DNA repair DNA damage


tolerance
Chromosome
segregation
4
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What is the maintenance of genome stability?
It is the ability of living organisms to preserve its genetic
material in time and across generations.
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What is the maintenance of genome stability?
What are the challenges to genome stability?
All living mater is constantly exposed to environment that challenges genome stability
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What are the challenges to genome stability?
All living mater is constantly exposed to environment that challenges genome stability
Endogenous
Cellular metabolism
DNA replication
Transcription
Spontaneous
modification
of the DNA
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What are the challenges to genome stability?
All living mater is constantly exposed to environment that challenges genome stability
Exogenous
Radiation
Diet
Stress
Endogenous
Cellular metabolism
DNA replication
Transcription
Spontaneous
modification
of the DNA
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What are the challenges to genome stability?
Hoeijmakers, 2001
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What are the challenges to genome stability?
Hoeijmakers, 2001
7
What are the challenges to genome stability?
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What are the challenges to genome stability?
What is more prevalent? Exogenous or endogenous damage?
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What are the challenges to genome stability?
What is more prevalent? Exogenous or endogenous damage?
Even-though, historically, exogenous DNA damage was
considered to be the prime cause of mutagenesis, recently,
as the methodology has progressed, the cellular DNA
metabolism pathways (replication and transcription) are being
recognised as the more prevalent cause of mutations.
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What are the challenges to genome stability?
Inability to repair properly the damage may lead to cancer, senescence, or
apoptosis.
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What is the difference between a primary lesion and a mutation?
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What is the difference between a primary lesion and a mutation?
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What is the difference between a primary lesion and a mutation?
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What is the difference between a primary lesion and a mutation?
10
What is the difference between a primary lesion and a mutation?
primary lesion
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What is the difference between a primary lesion and a mutation?
primary lesion
mutation
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Transient summary I
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Transient summary I
Terms Genome stability, DNA damage response, DNA repair, DNA damage
tolerance denote closely related, yet not interchangeable terms
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Transient summary I
Terms Genome stability, DNA damage response, DNA repair, DNA damage
tolerance denote closely related, yet not interchangeable terms
Cells are continuously exposed to wide variety of DNA damage
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Transient summary I
Terms Genome stability, DNA damage response, DNA repair, DNA damage
tolerance denote closely related, yet not interchangeable terms
Cells are continuously exposed to wide variety of DNA damage
Failure to properly deal with the damage may have fatal consequences to cells
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How do cells know genome stability has been compromised?
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How do cells know genome stability has been compromised?
Hoeijmakers, 2001
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How do cells know genome stability has been compromised?
The challenges
- different types of DNA damage
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How do cells know genome stability has been compromised?
The challenges
- different types of DNA damage
- cell-cycle stage
Hoeijmakers, 2001
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How do cells know genome stability has been compromised?
The challenges
- different types of DNA damage
- cell-cycle stage
Hoeijmakers, 2001
14
How do cells know genome stability has been compromised?
The challenges
- different types of DNA damage
- metabolic state
- cell-cycle stage
Hoeijmakers, 2001
14
How do cells know genome stability has been compromised?
Cells possess context-specific sensors that recognise signals from the damaged DNA
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TTA
How do cells know genome stability has been compromised?
Cells possess context-specific sensors that recognise signals from the damaged DNA
15
TTA
How do cells know genome stability has been compromised?
Cells possess context-specific sensors that recognise signals from the damaged DNA
XPC
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TTA
How do cells know genome stability has been compromised?
Cells possess context-specific sensors that recognise signals from the damaged DNA
XPC
Down-stream events
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TTA
How do cells know genome stability has been compromised?
Cells possess context-specific sensors that recognise signals from the damaged DNA
XPC
Down-stream events
TTRNAPII
B
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TTA
How do cells know genome stability has been compromised?
Cells possess context-specific sensors that recognise signals from the damaged DNA
XPC
Down-stream events
TTRNAPII
B
CSB
15
TTA
How do cells know genome stability has been compromised?
Cells possess context-specific sensors that recognise signals from the damaged DNA
XPC
Down-stream events
TTRNAPII
B
CSB
Down-stream events
15
TTA
How do cells know genome stability has been compromised?
Cells possess context-specific sensors that recognise signals from the damaged DNA
XPC
Down-stream events
TTRNAPII
B
CSB
Down-stream events
TT
DNA Pol
C
helicase
15
TTA
How do cells know genome stability has been compromised?
Cells possess context-specific sensors that recognise signals from the damaged DNA
XPC
Down-stream events
TTRNAPII
B
CSB
Down-stream events
TT
DNA Pol
C
helicase
RPA
15
TTA
How do cells know genome stability has been compromised?
Cells possess context-specific sensors that recognise signals from the damaged DNA
XPC
Down-stream events
TTRNAPII
B
CSB
Down-stream events
TT
DNA Pol
C
helicase
RPA
15
ATR
TTA
How do cells know genome stability has been compromised?
Cells possess context-specific sensors that recognise signals from the damaged DNA
XPC
Down-stream events
TTRNAPII
B
CSB
Down-stream events
TT
DNA Pol
C
helicase
RPA
15
ATR
How do cells react to DNA damage?
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How do cells react to DNA damage?
A simplified picture
d’Adda d’Fagagna, 201217
How do cells react to DNA damage?
A more comprehensive picture
Aguilera and García-Muse, 201318
Transient summary II
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Transient summary II
Cells possess specific factors - sensors - that recognise insults to DNA structure,
DNA breaks, or stalled machineries like transcription and replication.
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Transient summary II
Cells possess specific factors - sensors - that recognise insults to DNA structure,
DNA breaks, or stalled machineries like transcription and replication.
The sensors subsequently activate complex signalling pathways that lead to
halt of cell-cycle, as well as to decision as of which pathway is to be used;
balancing the cell-cycle stage and other needs of the cell.
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How do cell maintain genome stability?
DNA repair is prevalent outside the S-phase, in which DNA damage
tolerance is preferred.
Hoeijmakers, 2001
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Curtin et al., 2012
How do cell maintain genome stability?
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair
Sebesta and Krejci, 2016
NHEJ: non-homologous end joining
SSA: single strand annealing
SDSA: synthesis-dependent strand-
annealing
DSBR: DSB repair
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair
Sebesta and Krejci, 2016
NHEJ: non-homologous end joining
SSA: single strand annealing
SDSA: synthesis-dependent strand-
annealing
DSBR: DSB repair
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair
Sebesta and Krejci, 2016
NHEJ: non-homologous end joining
SSA: single strand annealing
SDSA: synthesis-dependent strand-
annealing
DSBR: DSB repair
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair
Sebesta and Krejci, 2016
NHEJ: non-homologous end joining
SSA: single strand annealing
SDSA: synthesis-dependent strand-
annealing
DSBR: DSB repair
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair
Sebesta and Krejci, 2016
NHEJ: non-homologous end joining
SSA: single strand annealing
SDSA: synthesis-dependent strand-
annealing
DSBR: DSB repair
22
How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair
Sebesta and Krejci, 2016
NHEJ: non-homologous end joining
SSA: single strand annealing
SDSA: synthesis-dependent strand-
annealing
DSBR: DSB repair
22
How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair
Sebesta and Krejci, 2016
NHEJ: non-homologous end joining
SSA: single strand annealing
SDSA: synthesis-dependent strand-
annealing
DSBR: DSB repair
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Error-prone
How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair
Sebesta and Krejci, 2016
NHEJ: non-homologous end joining
SSA: single strand annealing
SDSA: synthesis-dependent strand-
annealing
DSBR: DSB repair
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Error-prone
Error-free
How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Non-homologous end joining
NHEJ is an error-prone pathway
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Non-homologous end joining
NHEJ is an error-prone pathway
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Non-homologous end joining
NHEJ is an error-prone pathway
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Non-homologous end joining
NHEJ is an error-prone pathway
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
Sebesta and Krejci, 2016
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
Sebesta and Krejci, 2016
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
Sebesta and Krejci, 2016
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
Sebesta and Krejci, 2016
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
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Sebesta and Krejci, 2016
How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
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Sebesta and Krejci, 2016
How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
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Sebesta and Krejci, 2016
26
How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
Sebesta and Krejci, 2016
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
Sebesta and Krejci, 2016
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
Sebesta and Krejci, 2016
26
How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
Sebesta and Krejci, 2016
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How do cell maintain genome stability?
Double-stranded DNA breaks (DSB) repair


Homologous recombination
Sebesta and Krejci, 2016
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Transient summary III
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Transient summary III
Different types of DNA damage are repaired


by specific repair pathway
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Transient summary III
Different types of DNA damage are repaired


by specific repair pathway
The repair is generally error-free, except for NHEJ and SSA
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Transient summary III
Different types of DNA damage are repaired


by specific repair pathway
The repair is generally error-free, except for NHEJ and SSA
In S-phase, cells activate tolerance mechanisms that allow
timely completion of DNA replication
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How to study genome stability maintenance?
(Case study on Homologous recombination)
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How to study genome stability maintenance?
(Case study on Homologous recombination)
Different strategies exist
Genetic tools
Enable us to identify genes
and the relationships among,
thereby building a pathway
Microscopic tools
Give us a glimpse at spacial
and temporal relationships
of genes of interests
Biochemical tools
Enable us to understand
mechanisms and complex
formations within a studied
pathway
Structural tools
Enable us to understand
molecular mechanisms
at atomic resolution
Single molecule techniques
Enable us to understand behaviour at of single
molecules as compared to bulk biochemical
reactions
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How to study genome stability maintenance?


Step1: identify the genes
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How to study genome stability maintenance?


Step1: identify the genes
Using a thorough genetic analysis of the
isolated mutants, they were able to build a first
model of multiple pathways dealing with DNA
damage.
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How to study genome stability maintenance?


Step1: identify the genes
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How to study genome stability maintenance?


Step1: identify the genes
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How to study genome stability maintenance?


Step1: identify the genes
Using a genetic approach Mimitou and Symington, were
able to show for the first time the mechanism by which
cells resect the ends of broken DNA.
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How to study genome stability maintenance?


Step2: purify and study the proteins alone
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How to study genome stability maintenance?


Step2: purify and study the proteins alone
Using a purified protein, Patrick Sung was able to show that Rad51 is a bona fide recombinase.
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How to study genome stability maintenance?


Step2: purify and study the proteins in assemblies
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How to study genome stability maintenance?


Step2: purify and study the proteins in assemblies
Using purified proteins, Cejka et al., were able to
reconstitute end resection in vitro.
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How to study genome stability maintenance?


Step3: study the proteins in time and space
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How to study genome stability maintenance?


Step3: study the proteins in time and space
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How to study genome stability maintenance?


Step3: study the proteins in time and space
Using life-cell microscopy, Lisby et al., were
able to study the spatiotemporal interactions
among recombination factors.
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How to study genome stability maintenance?


Step4: study the role of protein complex formation?
Using SILAC approaches, Psakhye and
Jentsch showed that majority of HR proteins
are Sumoylated upon DSBs induction.
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How to study genome stability maintenance?


Step4: study the role of protein complex formation?
This Sumo-SIM mediated interactions are
trigger timely completion of HR.
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How to study genome stability maintenance?


Step4: study the role of protein complex formation?
This Sumo-SIM mediated interactions are
trigger timely completion of HR.
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How to study genome stability maintenance?


Step5: study the molecular mechanisms by the
means of structural biology
Crystal structure of presynaptic filament.
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How to study genome stability maintenance?


Step5: study the molecular mechanisms by the
means of structural biology
Crystal structure of postsynaptic filament.
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How to study genome stability maintenance?


Step5: study the molecular mechanisms by the
means of structural biology
By comparing the two structure a detailed, molecular
mechanism of the strand exchange reaction can be inferred.
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How to study genome stability maintenance?


Step6: study the molecular mechanisms by the
means of single-molecule techniques.
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How to study genome stability maintenance?


Step6: study the molecular mechanisms by the
means of single-molecule techniques.
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How to study genome stability maintenance?


Step6: study the molecular mechanisms by the
means of single-molecule techniques.
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Transient summary IV
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Transient summary IV
There are different techniques that allow us understand any given
pathway
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Transient summary IV
There are different techniques that allow us understand any given
pathway
The techniques must be combined, in order to get a full picture of
the pathway
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Transient summary IV
There are different techniques that allow us understand any given
pathway
The techniques must be combined, in order to get a full picture of
the pathway
Use whatever technique at hand that will help you answer your
scientific question
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Summary
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Summary
Maintenance of genome stability is a complex endeavour, which
requires intricate interplay of multiple pathways
44
Summary
Maintenance of genome stability is a complex endeavour, which
requires intricate interplay of multiple pathways
Cells use sophisticated mechanisms in deciding which pathway to
use at any given moment
44
Summary
Maintenance of genome stability is a complex endeavour, which
requires intricate interplay of multiple pathways
Cells use sophisticated mechanisms in deciding which pathway to
use at any given moment
Majority of factors responsible for maintaining genome
stability acts in complexes, let those be dynamic or not
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