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1	The construction and phenotypic characterization of mycobacterial mutants deficient in DNA glycosylases Goosens, Vivianne Jacoba 09 April 2009 (has links) Mycobacterium tuberculosis is an exquisitely adapted intracellular pathogen that encounters hostile, host-derived reactive nitrogen and oxygen intermediates during the course of infection of its human host. These radicals cause DNA damage, which is repaired through various pathways to allow for the continued survival of the organism. Base excision repair (BER) is one such pathway, which depends on DNA glycosylases to identify and excise damaged DNA bases. Formamidopyrimidine DNA glycosylase (Fpg/ MutM/ FAPY) and Endonuclease VIII (Nei) are such enzymes, which both target oxidatively damaged DNA and together, form the Fpg family of DNA glycosylases. Bioinformatic analyses identified two copies each of Fpg and Nei-encoding genes in M. tuberculosis as well as in its non-pathogenic relative, Mycobacterium smegmatis. To understand the role of these multiple glycosylases in the maintenance of genomic integrity and survival of mycobacteria, the genes encoding the four Fpg/Nei glycosylases were individually deleted in M. smegmatis strain mc2155 by homologous recombination. In addition to the four single mutants, double and triple Fpg and Nei glycosylase knockout mutants were generated by sequential gene knockout. When compared to the parental strain, the single and double mutants showed no variation in growth kinetics, no increased sensitivity to hydrogen peroxide and no increase in spontaneous mutation rates. However, a slight increase in frequency of spontaneous C T transition mutations was observed in double knockout mutants compared to the wild type and single mutant strains. These results suggest that these enzymes may be part of an extensive network of enzymes which collectively work to enhance the overall survival of M. smegmatis through the repair of oxidatively damaged DNA. Mycobacteria DNA glycosylases DNA repair
2	Random mutations, protein mutability, and DNA repair : understanding protein tolerance to random amino acid changes through directed evolution / Guo, Haiwei H., January 2004 (has links) Thesis (Ph. D.)--University of Washington, 2004. / Vita. Includes bibliographical references (leaves 88-100).
3	Oxidative damage and the DNA glycosylase MutYH / Jansson, Kristina, January 2010 (has links) Diss. (sammanfattning) Göteborg : Göteborgs universitet, 2010. / Härtill 4 uppsatser.
4	Biochemical Characterization of DNA Glycosylases from Mycobacterium Tuberculosis Guo, Yin 16 June 2010 (has links) The DNA glycosylases function in the first step of the base excision repair (BER) process, that is responsible for removing base lesions resulting from oxidation, alkylation or deamination. The DNA glycosylases that recognize oxidative base damage fall into two general families: the Fpg/Nei family and the Nth superfamily. Based on protein sequence alignments, we identified four putative Fpg/Nei family members as well as a putative Nth protein in Mycobacterium tuberculosis H37Rv, the causative agent of tuberculosis. While Fpg proteins are widely distributed among the bacteria and plants, Nei homologs are sparsely distributed across phyla, and are only found in γ-proteobacteria, actinobacteria and metazoans. Interestingly, M. tuberculosis H37Rv harbors two proteins (Rv2464c and Rv3297) from the Nei clade and two (Rv2924c and Rv0944) from the Fpg clade. All four Fpg/Nei proteins were successfully overexpressed by using a novel bicistronic vector, which theoretically prevented stable mRNA secondary structure(s) surrounding the translation initiation region (TIR) thereby improving translation efficiency. Additionally, MtuNth (Rv3674c) was also overexpressed in soluble form. The substrate specificities of the purified enzymes were characterized in vitro with oligonucleotide substrates containing single lesions. Some were further characterized by gas chromatography/mass spectrometry (GC/MS) analysis of products released from γ-irradiated DNA. MtuFpg1 (Rv2924c) has a substrate specificity similar to that of EcoFpg and recognizes oxidized purines. Both EcoFpg and MtuFpg1 are more efficient at removing spiroiminodihydantoin (Sp) than 7,8-dihydro-8-oxoguanine (8-oxoG); however, MtuFpg1 has a substantially increased opposite base discrimination compared to EcoFpg. The Rv0944 gene encodes MtuFpg2, which contains only the C-terminal domain of an Fpg protein and has no detectable DNA binding activity or DNA glycosylase/lyase activity and thus appears to be a pseudogene. MtuNei1 (Rv2464c) recognizes oxidized pyrimidines not only on doublestranded DNA but also on single-stranded DNA. It also exhibits uracil DNA glycosylase activity as well as weak activity on FapyA and FapyG. MtuNth recognizes a variety of oxidized bases, such as urea, 5,6-dihydrouracil (DHU), 5-hydroxyuracil (5- OHU), 5-hydroxycytosine (5-OHC) and methylhydantoin (MeHyd) as well as FapyA, FapyG and 8-oxoadenine (8-oxoA). Both MtuNei1 and MtuNth excise thymine glycol (Tg); however, MtuNei1 strongly prefers the (5R) isomers of Tg, whereas MtuNth recognizes only the (5S) isomers. The other Nei paralog, MtuNei2 (Rv3297), did not demonstrate activity in vitro as a recombinant protein, but when expressed in Escherichia coli, the protein decreased the spontaneous mutation frequency of both the fpg mutY nei triple and nei nth double mutants, suggesting that MtuNei2 is functionally active in vivo recognizing both guanine and cytosine oxidation products. The kinetic parameters of the MtuFpg1, MtuNei1 and MtuNth proteins on selected substrates were also determined and compared to those of their E. coli homologs. Since pathogenic bacteria are often exposed to an oxidative environment, such as in macrophages, our data, together with previous observations, support the idea that the BER pathway is of importance in protecting M. tuberculosis against oxidative stress, as has been observed with other pathogens . Mycobacterium tuberculosis Base Excision repair Oxidative DNA glycosylases
5	Kinetic analysis of the contribution of base flipping to the substrate specificity and catalytic activity of human alkyladenine dna glycosylase Vallur, Aarthy C., January 2004 (has links) Thesis (Ph.D.)--University of Florida, 2004. / Typescript. Title from title page of source document. Document formatted into pages; contains 135 pages. Includes Vita. Includes bibliographical references.
6	Control of retroviral replication by host cellular factors / Kaiser, Shari Marie. January 2007 (has links) Thesis (Ph. D.)--University of Washington, 2007. / Vita. Includes bibliographical references (leaves 115-127).
7	Studies On The Mechanism Of Uracil Excision Repair In Escherichia Coli And Structure-Function Relationship Of Single Stranded DNA Binding Proteins From Escherichia Coli And Mycobacterium Tuberculosis Bharti, Sanjay Kumar 05 1900 (has links) (PDF) To maintain the genomic integrity, cell has evolved various DNA repair pathways. Base Excision Repair pathway (BER) is one such DNA repair pathway which is dedicated to protect DNA from small lesions such as oxidation, alkylation, deamination and loss of bases. Uracil is a promutagenic base which appears in the genome as a result of misincorporation of dUTP or due to oxidative deamination of cytosine. Uracil-DNA glycosylases (UDGs) are DNA repair enzymes that initiate multistep base excision repair (BER) pathway to excise uracil from DNA. Excision of uracil generates an abasic site (APDNA). AP-sites are cytotoxic and mutagenic to the cell. AP endonucleases act downstream to UDG in this pathway and generate substrates for DNA polymerase to fill in the correct bases. The cytotoxicity of AP-sites raises the question whether uracil excision activity is coupled to AP endonuclease activity. Also, there is transient formation of single stranded DNA (ssDNA) during DNA metabolic processes such as replication, repair and recombination. ssDNA is more prone to various nucleases and DNA damaging agents. All the living organisms encode single stranded DNA binding protein (SSB) that binds to ssDNA and protects it from various damages. In addition, SSB plays a vital role during DNA replication, repair and recombination. Studies on SSBs from prototype Escherichia coli and an important human pathogen, Mycobacterium tuberculosis have shown that despite significant variations in their quaternary structures, the DNA binding and oligomerization properties of the two are similar. My PhD thesis consists of four Chapters. Chapter 1 summarizes the relevant literature review on DNA damage and repair with an emphasis on uracil DNA glycosylase and its interacting protein, SSB. Chapters 2 and 3 describe my studies on the mechanism of uracil excision repair in E. coli. Chapter 4 describes my findings on the structure-function relationship of single stranded DNA binding proteins from E. coli and M. tuberculosis. Specific details of my research are summarized as follows: (1) Analysis of the impact of allelic exchange of ung with a mutant gene encoding Uracil DNA Glycosylase attenuated in AP-DNA binding in the maintenance of genomic integrity in Escherichia coli. There are five families of UDGs. Of these, Ung proteins (family 1 UDGs) represent highly efficient and evolutionary conserved enzymes. Structural and biochemical analysis of Ung proteins has identified two conserved motif, motif A (62GQDPY66) and motif B (187HPSPLS192) in E. coli that are important for the catalysis by Ung enzyme. Y66 of motif A is in van der Waals contact with the C5 position of the uracil and prevents entry of other bases. Earlier study from the laboratory showed that the Y66W and Y66H mutants of Ung were compromised by ~7 and ~170 fold, respectively in their uracil excision activities. However, unlike the wild-type and Y66H proteins, Y66W was not inhibited by its product (uracil or AP-DNA). In this study, by fluorescence anisotropy measurements I have shown that compared with the wild-type protein, the Y66W mutant is moderately compromised and attenuated in binding to AP-DNA. Allelic exchange of ung in E. coli with ung::kan, ungY66H:amp or ungY66W:amp alleles showed ~5, ~3.0 and ~2.0 fold, respectively increase in mutation frequencies. Analysis of mutations in the rifampicin resistance determining region (RRDR) of rpoB revealed that the Y66W allele resulted in an increase in A to G (or T to C) mutations. However, the increase in A to G mutations was mitigated upon expression of wild-type Ung from a plasmid borne gene. Biochemical and computational analyses showed that the Y66W mutant maintains strict specificity for uracil excision from DNA. Interestingly, a strain deficient in AP-endonucleases also showed an increase in A to G mutations. These findings have been discussed in the context of a proposal that the residency of DNA glycosylase(s) onto the AP-sites they generate shields them until recruitment of AP-endonucleases for further repair. It is proposed that an error prone replication against AP-sites (as a result of uracil excision activities on A:U pair) may result in A to G mutations. 2. Mechanism of appearance of A to G mutations in ungY66W:amp strain of Escherichia coli. In this part of my study, I have investigated the role of error prone DNA polymerases in the mutational specificity of ungY66W:amp strain. It was observed from various studies in E. coli that, DNA polymerase IV (Pol IV) and DNA polymerase V (Pol V) are involved in error-prone replication on damaged or AP-site containing DNA. E. coli strains containing deletion of either dinB (encoding DNA Pol IV) or umuDC (encoding DNA Pol V) were generated and used to study mutation frequency and mutation spectrum. Deletion of DNA Pol V resulted in a decrease in A to G mutations in ungY66W:amp E. coli strain, suggesting that increase in A to G mutations were a consequence of error prone incorporation by DNA Pol V. 3. Structure and Function studies on Single Stranded DNA Binding Proteins from Escherichia coli and Mycobacterium tuberculosis. SSB from M. tuberculosis (MtuSSB) has similar domain organization as the EcoSSB. Moreover, the biochemical properties such as oligomerization, DNA binding affinity and minimum binding site size requirements were shown to be similar to EcoSSB. However, structural studies suggested that quaternary structures of these two SSBs are variable. In this study I have used X-ray crystal structure information of these two SSBs to generate various chimeras after swapping at various regions of SSBs. Chimeras mβ1, mβ1’β2, mβ1-β5, mβ1-β6, and mβ4-β5 SSBs were generated by substituting β1 (residues 611), β1’β2 (residues 21-45), β1-β5 (residues 1 to 111), β1-β6 including a downstream sequence (residues 1 to 130), and β4-β5 (residues 74-111) regions of EcoSSB with the corresponding sequences of MtuSSB, respectively. Additionally, mβ1’β2ESWR SSB was generated by mutating the MtuSSB specific ‘PRIY’ sequence in the β2 strand of mβ1’β2 SSB to EcoSSB specific ‘ESWR’ sequence. Biochemical characterization revealed that except for mβ1 SSB, all chimeras and a control construct lacking the C-terminal domain (ΔC SSB) efficiently bound DNA in modes corresponding to limited and unlimited modes of binding. The mβ1 SSB was also hypersensitive to chymotrypsin treatment. The mβ1-β6, MtuSSB, mβ1’β2 and mβ1-β5 constructs complemented E. coli Δssb in a dose dependent manner. Complementation by the mβ1-β5 SSB was poor. In contrast, mβ1’β2ESWR SSB complemented E. coli as well as EcoSSB. Interestingly, the inefficiently functioning SSBs resulted in an elongated cell/filamentation phenotype of E. coli. Taken together, our observations suggest that specific interactions within the DNA binding domain of the homotetrameric SSBs are crucial for their biological function. DNA Binding Proteins Escherichia coli Mycobacterium tuberculosis DNA Repair Uracil DNA Glycosylase (UDG) Single Stranded DNA Binding Proteins DNA Damage DNA Polymerases ungY66W:amp Strain Uracil Excision Repair Uracil DNA-Glycosylase Inhibitor (Ugi) DNA Glycosylases Biochemistry
8	The role of Organic Cation Transporters in the pharmacokinetics of clinically relevant DNA damaging agents : in vivo and in silico studies Papaluca, Arturo 03 1900 (has links) No description available. Transporteurs de cations organiques Apoptose Modélisation in silico Expression génique 5-hydroxyméthyluracil ADN glycosylases AP endonucléases Drug uptake and resistance Organic Cation Transporters C. elegans Apoptosis DNA damage and repair pathways In silico modeling Gene expression DNA repair pathway inhibitor 5-hydroxymethyluracil DNA glycosylases AP endonucleases

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