Establishing Relationships Between DNA Repair and Transcriptional Mutagenesis of Non-Bulky Base Damage in Escherichia coli Público
Clauson, Cheryl Lynn (2010)
Abstract
Establishing Relationships Between DNA Repair and
Transcriptional Mutagenesis of
Non-Bulky Base Damage in Escherichia coli
Cheryl Lynn Clauson
DNA damage occurs continuously, but faithful replication and
transcription are essential
for maintaining cell viability. Generally, cells in nature do not
divide or replicate DNA
often, thus, it is important to consider the outcome of RNA
polymerase (RNAP)
encounters with DNA damage. Base damage in the DNA can affect
transcriptional
fidelity, leading to production of mutant mRNA and protein in a
process termed
transcriptional mutagenesis (TM). It was of interest to determine
how DNA repair
pathways are involved in the process of TM. The contributions of
base excision repair
(BER), transcription-coupled repair (TCR), and nucleotide excision
repair (NER) to
repair of two non-bulky lesions, 8-oxoguanine and uracil, were
examined in vivo using a
luciferase-based reporter assay in Escherichia coli under
non-growth conditions. We
found that both TCR and NER are utilized by E. coli to
repair 8-oxoguanine and uracil.
We also found that TCR can utilize components of either pathway for
lesion removal.
These findings indicate a dynamic flexibility of DNA repair
pathways in the removal of
non-bulky DNA lesions in prokaryotes, and reveal their respective
contributions to the
repair of 8-oxoguanine and uracil in vivo. It was also of
interest to determine the
consequences of incomplete BER, which results in abasic (AP) sites
and strand breaks,
on the process of TM. These lesions also frequently occur
spontaneously, so RNAP
could often encounter these non-coding structures in vivo.
We were able to demonstrate
that RNAP is capable of bypassing AP sites and strand breaks in
E. coli resulting in TM
through adenine incorporation in nascent mRNA. Elimination of the
enzymes that
process AP sites and strand breaks further increases TM. TM has
many potential
biological consequences, including adaptive mutagenesis (directed
evolution) in bacteria,
as well as cancer and neurodegenerative diseases in humans.
Discerning the
contributions of DNA repair to the process of TM can aid in our
understanding of the
initiation and progression of important human diseases.
Table of Contents
TABLE OF CONTENTS
Chapter 1
General Introduction 1
References 23
Chapter 2
Dynamic Flexibility of DNA Repair Pathways in Growth Arrested
Escherichia coli 58
Abstract 59
Introduction 60
Materials and Methods 63
Results and Discussion 64
References 72
Chapter 3
Abasic Sites and Strand Breaks in DNA Cause Transcriptional
Mutagenesis in Escherichia coli
83
Abstract 84
Introduction 85
Materials and Methods 86
Results 89
Discussion 95
References 100
Chapter 4
Discussion and Future Directions 117
References 135
FIGURES AND TABLES
Chapter 1
General Introduction 1
Figure 1
The Four Principle DNA Bases and the Major Sites of Base
Deamination and Hydrolytic and Oxidative Damage in DNA
47
Figure 2
Transcriptional Mutagenesis 48
Figure 3
Model for Base Excision Repair in E. coli 49
Figure 4
Details of Base Excision Repair End Structures in E. coli 50
Figure 5
Transcription-Coupled and Global Genome Repair in E.
coli 51
Figure 6
DNA Damage Examined in These Studies 52
Figure 7
Critical Steps for the Generation of Double-Stranded DNA Vectors
Containing Site-Specific Base Modifications 53
Figure 8
Transcriptional Mutagenesis Luciferase Assay System (TM-LAS)
54
Table 1
RNAP Bypass Efficiencies and Insertion Events at Sites of DNA
Damage 55
Table 2
Genes Involved in BER 56
Table 3
Genes involved in NER 57
Chapter 2
Dynamic Flexibility of DNA Repair Pathways in Growth Arrested
Escherichia coli 58
Figure 1
Transcriptional Mutagenesis Luciferase Assay System (TM-LAS)
77
Figure 2
DNA Repair Pathways Involved in Removal of Non-Bulky Lesions from
DNA in vivo. 79
Figure 3
Dynamic Flexibility of Interacting DNA Repair Pathways in E.
coli 80
Table 1
Strains and Primers 81
Table 2
Luciferase Activities 2 hr Following Induction in 8OG and U
Repair-Proficient and Deficient Cells 82
Chapter 3
Abasic Sites and Strand Breaks in DNA Cause Transcriptional
Mutagenesis in Escherichia coli 83
Figure 1
Transcriptional Mutagenesis Luciferase Assay System (TM-LAS)
105
Figure 2
AP Site-Mediated Transcriptional Mutagenesis in vivo 107
Figure 3
Observed Leakiness of the Luciferase Promoter Used in These Studies
109
Figure 4
Strand Break-Mediated Transcriptional Mutagenesis in vivo 103
Figure 5
RNAP Bypass of AP sites and Strand Breaks Reveal the Relationship
Between the Transcriptional Machinery and DNA Repair Processes
111
Table 1
Strains and Primers Used in This Study 112
Table 2
TM Caused by Abasic Sites and Strand Breaks in Repair-Proficient
and Deficient E. coli 113
Table 3
TM Caused by Abasic Sites and Strand Breaks in E. coli,
Including Control Constructs 115
Chapter 4
Discussion and Future Directions 117
Figure 1
Retromutagenesis 142
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