Efeito da p53 sobre a expressão e atividade da enzima de reparo de DNA Timina-DNA Glicosilase / Effect of p53 on the expression and activity of DNA repair enzyme thymine-DNA glycosylase

Nathalia de Oliveira Meireles da Costa

22 February 2011

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / O câncer de esôfago é uma malignidade altamente freqüente e letal. Uma característica específica das áreas de alta incidência de câncer de esôfago é a grande proporção de duplas mutações no gene TP53, sendo, ao menos uma delas, uma transição G para A em sítios CpG. Essas transições resultam de malpareamentos GT causados pela desaminação espontânea da 5-metilcitosina em ilhotas CpG. A enzima de reparo de DNA Timina-DNA Glicosilase (TDG) é responsável pelo primeiro passo na remoção da timina de malpareamentos GT em CpG. A alta proporção de mutações em sítios CpG em câncer de esôfago das áreas de alta incidência sugere que a via de reparo de DNA iniciada pela TDG pode estar prejudicada. A presença de duplas mutações, sendo ao menos uma delas em CpG, levantou a hipótese de que a primeira mutação no TP53 reduz a atividade da via de reparo iniciada pela TDG, que acarretaria a segunda mutação em sítios CpG. Dessa forma, o objetivo desse trabalho foi analisar o efeito da p53 sobre a expressão e atividade da TDG. Os resultados obtidos mostram que a expressão de TDG é regulada transcricionalmente pela p53 numa gama de linhagens celulares e é induzida pelo dano ao DNA, de forma p53-dependente. Além disto, os resultados apontam um possível papel da proteína p53 ativa na migração nuclear e atividade da TDG. Estes resultados ainda nos levam à conclusão de que o silenciamento de TDG aumenta a sensibilidade à morte celular induzida por MMS quando a p53 é encontrada na forma selvagem, mas não quando esta proteína é mutada, e de que o status mutacional de TP53 parece afetar a expressão de TDG em CEE primários. Juntos esses resultados sugerem que a p53 regula o reparo de DNA mediado pela TDG e que a inativação de p53 em células tumorais pode contribuir para a aquisição de um mutator phenotype. / Esophageal squamous cell carcinoma (ESCC) is a highly frequent and fatal malignancy in the world. A peculiar characteristic of the high incidence areas of esophageal cancer is the large proportion of double mutations in TP53 gene, being, at least one of them, a G to A transition at CpG sites. These transitions result from GT mismatches caused by the spontaneous deamination of 5-methylcytosine at CpG sites. The DNA repair enzyme Thymine-DNA Glycosylase (TDG) is responsible for the first step in the removal of the thymidine from the GT mismatches at CpG sites. The high proportion of mutations at CpG sites in esophageal tumors in the high incidence areas suggests that the DNA repair pathway initiated by TDG might be impaired. The large number of double mutations, with one being at a CpG site, raised the possibility that the first mutation in TP53 reduces the activity of the TDG base excision repair pathway, increasing the chance of a second mutation event at a CpG site. In this way, the aim of this work was to analyze the effect of p53 on the expression and activity of TDG. The results achieved show that TDG expression is regulated by p53 in a variety of cells lines at the trancriptional level and induced by DNAdamage in a p53-dependent manner. Furthermore, these results point out a possible role of active p53 in the nuclear migration and activity of TDG. The results further support the notion that TDG silencing increases the sensitivity to cell death induced by Methylmethane sulphonate when p53 is found in a wild-type, but not in a mutant form, and that TP53 mutation seems to affect TDG expression in primary ESCC. Together, these results suggest that p53 regulates TDG-mediated repair and that p53 inactivation in cancer cells may contribute to a mutator phenotype through loss of TDG function.

Reparo de DNA

TDG

Mutator phenotype

Estabilidade genética

DNA repair

TDG

Mutator phenotype

Ggenetic stability

Ciências Biológicas

Efeito da p53 sobre a expressão e atividade da enzima de reparo de DNA Timina-DNA Glicosilase / Effect of p53 on the expression and activity of DNA repair enzyme thymine-DNA glycosylase

Nathalia de Oliveira Meireles da Costa

22 February 2011

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / O câncer de esôfago é uma malignidade altamente freqüente e letal. Uma característica específica das áreas de alta incidência de câncer de esôfago é a grande proporção de duplas mutações no gene TP53, sendo, ao menos uma delas, uma transição G para A em sítios CpG. Essas transições resultam de malpareamentos GT causados pela desaminação espontânea da 5-metilcitosina em ilhotas CpG. A enzima de reparo de DNA Timina-DNA Glicosilase (TDG) é responsável pelo primeiro passo na remoção da timina de malpareamentos GT em CpG. A alta proporção de mutações em sítios CpG em câncer de esôfago das áreas de alta incidência sugere que a via de reparo de DNA iniciada pela TDG pode estar prejudicada. A presença de duplas mutações, sendo ao menos uma delas em CpG, levantou a hipótese de que a primeira mutação no TP53 reduz a atividade da via de reparo iniciada pela TDG, que acarretaria a segunda mutação em sítios CpG. Dessa forma, o objetivo desse trabalho foi analisar o efeito da p53 sobre a expressão e atividade da TDG. Os resultados obtidos mostram que a expressão de TDG é regulada transcricionalmente pela p53 numa gama de linhagens celulares e é induzida pelo dano ao DNA, de forma p53-dependente. Além disto, os resultados apontam um possível papel da proteína p53 ativa na migração nuclear e atividade da TDG. Estes resultados ainda nos levam à conclusão de que o silenciamento de TDG aumenta a sensibilidade à morte celular induzida por MMS quando a p53 é encontrada na forma selvagem, mas não quando esta proteína é mutada, e de que o status mutacional de TP53 parece afetar a expressão de TDG em CEE primários. Juntos esses resultados sugerem que a p53 regula o reparo de DNA mediado pela TDG e que a inativação de p53 em células tumorais pode contribuir para a aquisição de um mutator phenotype. / Esophageal squamous cell carcinoma (ESCC) is a highly frequent and fatal malignancy in the world. A peculiar characteristic of the high incidence areas of esophageal cancer is the large proportion of double mutations in TP53 gene, being, at least one of them, a G to A transition at CpG sites. These transitions result from GT mismatches caused by the spontaneous deamination of 5-methylcytosine at CpG sites. The DNA repair enzyme Thymine-DNA Glycosylase (TDG) is responsible for the first step in the removal of the thymidine from the GT mismatches at CpG sites. The high proportion of mutations at CpG sites in esophageal tumors in the high incidence areas suggests that the DNA repair pathway initiated by TDG might be impaired. The large number of double mutations, with one being at a CpG site, raised the possibility that the first mutation in TP53 reduces the activity of the TDG base excision repair pathway, increasing the chance of a second mutation event at a CpG site. In this way, the aim of this work was to analyze the effect of p53 on the expression and activity of TDG. The results achieved show that TDG expression is regulated by p53 in a variety of cells lines at the trancriptional level and induced by DNAdamage in a p53-dependent manner. Furthermore, these results point out a possible role of active p53 in the nuclear migration and activity of TDG. The results further support the notion that TDG silencing increases the sensitivity to cell death induced by Methylmethane sulphonate when p53 is found in a wild-type, but not in a mutant form, and that TP53 mutation seems to affect TDG expression in primary ESCC. Together, these results suggest that p53 regulates TDG-mediated repair and that p53 inactivation in cancer cells may contribute to a mutator phenotype through loss of TDG function.

Reparo de DNA

TDG

Mutator phenotype

Estabilidade genética

DNA repair

TDG

Mutator phenotype

Ggenetic stability

Ciências Biológicas

The molecular basis of the genetic mosaicism in hereditary tyrosinemia (HT1) / Etresia van Dyk

Van Dyk, Etresia

January 2011

Hereditary tyrosinemia type 1 (HT1) is an autosomal recessive disorder of the tyrosine degradation pathway. The defective fumarylacetoacetate hydrolase enzyme causes the accumulation of upstream metabolites such as fumarylacetoacetate (FAA), maleylacetoacetate (MAA), succinylacetone (SA) and p-hydroxyphenylpyruvic acid (pHPPA). In vitro and in vivo studies showed that the accumulation of these metabolites are detrimental to cell homeostasis, by inducing cell cycle arrest, apoptosis, and endoplasmic reticulum stress, depleting GSH, inhibiting DNA ligase, causing chromosomal instability, etc. For in vivo studies different models of HT1 were developed. Most notably was the fah deficient mouse, whose neonatally lethal phenotype is rescued by the administration of 2-(2-nitro-4-trifluoromethylbenzoyl)-1,3-cyclohexanedione (NTBC). Although, this model most closely resembles the human phenotype with elevated tyrosine levels and the development of hepatocellular carcinoma (HCC), the model is not human genome based. Both the in vitro and in vivo studies suggested that DNA repair is affected in HT1. However, it is not yet clear which DNA repair mechanisms are affected and if only protein functionality is affected, or if expression of DNA repair proteins are also affected. Characteristic of HT1 is the high prevalence of HCC and the presence of liver mosaicism. The liver mosaicism observed in HT1 patients are the result of reversion of the inherited mutation to wild-type. The general consensus is that the reversion is the result of a true back mutation. However, the mechanism underlying the back mutation is still unresolved. It was suggested that cancer develops either through a chromosomal instability mutator phenotype, a microsatellite instability mutator phenotype, or a point mutation instability mutator phenotype. In HT1 only chromosomal instability was reported. The aims of this study were to contribute to the understanding of the molecular basis of the genetic mosaicism in hereditary tyrosinemia type 1. More specifically, determine whether baseand nucleotide DNA repair mechanisms are affected and to what extent, and to determine if microsatellite instability is found in HT1. To achieve these aims, a parallel approach was followed: i.e. to develop a HT1 hepatic cell model and to use HT1 related models and HT1 patient material. To assess the molecular basis of the genetic mosaicism in HT1, the comet assay, gene expression assays, microsatellite instability assays, high resolution melting and dideoxy sequencing techniques were employed. Results from the comet assay showed that the HT1 accumulating metabolites, SA and pHPPA, decreased the capacity of cells for base- and nucleotide excision repair. Gene expression assays showed that short term exposure to SA and/or pHPPA do not affect expression of hOGG1 or ERCC1. The expression of these genes were, however, low in HT1 patient samples. Microsatellite instability assays showed allelic imbalance on chromosome 7 of the mouse genome, and microsatellite instability in the lymphocytes of HT1 patients. Although high resolution melt and sequencing results did not reveal any de novo mutations in fah or hprt1, the appearance of de novo mutations on other parts of the genome can not be ruled out. To conclude, results presented in this thesis, for the first time show that in HT1 the initiating proteins of the base- and nucleotide repair mechanisms are affected, the gene expression of DNA repair proteins are low, and microsatellite instability is found in HT1. By contributing to the elucidation of the mechanism underlying the development of HT1-associated HCC, and providing evidence for the development of a mutator phenotype, the results presented in this thesis contributes to the understanding of the molecular mechanisms underlying the genetic mosaicism in HT1. In addition to these contributions, a hypothesis is posited, which suggests that a point mutation instability (PIN) mutator phenotype is the mechanism underlying the mutation reversions seen in HT1. / Thesis (Ph.D. (Biochemistry))--North-West University, Potchefstroom Campus, 2012

Hereditary tyrosinemia type1

Mosaicism

Hepatocellular carcinoma

DNA repair

Genome instability

Mutator phenotype

The molecular basis of the genetic mosaicism in hereditary tyrosinemia (HT1) / Etresia van Dyk

Van Dyk, Etresia

January 2011

Hereditary tyrosinemia type 1 (HT1) is an autosomal recessive disorder of the tyrosine degradation pathway. The defective fumarylacetoacetate hydrolase enzyme causes the accumulation of upstream metabolites such as fumarylacetoacetate (FAA), maleylacetoacetate (MAA), succinylacetone (SA) and p-hydroxyphenylpyruvic acid (pHPPA). In vitro and in vivo studies showed that the accumulation of these metabolites are detrimental to cell homeostasis, by inducing cell cycle arrest, apoptosis, and endoplasmic reticulum stress, depleting GSH, inhibiting DNA ligase, causing chromosomal instability, etc. For in vivo studies different models of HT1 were developed. Most notably was the fah deficient mouse, whose neonatally lethal phenotype is rescued by the administration of 2-(2-nitro-4-trifluoromethylbenzoyl)-1,3-cyclohexanedione (NTBC). Although, this model most closely resembles the human phenotype with elevated tyrosine levels and the development of hepatocellular carcinoma (HCC), the model is not human genome based. Both the in vitro and in vivo studies suggested that DNA repair is affected in HT1. However, it is not yet clear which DNA repair mechanisms are affected and if only protein functionality is affected, or if expression of DNA repair proteins are also affected. Characteristic of HT1 is the high prevalence of HCC and the presence of liver mosaicism. The liver mosaicism observed in HT1 patients are the result of reversion of the inherited mutation to wild-type. The general consensus is that the reversion is the result of a true back mutation. However, the mechanism underlying the back mutation is still unresolved. It was suggested that cancer develops either through a chromosomal instability mutator phenotype, a microsatellite instability mutator phenotype, or a point mutation instability mutator phenotype. In HT1 only chromosomal instability was reported. The aims of this study were to contribute to the understanding of the molecular basis of the genetic mosaicism in hereditary tyrosinemia type 1. More specifically, determine whether baseand nucleotide DNA repair mechanisms are affected and to what extent, and to determine if microsatellite instability is found in HT1. To achieve these aims, a parallel approach was followed: i.e. to develop a HT1 hepatic cell model and to use HT1 related models and HT1 patient material. To assess the molecular basis of the genetic mosaicism in HT1, the comet assay, gene expression assays, microsatellite instability assays, high resolution melting and dideoxy sequencing techniques were employed. Results from the comet assay showed that the HT1 accumulating metabolites, SA and pHPPA, decreased the capacity of cells for base- and nucleotide excision repair. Gene expression assays showed that short term exposure to SA and/or pHPPA do not affect expression of hOGG1 or ERCC1. The expression of these genes were, however, low in HT1 patient samples. Microsatellite instability assays showed allelic imbalance on chromosome 7 of the mouse genome, and microsatellite instability in the lymphocytes of HT1 patients. Although high resolution melt and sequencing results did not reveal any de novo mutations in fah or hprt1, the appearance of de novo mutations on other parts of the genome can not be ruled out. To conclude, results presented in this thesis, for the first time show that in HT1 the initiating proteins of the base- and nucleotide repair mechanisms are affected, the gene expression of DNA repair proteins are low, and microsatellite instability is found in HT1. By contributing to the elucidation of the mechanism underlying the development of HT1-associated HCC, and providing evidence for the development of a mutator phenotype, the results presented in this thesis contributes to the understanding of the molecular mechanisms underlying the genetic mosaicism in HT1. In addition to these contributions, a hypothesis is posited, which suggests that a point mutation instability (PIN) mutator phenotype is the mechanism underlying the mutation reversions seen in HT1. / Thesis (Ph.D. (Biochemistry))--North-West University, Potchefstroom Campus, 2012

Hereditary tyrosinemia type1

Mosaicism

Hepatocellular carcinoma

DNA repair

Genome instability

Mutator phenotype