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Uracil DNA Glycosylase From Mycobacteria And Escherichia coli : Mechanism Of Uracil Excision From Synthetic Substrates And Differential Interaction With Uracil DNA Glycosylase Inhibitor (Ugi) And Single Stranded DNA Binding Proteins (SSBs)Padmakar, Purnapatre Kedar. 03 1900 (has links) (PDF)
No description available.
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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 TuberculosisBharti, 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.
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Interaction entre yOgg1, une ADN glycosylase de la voie BER, et l’ADN polymérase réplicative Polε chez Saccharomyces cerevisiae / yOgg1, a Saccharomyces cerevisiae bifunctional DNA glycosylase involved in base excision repair of oxidative DNA damage, interacts with the replicative DNA polymerase, PolεEssalhi, Kadija 12 December 2013 (has links)
Les dommages oxydatifs de l’ADN sont impliqués dans les processus pathologiques que sont le cancer, les maladies neurodégénératives ou le vieillissement. Ces dommages résultent en partie de l’action des espèces réactives de l’oxygène (ERO), qui proviennent du métabolisme cellulaire ou d’agents exogènes (physiques ou chimiques), et qui conduisent à différents types de lésions parmi lesquelles l’oxydation des bases de l’ADN (8-oxoguanine, 8-oxoG) ou la formation de sites abasiques AP (apurique/apyrimidique). Ces lésions, qui si elles ne sont pas éliminées conduisent à des processus de mutagenèse ou de mort cellulaire, sont prises en charge spécifiquement par le système de réparation de l’ADN par excision de base ou BER. Le BER est initié par l’action d’une ADN glycosylase, telles que la 8-oxoG-ADN glycosylase (Ogg1) chargée d’éliminer la 8-oxoG, une lésion très abondante. Une étude par « double-hybride » initiatrice de ce projet a révélé l’existence d’une interaction in vivo chez S. cerevisiae entre la protéine yOgg1 et la sous-unité catalytique de l’ADN polymérase réplicative Polε (yPol2), également impliquée dans la voie BER chez la levure. Nos travaux démontrent que yOgg1 et yPol2 interagissent bien physiquement entre elles et de façon spécifique. Une étude par troncations et mutagenèse dirigée nous a permis d’identifier le domaine 3’→5’ exonucléase de yPol2 comme faisant partie de la forme tronquée minimale de yPol2 capable d’interagir avec yOgg1. La poche du site actif de yOgg1 et/ou son voisinage immédiat pourrait contenir pour partie le site d’interaction pour yPol2. Nous observons d’ailleurs une corrélation nette entre l’activité de yOgg1 et sa capacité à interagir avec yPol2 dans la levure. De même, l’activité 3’→5’ exonucléase de yPol2 pourrait être liée à son interaction avec yOgg1. D’un point de vue fonctionnel, yPol2 stimulerait l’activité AP lyase de yOgg1 et le couplage entre l’activité ADN glycosylase et AP lyase de l’enzyme, permettant ainsi une meilleure coordination de l’étape d’excision du nucléoside endommagé et l’étape de resynthèse de l’ADN dans la voie BER. / Oxidative DNA damages are involved in pathological processes such as cancer, neurodegenerative diseases and aging. Part of these damages results from the action of reactive oxygen species (ROS), which are produced by cellular metabolism or (physical or chemical) exogenous agents. They lead to different types of DNA lesions including DNA base oxidation (8-oxoguanine, 8-oxoG) and abasic site formation (AP, apuric/apyrimidic). If not removed, these lesions lead to mutagenesis or cell death. Most of base lesions are dealt specifically by the base excision repair (BER) pathway. BER is initiated by a DNA glycosylase, such as 8-oxoG-DNA glycosylase (Ogg1) which is responsible for the removal of 8-oxoG. In previous unpublished work, a yeast two-hybrid study revealed the existence in S. cerevisiae of an interaction between yOgg1 and the catalytic subunit of the replicative DNA polymerase Polε (yPol2), also involved in the BER pathway in eukaryotes. Our work shows that yOgg1 and yPol2 physically and specifically interact with each other. Truncation and site-directed mutagenesis studies allowed us to identify the 3 ' → 5' exonuclease activity domain of yPol2 as part of the minimal form of yPol2 still able to interact with yOgg1. The active site of yOgg1 and/or its immediate vicinity may contain part of its interaction domain with yPol2. Besides, we observe a clear correlation between yOgg1 catalytic activity and its ability to interact with yPol2 in vivo. Similarly, the 3'→5' exonuclease activity of yPol2 could be useful to its interaction with yOgg1. From a functional point of view, yPol2 stimulates in vitro the AP lyase activity of yOgg1 and the coupling of both DNA glycosylase and AP lyase enzyme activity. The interaction yOgg1/yPol2 could allow a better coordination of damaged nucleoside excision and DNA re-synthesis steps in BER.
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DNA Repair Mechanisms, Aflatoxin B1-Induced DNA Damage and CarcinogenesisMULDER, JEANNE E 18 October 2013 (has links)
The studies described in this thesis investigated the relationship between DNA repair mechanisms, aflatoxin B1 (AFB1)-induced DNA damage and carcinogenesis. Mice deficient in 8-oxoguanine glycosylase (OGG1, the rate-limiting enzyme in repair of oxidized guanine), mice heterozygous for OGG1, and wild type mice, were exposed to a single tumourigenic dose (50 mg/kg) of AFB1. Neither ogg1 genotype nor AFB1 treatment affected levels of oxidized guanine in lung or liver 2 h post-treatment. ogg1 (-/-) mice had increased susceptibility to AFB1 toxicity, as reflected by increased mortality within one week of AFB1 exposure. AFB1 treatment did not significantly increase lung or liver tumourigenesis compared to DMSO controls. No difference was observed between ogg1 genotypes, although a non-significant trend towards AFB1-treated ogg1 (-/-) mice being more susceptible to tumourigenicity was apparent. Overall, deletion of ogg1 did not significantly affect AFB1-induced DNA damage or tumourigenicity, suggesting that oxidized guanine may not be a major contributor to AFB1-induced tumourigenesis.
The effects of AFB1 on DNA repair were assessed in p53 (a protein implicated in regulation of DNA repair) wild type and heterozygous mice. p53 (+/+) mice treated with 0, 0.2 or 1.0 ppm AFB1 for 26 weeks had increased nucleotide excision repair (NER) activities in lung and liver compared to control, which may represent an adaptive response to AFB1-derived DNA adducts. In p53 (+/-) mice, the AFB1-induced increase in NER was significantly attenuated, suggesting that loss of one allele of p53 limits the ability of NER to up-regulate in response to AFB1-induced DNA damage.
Twenty-six week exposure to AFB1 did not affect base excision repair (BER) in p53 (+/+) mouse lung or liver compared to control. BER was significantly decreased in livers from mice exposed to 1.0 ppm AFB1 compared to those exposed to 0.2 ppm AFB1, a result that was not due to liver cell death or to altered levels of OGG1 protein. In lungs and livers of p53 (+/-) mice, BER activity was unchanged by AFB1. As such, the difference in BER response between 0.2 ppm and 1.0 ppm AFB1 treatment seen in the p53 (+/+) mice appears to be p53 dependent. / Thesis (Ph.D, Pharmacology & Toxicology) -- Queen's University, 2013-10-17 22:24:31.577
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Strukturní studie mechanismů opravy poškozené DNA Nei glykosylasou / Structure and molecular mechanisms of DNA repair by Nei glycosylaseLandová, Barbora January 2019 (has links)
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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The role of DNA repair in DNA methylation dynamicsGould, Poppy Aeron January 2018 (has links)
The mammalian epigenome is globally reprogrammed at two stages of development; this involves the erasure and re-establishment of DNA methylation by both passive and active mechanisms, including DNA repair pathways, and occurs concurrently with an increase in developmental potency. In addition to Uhrf1 and the Tet enzymes, the interplay between activation induced cytidine deaminase (AID) and the DNA repair machinery has been implicated in epigenetic reprogramming of various in vivo and in vitro systems including mouse primordial germ cells, zygotes and induced pluripotent stem cells. AID deaminates cytosine to uracil and can also deaminate methylcytosine, whereas the primary role of UNG is to maintain the integrity of the genome through erasure of uracil. In this thesis, I have aimed to investigate the role of DNA repair in demethylation. To do this I have focused on the specific role of AID and UNG in the demethylation of a static system – primed serum ESCs and a dynamic system – serum to 2i (naïve) to epiblast-like ES cells. As the role of both AID and UNG involves genomic uracil, the central theme of my thesis is the impact of accumulation of uracil on DNA methylation levels in the genome. Therefore, my first aim was to develop a quantitative method to detect low levels of genomic uracil in DNA firstly, by mass spectrometry and secondly, by whole genome sequencing. In Chapter Three, I show that the impact of deamination during DNA preparation can be minimised, such that the level of genomic ESC uracil can be accurately determined as around 12,000 uracil per genome and that, as anticipated, Ung null ESCs have almost twice the genomic uracil content of wildtype ESCs. Secondly, I address the main question which is the impact of uracil accumulation on methylation levels. In order to do this, I generate two cell lines: Ung knockout and Aid over expressing, both of which should result in an increase in genomic uracil. I demonstrate that while over expression of Aid stimulates demethylation in static system and in a dynamic demethylating system, the impact of Ung knockout is less clear. In (static) serum ESCs, loss of Ung results in hypomethylation however, in order to transition to 2i (naïve) ESCs, a process which involves demethylation of the genome, it appears the Ung is required as loss of this gene inhibits proper demethylation. As such, I conclude that UNG-mediated DNA repair functions alongside passive demethylation, by reduction of UHRF1 levels, to demethylate 2i ESCs. To probe the mechanism by which accumulation of uracil in the genome alters methylation levels, I investigate the impact of Ung KO and Aid OE on global levels of DNA damage. I show that both cell lines have a greater incidence of double strand breaks compared to a wild type cell line, and accordingly, upregulate their DNA damage response pathway and the expression of certain repair genes. I suggest that increasing genomic levels of uracil causes genomic instability and that DNA demethylation occurs as a consequence of the repair of extensive DNA damage. More broadly, I suggest that ESCs are uniquely poised, due to their heightened DNA damage response, to use uracil as an intermediate of DNA demethylation. Interestingly, I also note that the biological impact on serum ESCs of loss of Ung appears to be an increase in pluripotency.
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Regulation of DNA methylation by DNA glycosylases MBD4 and TDG / Régulation de la methylation de l'ADN par les glycosylases MBD4 et TDGIbrahim, Abdulkhaleg 19 May 2015 (has links)
Chez les mammifères, la méthylation est une marque épigénétique ciblant la cytosine principalement dans un contexte CpG pour produire une 5mC. 5mC est très sensible à une déamination spontanée ou enzymatique, conduisant à la formation d'un mésappariement G/T. La 5mCpeut également être oxydée pour former successivement la 5hmC, la 5fC et la 5caC. Ces modifications de la 5mC participent aux processus actifs de déméthylation de l’ADN. Chez les mammifères, la thymine, dans le mésappariement G/T, est clivée par TDG et MBD4. TDG est également en mesure d'exciser 5fC et 5caC. Cette thèse avait pour but de clarifier la fonction de TDG et MBD4 dans la dynamique de la 5mC. Nous avons montré que MBD4 est associée aux protéines de réparation des mésappariements. Les tests enzymatiques, in vitro, montrent que le complexe MBD4/MMR a une activité bifonctionnelle (glycosylase/lyase) spécifique pour G/T, qui est régulée par la méthylation. Pour TDG, nous avons ciblé cette enzyme dans les cellules MEF et caractérisé la distribution des cytosines modifiées. Les résultats montrent des profils de méthylation/oxydation d'ADN qui sont régulés par TDG et surviennent principalement au niveau des répétitions de CA et dans les rétroéléments spécifiques de la lignée souris. / In mammals, methylation is an epigenetic mark targeting cytosine mainly in a CpG context, producing 5mC. 5mC is highly sensitive to a spontaneous or enzymatic deamination leading to G/Tmismatch. 5mC can also be oxidized to 5- 5hmC, 5fC and 5caC. These modifications of 5mC participate in the active demethylation processes. In mammals, the thymine in G/T mismatch is cleaved by TDG and MBD4 glycosylases. TDG is able also to excise the 5fC and 5caC.This thesis was to clarify the function of TDG and MBD4 in the dynamics of 5mC. We showed that MBD4 is associated with PMS2, MLH1, MSH2 and MSH6 proteins, four proteins involved in DNA mismatch repair (MMR). The in vitro enzymatic tests show that MBD4/MMR complex has a bifunctional glycosylase/lyase activity specific for G/T and is regulated by methylation.For TDG, we targeted this enzyme in MEF cells and characterized the distribution of modified cytosines. The results show that DNA methylation/oxidation patterns are regulated by TDG and occur mainly at CA repeats and at the mouse-lineage specific retro-elements.
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Identifica??o de genes MUTM em BACs da cana-de-a?ucar e caracteriza??o preliminar destes genes e seus promotoresTrindade, Adilson Silva da 22 February 2013 (has links)
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Previous issue date: 2013-02-22 / Sugarcane has an importance in Brazil due to sugar and biofuel production. Considering this aspect, there is basic research being done in order to understand its physiology to improve production. The aim of this research is the Base Excision Repair pathway, in special the enzyme MUTM DNA-glycosylase (formamidopyrimidine) which recognizes oxidized guanine in DNA. The sugarcane scMUTM genes were analyzed using four BACs (Bacterial Artificial Chromosome) from a sugarcane genomic library from R570 cultivar. The resulted showed the presence in the region that had homology to scMUTM the presence of transposable elements. Comparing the similarity, it was observed a highest similarity to Sorghum bicolor sequence, both nucleotide and peptide sequences. Furthermore, promoter regions from MUTM genes in some grass showed different cis-regulatory elements, among which, most were related to oxidative stress, suggesting a gene regulation by oxidative stress / A cana-de-a??car ? uma das principais culturas brasileiras e importante, principalmente, pela produ??o de a??car e biocombust?vel. Por isso, manter a qualidade das cultivares desta esp?cie tornou-se alvo das pesquisas envolvendo gen?tica e bioqu?mica moleculares. Um dos objetivos destas pesquisas ? descobrir informa??es ?teis sobre o material gen?tico que as cultivares da cana-de-a??car possuem, para utiliz?-las como ferramentas no melhoramento contra intemp?ries que afetam sua produ??o, muitas vezes, de forma dr?stica. O foco deste trabalho ? a via de reparo de DNA conhecida por Reparo por Excis?o de Base, mais precisamente, a enzima DNA-glicosilase MUTM (formamidopirimidina-DNA-glicosilase), a qual reconhece e repara guaninas oxidadas no DNA. A caracteriza??o dos genes MUTM da cana-de-a??car foi realizada a partir das an?lises de quatro BACs (Bacterial Artificial Chromosome) de uma biblioteca gen?mica da cultivar R570. Os resultados obtidos dos alinhamentos mostraram a presen?a marcante de elementos de transposi??o. Al?m disso, foi verificado que os genes MUTM foram altamente similares aos de Sorghum bicolor, tanto em sequ?ncias nucleot?dicas e pept?dicas, como na estrutura g?nica. Foi analisado tamb?m que as regi?es promotoras de genes MUTM em algumas gram?neas apresentam v?rios elementos reguladores de express?o, associados com o estresse oxidativo, indicando uma regula??o por estresse oxidativo
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Caracteriza??o dos genes scMUTM1 e scMUTM2 de cana-de-a??carMedeiros, Viviane Katielly Silva 23 February 2007 (has links)
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Previous issue date: 2007-02-23 / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico / Plants are organisms sessile and because of this they are susceptible to genotoxic effects due to environmental exposure such as light [including ultraviolet (UV)], heat, drought and chemicals agents. Therefore, there are differents pathways in order to detect a lesion and correct. These pathways are not well known in plants. The MutM/Fpg protein is a DNA glycosylase that is responsible for detect and correct oxidative lesions. In the sugarcane genome, it was found two possible cDNAs that had homology to this protein: scMUTM1 and scMUTM2. The aim of this work was to characterize the role of these cDNAs in plants. In order to do this, the expression level after oxidative stress was evaluated by semiquantitative RT-PCR. Another point analyzed in order to obtain the full-length gene, it was to use a sugarcane genomic library that was hybridized with both cDNAs as a probe. It was found two clones that will bought and sequenced. The promoter region was also cloned. It was obtained sequences only for scMUTM2 promoter region. The sequences obtained were divided into six groups. It was found regulatory motifs such as TATA-box, CAAT-box, oxidative stress element response and regulatory regions that response to light. The other point analyzed was to characterize the N-terminal region by PCR constructs. These constructs have deletions at 5 region. These sequences were introduce into Escherichia coli wild type strain (CC104) and double mutant (CC104mutMmutY). The results showed that proteins with deletions of scMUTM1 N-terminal region were able to complement the Fpg and MutY-glycosylase deficiency in CC104 mutMmutY reducing the spontaneous mutation frequency / As plantas s?o organismos particularmente suscept?veis aos efeitos genot?xicos devido a sua constante exposi??o a agentes do meio ambiente tais como a luz [incluindo a ultravioleta (UV)], o calor, a seca e diferentes subst?ncias qu?micas. Entretanto, existem diferentes mecanismos de reparo para detectar estas les?es e corrigi-las. Entretanto, em plantas estas vias s?o pouco compreendidas. Uma das vias ? a por excis?o de bases (BER). A prote?na MUTM/FPG ? uma DNA glicosilase da via BER que corrige danos oxidativos. No genoma da cana-de-a??car foram encontrados dois poss?veis cDNAs que possuem homologia de seq??ncia a esta prote?na: scMUTM1 e scMUTM2. O objetivo deste trabalho foi caracterizar o papel destes genes em plantas. Para isto, o n?vel de express?o dos genes ap?s estresse oxidativo foi avaliado atrav?s de RT-PCR semiquantitativo. Para obter a sequ?ncia completa dos gene, uma biblioteca de DNA gen?mico de cana-de-a??car foi hibridizada com sondas radioativas para ambos cDNAs, encontrando-se dois clones em potencial. A regi?o promotora foi clonada, seq?enciada e analisada. Dentro das seq??ncias obtidas para a regi?o promotora de scMUTM2, estas podem ser divididas em seis grupos. Os motivos regulat?rios foram identificados, tais como o TATA-box, CAAT-box, elementos de resposta ao estresse oxidativo e elementos de resposta ? luz. Um outro ponto de interesse neste trabalho foi a caracteriza??o da regi?o N-terminal da prote?na scMUTM1. Para isto, foram realizadas algumas constru??es via PCR. Estas constru??es foram posteriormente introduzidas em cepas selvagem (CC104) e duplo mutante (CC104mutMmutY) de Escherichia coli e foram realizados ensaios de complementa??o de modo a avaliar a import?ncia de cada regi?o para o reconhecimento e corre??o das les?es. Os resultados mostraram que as prote?nas com dele??es na por??o N-terminal de scMUTM1 s?o capazes de complementar a defici?ncia de Fpg and MutY-glicosilase na bact?ria CC104 mutMmutY reduzindo assim a freq??ncia de muta??o espont?nea
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ETUDE DES INTERACTIONS ENTRE PROTEINES ET LESIONS DE L'ADN PAR RESONANCE PLASMONIQUE DE SURFACE PAR IMAGERIE (SPRI)Corne, Christelle 13 July 2010 (has links) (PDF)
L'ADN étant le support de l'information génétique, les lésions de l'ADN provoquées par différents stress physiques ou chimiques sont un défi pour les systèmes de réparation cellulaire. Parmi ceux-ci le système de réparation par excision de bases (BER) implique plusieurs enzymes dont les objectifs sont la reconnaissance et le retrait de la base lésée, fonctions bien connues pour deux glycosylases : Fpg Procaryote et OGG1 Eucaryote. De nombreuses approches ont été décrites pour étudier les interactions ADN/protéine in vitro. Avec la résonance plasmonique de surface par imagerie (SPRi), nous disposons d'une technique d'analyse en temps réel, sans marquage avec laquelle nous avons pu observer des interactions parallélisées d'une même protéine enzymatique purifiée (Fpg, OGG1, EndoIV ou Ape1) vis-à-vis de différentes lésions sur des oligonucléotides de synthèse immobilisés sur une surface d'or. Les dommages étudiés sont une base oxydée (8-oxoG), une base cyclisée (cycloadénine) et des analogues de sites abasiques (THF et C3). Nous avons également étudié l'action de ces mêmes enzymes sur des lésions multiples, en tandem, associant les bases 8-oxoG et 8-oxoA sur le même brin d'ADN. L'originalité de notre dispositif associe l'analyse directe de l'interaction ADN/protéine et l'approche indirecte de sa conséquence par une stratégie d'hybridation et d'amplification du signal après une rampe thermique. Les résultats obtenus permettent d'envisager l'utilisation de notre technique pour observer la réparation simultanée de certaines lésions par des extraits cellulaires pour des travaux de biochimie ou des extraits tissulaires humains pour des travaux de biologie médicale.
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