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Mechanistic insights into alcohol-induced interstrand crosslink repair by the nuclease SLX4-XPF-ERCC1
Havlíková, Jana ; Šilhán, Jan (advisor) ; Lux, Vanda (referee)
Alcohol ranks among the most widely used recreational drugs in the world, even though it is considered a risk factor for more than 200 diseases. The primary negative impact of alcohol lies in its metabolite, acetaldehyde, which, as a highly reactive compound, can form mutagenic adducts and interstrand crosslinks (ICLs) in DNA. The formation of ICLs, which have a covalent nature and block the separation of the two DNA strands during replication, is one of the important causes of mutagenesis and carcinogenesis. To maintain genomic stability, repair mechanisms have evolved. One of them is a pathway that uses proteins encoded by Fanconi anaemia genes, whose defects lead to the disease of the same name. Defects in repair pathways can be particularly dangerous in individuals with impaired functionality in other metabolic pathways, such as alcoholics and individuals with mutations in genes that result in the accumulation of toxic acetaldehyde. The theoretical part of this thesis deals with alcohol metabolism, in vivo acetaldehyde formation, and its interactions with DNA. The ICL and their repair pathways are characterized in more detail. A separate chapter is dedicated to Fanconi anaemia. The practical part of this work focuses on the preparation of site-specific acetaldehyde- induced ICL (AA-ICLs) and the study...
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Structure and molecular mechanisms of DNA repair by Nei glycosylase
Landová, Barbora ; Šilhán, Jan (advisor) ; Lux, Vanda (referee)
Abasic sites (Ap site, from apurinic/apyrimidinic) are one of the most common lesions generated in DNA by spontaneous base loss or DNA repair processes. There are two equilibrating forms of an Ap site - ring-open aldehyde and cyclic hemiacetal. Ring- opened aldehydes are reactive electrophilic groups capable of formation covalent adduct with nucleophilic sites in DNA. DNA interstrand cross-link (ICL) resulting from the Ap sites is formed spontaneously as a covalent bond between ring-open aldehyde and amin group of adenin residue in the opposite strand of double stranded DNA. ICLs block DNA replication and transcription. The formation of Ap site derived ICL is relatively long process taking several hours. We assume that the ring-opening of an abasic site is the rate-limiting step in the formation of the thermodynamic ICL. However, formation, stability and DNA repair of Ap-ICL are still poorly understood processes. Here, I have set up mechanistic in vitro experiments to reveal and calculate the probability of Ap-ICl formation in vivo. In more detail, I study the rates of formation of Ap-ICLs in the sequence context of neighbouring nucleotides of freshly formed covalent bond of ICL. I focus on sequence preference, the influence of AT/ GC rich regions and the length of oligonucleotides. I have...
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