Characterisation and mutation spectrum analysis of a novel chinese hamster cell line

Godfrey, Tony Edward

January 1993

No description available.

610

DNA damaging agents; Skin cancer

The Isolation of Natural Products From Plant Extracts

Pung, Thitiya

13 July 2000

Bioassay-guided fractionation of the ethyl acetate extract of Virola sp. (Myristicaceae) using the Sc7 yeast strain resulted in the isolation of the weakly cytotoxic biochanin A (an isoflavone compound). The bioassay of three mutant yeast strains (1138, 1104, and 1353) directed the isolation of DNA-damaging alkaloids from Solanum hostmannii. These alkaloids were identified as verazine and (20R) epimer verazine. In addition, three oxoaporphine alkaloids were isolated from the bark of Papualthia sp. (Annonaceae). Oxocrebanine and atherospermidine showed DNA-damaging activity whereas liriodenine had cytotoxic activity. / Master of Science

oxoaporphine

verazines

natural product

biochanin A

DNA-damaging agents

Chemically Induced DNA Damage in Extended-term Cultures of Human Lymphocytes

Andersson, Maria

January 2006

<p>Generation of DNA damage is regarded to be an important initial event in the development cancer. Consequently, a battery of tests have been developed to detect different types of genotoxic effects in order to be able to predict the potential genotoxicity and mutagenicity of chemicals, including both pharmaceutical drugs and various types of environmental and occupational agents, as well as dietary factors. The aim of this thesis was to evaluate whether the combination of the comet assay and the extended-term cultures of human lymphocytes (ETC) can be used as an alternative <i>in vitro</i> system to more commonly used transformed mammalian cell lines, and primary cell cultures from humans, when testing the potential genotoxicity of chemicals. </p><p>Using the comet assay, a panel of reference compounds showed that the ETC were found to detect the DNA-damaging effects with no remarkable difference to what has been reported in other cell types. Moreover, in comparison with a well-established rodent cell line, the mouse lymphoma L5178Y cells, the ETC showed similar sensitivity to the DNA damaging effects of the genotoxic agents hydrogen peroxide and catechol. Although there was an interindividual variation in induced DNA damage and the subsequent repair when using ETC from different blood donors, it did not seem to be of crucial importance for the identification of DNA-damaging agents. The demonstrated difference in sensitivity to catechol-induced DNA damage between freshly isolated peripheral lymphocytes and ETC may very well be due to their different proliferative status but despite this difference, both <i>in vitro</i> systems were able to identify catechol as a DNA-damaging agent at the same concentration.</p><p>Based on these results, it is proposed that the ETC and the comet assay are a useful combination when testing for the potential DNA damaging effects of chemicals. Representing easily cultivated cells possessing the normal human karyotype, where one blood sample can be used for numerous experiments performed over a long time, extended-term cultures appear to be a useful alternative, both to transformed mammalian cell lines, and primary cell cultures from humans. In fact, the extended-term lymphocytes, with or without S9 and/or lesion specific DNA repair enzymes, should be used more frequently when screening for the potential genotoxicity of chemicals.</p>

Toxicology

Comet assay

DNA-damaging agents

DNA repair

Genotoxicity

Induced DNA damage

In vitro

Mouse Lymphoma Cells

Primary Cell Cultures

Reactive Oxygen Species

Toxikologi

Chemically Induced DNA Damage in Extended-term Cultures of Human Lymphocytes

Andersson, Maria

January 2006

Generation of DNA damage is regarded to be an important initial event in the development cancer. Consequently, a battery of tests have been developed to detect different types of genotoxic effects in order to be able to predict the potential genotoxicity and mutagenicity of chemicals, including both pharmaceutical drugs and various types of environmental and occupational agents, as well as dietary factors. The aim of this thesis was to evaluate whether the combination of the comet assay and the extended-term cultures of human lymphocytes (ETC) can be used as an alternative in vitro system to more commonly used transformed mammalian cell lines, and primary cell cultures from humans, when testing the potential genotoxicity of chemicals. Using the comet assay, a panel of reference compounds showed that the ETC were found to detect the DNA-damaging effects with no remarkable difference to what has been reported in other cell types. Moreover, in comparison with a well-established rodent cell line, the mouse lymphoma L5178Y cells, the ETC showed similar sensitivity to the DNA damaging effects of the genotoxic agents hydrogen peroxide and catechol. Although there was an interindividual variation in induced DNA damage and the subsequent repair when using ETC from different blood donors, it did not seem to be of crucial importance for the identification of DNA-damaging agents. The demonstrated difference in sensitivity to catechol-induced DNA damage between freshly isolated peripheral lymphocytes and ETC may very well be due to their different proliferative status but despite this difference, both in vitro systems were able to identify catechol as a DNA-damaging agent at the same concentration. Based on these results, it is proposed that the ETC and the comet assay are a useful combination when testing for the potential DNA damaging effects of chemicals. Representing easily cultivated cells possessing the normal human karyotype, where one blood sample can be used for numerous experiments performed over a long time, extended-term cultures appear to be a useful alternative, both to transformed mammalian cell lines, and primary cell cultures from humans. In fact, the extended-term lymphocytes, with or without S9 and/or lesion specific DNA repair enzymes, should be used more frequently when screening for the potential genotoxicity of chemicals.

Toxicology

Comet assay

DNA-damaging agents

DNA repair

Genotoxicity

Induced DNA damage

In vitro

Mouse Lymphoma Cells

Primary Cell Cultures

Reactive Oxygen Species

Toxikologi

The in vivo characterization of the DNA repair gene apn-1 in the model organism Caenorhabditis elegans

Zakaria, Chadi

08 1900

Les sites apuriniques/apyrimidinique (AP) représentent une forme de dommage à l’ADN hautement mutagène et ce type de dommage peut survenir spontanément ou être induit par une variété d’agents. Afin de préserver la stabilité génomique, deux familles d’endonucléases de type AP, endo-IV et exo-III, sont nécessaires pour contrecarrer les effets mutagènes des sites AP. Malgré l’identification de membres des deux familles dans plusieurs organismes unicellulaire tels que E.coli et S. cerevisiae, aucun membre de la famille endo-IV n’a été identifié chez les organismes multicellulaires à l’exception de C. elegans et de C. briggsae. Nous avons donc décidé d’investiguer l’importance biologique de APN-1 chez C. elegans par l’utilisation d’une approche de knockdown du gène. Dans notre étude, nous avons montré que le knockdown du gène apn-1 chez C. elegans, en utilisant des ARN d’interférence (ARNi), cause une accumulation de mutations spontanées et induites par des drogues résultant en un délai de l’éclosion des œufs ainsi que par une diminution de la survie et de la longévité des vers adultes. De plus, nous avons montré que cette accumulation de mutations mène à un délai dans la progression du cycle cellulaire durant l’embryogénèse, représentant possiblement une explication du délai dans l’éclosion des œufs. Nous avons montré qu’il y avait une augmentation du niveau de mutations dans la gorge des vers, sans toutefois pouvoir confirmer la distribution de APN-1 qui possède une étiquette GFP. Les animaux transgéniques APN-1-GFP n’exprimaient pas suffisamment de la protéine de fusion pour permettre une visualisation à l’aide d’un microscope à fluorescence, mais la protéine a été détectée par immunobuvardage de type western. Les animaux transgéniques APN-1-GFP étaient instables et avaient des phénotypes concordants avec les défauts génétiques. En conclusion, il semble que C. elegans aie évolué afin de retenir un niveau de base de APN-1 jouant ainsi un rôle versatile afin de maintenir l’intégrité génétique d’autant plus que cet organisme semble manquer plusieurs enzymes de la voie de réparation par excision de base. / Apurinic/apyrimidinic (AP) sites are a form of highly mutagenic DNA damage that arise either spontaneously or by a variety of DNA damaging agents. To preserve genomic stability two AP endonuclease families, endo-IV and exo-III, evolved to counteract the mutagenic effect of AP sites. While members of both families were identified in multiple unicellular organisms, notably E. coli and S. cerevisiae, no members of the endo-IV family were identified in multicellular ones, with the exception of C. elegans and its close relatives, particularly C. briggsae. We set out to investigate the biological importance of APN-1 in C. elegans using gene knockdown approach. In our study, we showed that the knockdown of C. elegans apn-1 gene, using RNAi causes the accumulation of spontaneous and drug induced mutations, resulting in a delay in egg hatching, decreased survival and longevity. Furthermore, we have showed that the accumulated mutations lead to delays in cell cycle progression during early embryogenesis, thus providing a possible explanation for the observed delay in hatching. Although we showed increased mutations in the gut of the worm, we were unable to confirm APN-1 distribution tagged with GFP. The transgenic APN-1-GFP animal did not express enough of this fusion protein to be visualized by fluorescent microscopy, although it was detected by Western blot analysis. The transgenic animals over-expressing APN-1-GFP were unstable and showed phenotypes consistent with genetic defects. In conclusion, it would seem that C. elegans has evolved to retain a balanced level of APN-1, which plays a versatile role in maintaining genetic integrity, since this organism lacks a full complement of the enzymes in the base-excision repair pathway.

C. elegans

Endo IV

Réparation par excision de base

Site AP

Endonucléase de type AP

Stress oxidatif

Agents causant des dommages à l’ADN

Réparation de l’ADN

C. elegans

Endo IV

Base excision repair

AP site

AP endonuclease

Oxidative stress

DNA damaging agents

DNA repair

The in vivo characterization of the DNA repair gene apn-1 in the model organism Caenorhabditis elegans

Zakaria, Chadi

08 1900

Les sites apuriniques/apyrimidinique (AP) représentent une forme de dommage à l’ADN hautement mutagène et ce type de dommage peut survenir spontanément ou être induit par une variété d’agents. Afin de préserver la stabilité génomique, deux familles d’endonucléases de type AP, endo-IV et exo-III, sont nécessaires pour contrecarrer les effets mutagènes des sites AP. Malgré l’identification de membres des deux familles dans plusieurs organismes unicellulaire tels que E.coli et S. cerevisiae, aucun membre de la famille endo-IV n’a été identifié chez les organismes multicellulaires à l’exception de C. elegans et de C. briggsae. Nous avons donc décidé d’investiguer l’importance biologique de APN-1 chez C. elegans par l’utilisation d’une approche de knockdown du gène. Dans notre étude, nous avons montré que le knockdown du gène apn-1 chez C. elegans, en utilisant des ARN d’interférence (ARNi), cause une accumulation de mutations spontanées et induites par des drogues résultant en un délai de l’éclosion des œufs ainsi que par une diminution de la survie et de la longévité des vers adultes. De plus, nous avons montré que cette accumulation de mutations mène à un délai dans la progression du cycle cellulaire durant l’embryogénèse, représentant possiblement une explication du délai dans l’éclosion des œufs. Nous avons montré qu’il y avait une augmentation du niveau de mutations dans la gorge des vers, sans toutefois pouvoir confirmer la distribution de APN-1 qui possède une étiquette GFP. Les animaux transgéniques APN-1-GFP n’exprimaient pas suffisamment de la protéine de fusion pour permettre une visualisation à l’aide d’un microscope à fluorescence, mais la protéine a été détectée par immunobuvardage de type western. Les animaux transgéniques APN-1-GFP étaient instables et avaient des phénotypes concordants avec les défauts génétiques. En conclusion, il semble que C. elegans aie évolué afin de retenir un niveau de base de APN-1 jouant ainsi un rôle versatile afin de maintenir l’intégrité génétique d’autant plus que cet organisme semble manquer plusieurs enzymes de la voie de réparation par excision de base. / Apurinic/apyrimidinic (AP) sites are a form of highly mutagenic DNA damage that arise either spontaneously or by a variety of DNA damaging agents. To preserve genomic stability two AP endonuclease families, endo-IV and exo-III, evolved to counteract the mutagenic effect of AP sites. While members of both families were identified in multiple unicellular organisms, notably E. coli and S. cerevisiae, no members of the endo-IV family were identified in multicellular ones, with the exception of C. elegans and its close relatives, particularly C. briggsae. We set out to investigate the biological importance of APN-1 in C. elegans using gene knockdown approach. In our study, we showed that the knockdown of C. elegans apn-1 gene, using RNAi causes the accumulation of spontaneous and drug induced mutations, resulting in a delay in egg hatching, decreased survival and longevity. Furthermore, we have showed that the accumulated mutations lead to delays in cell cycle progression during early embryogenesis, thus providing a possible explanation for the observed delay in hatching. Although we showed increased mutations in the gut of the worm, we were unable to confirm APN-1 distribution tagged with GFP. The transgenic APN-1-GFP animal did not express enough of this fusion protein to be visualized by fluorescent microscopy, although it was detected by Western blot analysis. The transgenic animals over-expressing APN-1-GFP were unstable and showed phenotypes consistent with genetic defects. In conclusion, it would seem that C. elegans has evolved to retain a balanced level of APN-1, which plays a versatile role in maintaining genetic integrity, since this organism lacks a full complement of the enzymes in the base-excision repair pathway.

C. elegans

Endo IV

Réparation par excision de base

Site AP

Endonucléase de type AP

Stress oxidatif

Agents causant des dommages à l’ADN

Réparation de l’ADN

C. elegans

Endo IV

Base excision repair

AP site

AP endonuclease

Oxidative stress

DNA damaging agents

DNA repair