Engineering an improved adenovirus packaging cell line

Recombinant human adenovirus (Ad) vectors are being extensively explored for their use in gene therapy and recombinant vaccines. Ad vectors are attractive for many reasons, including the fact that (1) they are relatively safe, based on their use as live oral vaccines, (2) they can accept large transgene inserts, (3) they can infect dividing and postmitotic cells, and (4) they can be produced to high titers. However, there are also a number of major problems associated with Ad vectors, including transient foreign gene expression due to host cellular immune responses, problems with humoral immunity, and the creation of replication competent adenoviruses (RCA). Most Ad vectors contain deletions in the E1 region that allow for insertion of a transgene. However, the E1 gene products are required for replication and thus must be supplied in trans by a helper ceillille that will allow for the growth and packaging of the defective virus. For this purpose the 293 cell line (Graham et al., 1977) is used most often; however, homologous recombination between the vector and the cell line often results in the generation of RCA. The presence of RCA in batches of adenoviral vectors for clinical use is a safety risk because tlley . may result in the mobilization and spread of the replication-defective vector viruses, and in significant tissue damage and pathogenicity. The present research focused on the alteration of the 293 cell line such that RCA formation can be eliminated. The strategy to modify the 293 cells involved the removal of the first 380 bp of the adenovirus genome through the process of homologous recombination. The first step towards this goal involved identifying and cloning the left-end cellular-viral jUl1ction from 293 cells to assemble sequences required for homologous recombination. Polymerase chain reaction (PCR) was performed to clone the junction, and the clone was verified through sequencing. The plasn1id PAM2 was then constructed, which served as the targeting cassette used to modify the 293 cells. The cassette consisted of (1) the cellular-viral junction as the left-end region of homology, (2) the neo gene to use for positive selection upon tranfection into 293 cells, (3) the adenoviral genome from bp 380 to bp 3438 as the right-end region of homology, and (4) the HSV-tk gene to use for negative selection. The plasmid PAM2 was linearized to produce a double strand break outside the region of homology, and transfected into 293 cells using the calcium-phosphate technique. Cells were first selected for their resistance to the drug G418, and subsequently for their resistance to the drug Gancyclovir (GANC). From 17 transfections, 100 pools of G418f and GANCf cells were picked using cloning lings and expanded for screening. Genomic DNA was isolated from the pools and screened for the presence of the 380 bps using PCR. Ten of the most promising pools were diluted to single cells and expanded in order to isolate homogeneous cell lines. From these, an additional 100 G41Sf and GANef foci were screened. These preliminary screening results appear promising for the detection of the desired cell line. Future work would include further cloning and purification of the promising cell lines that have potentially undergone homologous recombination, in order to isolate a homogeneous cell line of interest.

Un rôle pour les protéines de la famille Whirly dans le maintien de la stabilité du génome des organelles chez Arabidopsis thaliana

Le maintien de la stabilité du génome est essentiel pour la propagation de l’information génétique et pour la croissance et la survie des cellules. Tous les organismes possèdent des systèmes de prévention des dommages et des réarrangements de l’ADN et nos connaissances sur ces processus découlent principalement de l’étude des génomes bactériens et nucléaires. Comparativement peu de choses sont connues sur les systèmes de protection des génomes d’organelles. Cette étude révèle l’importance des protéines liant l’ADN simple-brin de la famille Whirly dans le maintien de la stabilité du génome des organelles de plantes. Nous rapportons que les Whirlies sont requis pour la stabilité du génome plastidique chez Arabidopsis thaliana et Zea mays. L’absence des Whirlies plastidiques favorise une accumulation de molécules rearrangées produites par recombinaison non-homologue médiée par des régions de microhomologie. Ce mécanisme est similaire au “microhomology-mediated break-induced replication” (MMBIR) retrouvé chez les bactéries, la levure et l’humain. Nous montrons également que les organelles de plantes peuvent réparer les bris double-brin en utilisant une voie semblable au MMBIR. La délétion de différents membres de la famille Whirly entraîne une accumulation importante de réarrangements dans le génome des organelles suite à l’induction de bris double-brin. Ces résultats indiquent que les Whirlies sont aussi importants pour la réparation fidèle des génomes d’organelles. En se basant sur des données biologiques et structurales, nous proposons un modèle où les Whirlies modulent la disponibilité de l’ADN simple-brin, régulant ainsi le choix des voies de réparation et permettant le maintien de la stabilité du génome des organelles. Les divers aspects de ce modèle seront testés au cours d’expériences futures ce qui mènera à une meilleure compréhension du maintien de la stabilité du génome des organelles.

Identification et caractérisation de facteurs impliqués dans la réplication et la stabilité des génomes des organelles de plantes

Comparativement au génome contenu dans le noyau de la cellule de plante, nos connaissances des génomes des deux organelles de cette cellule, soit le plastide et la mitochondrie, sont encore très limitées. En effet, un nombre très restreint de facteurs impliqués dans la réplication et la réparation de l’ADN de ces compartiments ont été identifiés à ce jour. Au cours de notre étude, nous avons démontré l’implication de la famille de protéines Whirly dans le maintien de la stabilité des génomes des organelles. Des plantes mutantes pour des gènes Whirly chez Arabidopsis thaliana et Zea mays montrent en effet une augmentation du nombre de molécules d’ADN réarrangées dans les plastides. Ces nouvelles molécules sont le résultat d’une forme de recombinaison illégitime nommée microhomology-mediated break-induced replication qui, en temps normal, se produit rarement dans le plastide. Chez un mutant d’Arabidopsis ne possédant plus de protéines Whirly dans les plastides, ces molécules d’ADN peuvent même être amplifiées jusqu’à cinquante fois par rapport au niveau de l’ADN sauvage et causer un phénotype de variégation. L’étude des mutants des gènes Whirly a mené à la mise au point d’un test de sensibilité à un antibiotique, la ciprofloxacine, qui cause des bris double brin spécifiquement au niveau de l’ADN des organelles. Le mutant d’Arabidopsis ne contenant plus de protéines Whirly dans les plastides est plus sensible à ce stress que la plante sauvage. L’agent chimique induit en effet une augmentation du nombre de réarrangements dans le génome du plastide. Bien qu’un autre mutant ne possédant plus de protéines Whirly dans les mitochondries ne soit pas plus sensible à la ciprofloxacine, on retrouve néanmoins plus de réarrangements dans son ADN mitochondrial que dans celui de la plante sauvage. Ces résultats suggèrent donc une implication pour les protéines Whirly dans la réparation des bris double brin de l’ADN des organelles de plantes. Notre étude de la stabilité des génomes des organelles a ensuite conduit à la famille des protéines homologues des polymérases de l’ADN de type I bactérienne. Plusieurs groupes ont en effet suggéré que ces enzymes étaient responsables de la synthèse de l’ADN dans les plastides et les mitochondries. Nous avons apporté la preuve génétique de ce lien grâce à des mutants des deux gènes PolI d’Arabidopsis, qui encodent des protéines hautement similaires. La mutation simultanée des deux gènes est létale et les simples mutants possèdent moins d’ADN dans les organelles des plantes en bas âge, confirmant leur implication dans la réplication de l’ADN. De plus, les mutants du gène PolIB, mais non ceux de PolIA, sont hypersensibles à la ciprofloxacine, suggérant une fonction dans la réparation des bris de l’ADN. En accord avec ce résultat, la mutation combinée du gène PolIB et des gènes des protéines Whirly du plastide produit des plantes avec un phénotype très sévère. En définitive, l’identification de deux nouveaux facteurs impliqués dans le métabolisme de l’ADN des organelles nous permet de proposer un modèle simple pour le maintien de ces deux génomes.

The role of ubiquitination and deubiquitination in the regulation of BRCA1 function during genotoxic stress

BRCA1 est un suppresseur de tumeur majeur jouant un rôle dans la transcription, la réparation de l’ADN et le maintien de la stabilité génomique. En effet, des mutations dans le gène BRCA1 augmentent considerablement le risque de cancers du sein et de l’ovaire. BRCA1 a été en majorité caractérisé pour son rôle dans la réparation de l’ADN par la voie de recombinaison homologue (HR) en présence de bris double brins, par example, induits par l’irradiation gamma (IR). Cependant, la fonction de BRCA1 dans d’autres voies de réparation de l’ADN, comme la réparation par excision de nucléotides (NER) ou par excision de base (BER), demeurent toutefois obscures. Il est donc important de comprendre la régulation de BRCA1 en présence d’agents génotoxiques comme le méthyle méthanesulfonate (MMS) ou l’UV, qui promouvoient le BER et le NER respectivement. Nos observations suggèrent que BRCA1 est dégradée par le protéasome après traitement avec le MMS ou les UV, et non avec l’IR. Par ailleurs, cette dégradation semble compromettre le recrutement de Rad51, suggérant que la voie de HR est inhibée. Nos résultats suggèrent que la HR est inhibée afin d’éviter l’activation simultanée de multiples voies de réparation. Nous avons aussi observé que la dégradation BRCA1 est réversible et que la restauration des niveaux de BRCA1 coïncide avec le recrutement de Rad51 aux sites de dommages. Cela suggère que la HR est réactivée tardivement par les bris double brins générés suite à l’effondrement des fourches de réplication. Ayant observé que BRCA1 est hautement régulé par l’ubiquitination et est ciblé par le protéasome pour dégradation, nous avons émis une hypothèse que BRCA1 est régulé par des déubiquitinases. Cela amène à caractériser plus en profondeur par un criblage en déplétant les déubiquitinases individuellement par RNAi et en observant leur effet sur le recrutement de BRCA1 et des protéines reliées à cette voie. Un criblage préliminaire nous a permi d’identifié candidats potentiels tel que BAP1, CXORF53, DUB3, OTUB1 et USP36.

Étude du rôle de la phosphorylation du complexe Mre11-Rad50-Xrs2 dans le maintien de l'intégrité génomique

L'ADN de chaque cellule est constamment soumis à des stress pouvant compromettre son intégrité. Les bris double-brins sont probablement les dommages les plus nocifs pour la cellule et peuvent être des sources de réarrangements chromosomiques majeurs et mener au cancer s’ils sont mal réparés. La recombinaison homologue et la jonction d’extrémités non-homologues (JENH) sont deux voies fondamentalement différentes utilisées pour réparer ce type de dommage. Or, les mécanismes régulant le choix entre ces deux voies pour la réparation des bris double-brins demeurent nébuleux. Le complexe Mre11-Rad50-Xrs2 (MRX) est le premier acteur à être recruté à ce type de bris où il contribue à la réparation par recombinaison homologue ou JENH. À l’intersection de ces deux voies, il est donc idéalement placé pour orienter le choix de réparation. Ce mémoire met en lumière deux systèmes distincts de phosphorylation du complexe MRX régulant spécifiquement le JENH. L’un dépend de la progression du cycle cellulaire et inhibe le JENH, tandis que l’autre requiert la présence de dommages à l’ADN et est nécessaire au JENH. Ensembles, nos résultats suggèrent que le complexe MRX intègre différents phospho-stimuli pour réguler le choix de la voie de réparation.

The role of double-stranded break repair in the creation of phenotypic diversity at cereal VRN1 loci

Nonhomologous repair of double-stranded breaks, although fundamental to the maintenance of genomic integrity in all eukaryotes, has received little attention as to its evolutionary consequences in the generation and selection of phenotypic diversity. Here we document the role of illegitimate recombination in the creation of novel alleles in VRN1 orthologs selected to confer adaptation to annual cropping systems in barley and wheat.

Análise da Expressão de APE1 após Estresse Oxidativo Induzido em Células Proficientes e Deficientes na Via de Reparo por Excisão de Nucleotídeos

Riboflavin is a vitamin very important in aerobic organisms, as a precursor of many coenzymes involved in the electron transporter chain. However, after photosensitization of riboflavin with UV or visible light, it generates reactive oxygen species (ROS), which can oxidize the DNA. The repair of oxidative lesions on DNA occurs through the base excision repair pathway (BER), where APE1 endonuclease plays a central role. On the other hand, the nucleotide excision repair pathway (NER) repairs helix-distorting lesions. Recently, it was described the participation of NERproteins in the repair of oxidative damage and in stimulation of repair function fromAPE1. The aim of this research was to evaluate the cytotoxic effects of photosensitized riboflavin (RF*) in cells proficient and deficient in NER, correlating with APE1 expression. For this propose, the cells were treated with RF* and it was performed the cell viability assay, extraction of whole proteins, cells fractionation, immunoblotting, indirect immunofluorescence and analysis of polymorphisms of BER gens. The results evidenced that cells deficient in XPA and CSB proteins were more sensitive to RF*. However, XPC-deficient cells presented similar resistance to MRC5- SV cells, which is proficient in NER. These results indicate that XPA and CSB proteins have an important role on repair of oxidative lesions induced by RF*. Additionally, it was evidenced that single nucleotide polymorphisms (SNPs) in BER enzymes may influence in sensitivity of NER-deficient cell lines. Concerning the APE1 expression, the results showed that expression of this protein after treatment with RF* only changed in XPC-deficient cells. Though, it was observed that APE1 is recruited and is bound to chromatin in MRC5-SV and XPA cells after treatment with RF*. The results also showed the induction of DNA damage after treatment with RF*, through the analysis of-H2AX, since the treatment promoted an increase of endogenous levels of this phosphorylated protein, which acts signaling double strand-break on DNA. On the other hand, in XPC-deficient cells, regardless of resistance of RF*, the endogenous levels of APE1 are extremely reduced when compared with other cell lines and APE1 is not bound to chromatin after treatment with RF*. These results conclude that RF* was able to induce cell death in NERdeficient cells, where XPA and CSB cells were more sensitive when compared with MRC5-SV and XPC-deficient cells. This last result is potentially very interesting, since XPC-deficient cell line presents low levels of APE1. Additionally, the results evidenced that APE1 protein can be involved in the repair of oxidative damage induced by RF*, because APE1 is recruited and bound strongly to chromatin after treatment.

Chromosomal aberrations induced by 5-azacytidine combined with VP-16 (etoposide) in CHO-K1 and XRS-5 cell lines

A cytogenetic study was carried out with 5-azacytidine (5-azaC) and etoposide (VP-16) in CHO-K1 and XRS-5 (mutant cells deficient for double-strand break rejoining) cell lines to verify the interaction effects of the drugs in terms of induction of chromosomal aberrations. 5-azaC is incorporated into DNA causing DNA hypomethylation, and VP-16 (inhibitor of topoisomerase 11 enzyme) is a potent clastogenic agent. Cells in exponential growth were treated with 5-azaC for I h, following incubation for 7 h, and posttreatment with VP16 for the last 3 h. In K1 cells, the combined treatments induced a significant reduction in the aberrations induced in the X and A (autosome) chromosomes, which are the main target for 5-azaC. However, in XRS-5 cells, the drug combination caused a significant increase in the aberrations induced in those chromosomes, but with a concomitant reduction in the randomly induced-aberrations. In addition, each cell line presented characteristic cell cycle kinetics; while the combined treatment induced an S-arrest in K1 cells, alterations in cell cycle progression were not found for XRS-5, although each drug alone caused a G2-arrest. The different cell responses presented by the cell lines may be explained on the basis of the evidence that alterations in chromatin structure caused by 5-aza-C probably occur to a different extent in K1 and XRS-5 cells, since the mutant cells present a typical hyper-condensed chromosome structure (especially the X- and A chromosomes), but, alternatively, 5-aza-C could induce reactivation of DNA repair genes in XRS-5 cells. Teratogenesis Carcinog. Mutagen. Suppl. 1:171-186, 2003. (C) 2003 Wiley-Liss, Inc.

Whydration effects on DNA double helix stability modulates ligand binding to natural DNA in response to changes in water activity

In this work we present evidence that water molecules are actively involved on the control of binding affinity and binding site discrimination of a drug to natural DNA. In a previous study, the effect of water activity (a(w)) on the energetic parameters of actinomycin-D intercalation to natural DNA was determined using the osmotic stress method (39). This earlier study has shown evidence that water molecules act as an allosteric regulator of ligand binding to DNA via the effect of water activity on the long-range stability of the DNA secondary structure. In this work we have carried out DNA circularization experiments using the plasmid pUC18 in the absence of drugs and in the presence of different neutral solutes to evaluate the contribution of water activity to the energetics of DNA helix unwinding. The contribution of water to these independent reactions were made explicit by the description of how the changes in the free energy of ligand binding to DNA and in the free energy associated with DNA helix torsional deformation are linked to a(w) via changes in structural hydration. Taken together, the results of these studies reveal an extensive linkage between ligand binding affinity and site binding discrimination, and long range helix conformational changes and DNA hydration, This is strong evidence that water molecules work as a classical allosteric regulator of ligand binding to the DNA via its contribution to the stability of the double helix secondary structure, suggesting a possible mechanism by which the biochemical machinery of DNA processing takes advantage of the low activity of water into the cellular milieu.

Group I Introns and Homing Endonucleases in T-even-like Bacteriophages

Homing endonucleases are rare-cutting enzymes that cleave DNA at a site near their own location, preferentially in alleles lacking the homing endonuclease gene (HEG). By cleaving HEG-less alleles the homing endonuclease can mediate the transfer of its own gene to the cleaved site via a process called homing, involving double strand break repair. Via homing, HEGs are efficiently transferred into new genomes when horizontal exchange of DNA occurs between organisms. Group I introns are intervening sequences that can catalyse their own excision from the unprocessed transcript without the need of any proteins. They are widespread, occurring both in eukaryotes and prokaryotes and in their viruses. Many group I introns encode a HEG within them that confers mobility also to the intron and mediates the combined transfer of the intron/HEG to intronless alleles via homing. Bacteriophage T4 contains three such group I introns and at least 12 freestanding HEGs in its genome. The majority of phages besides T4 do not contain any introns, and freestanding HEGs are also scarcely represented among other phages. In the first paper we looked into why group I introns are so rare in phages related to T4 in spite of the fact that they can spread between phages via homing. We have identified the first phage besides T4 that contains all three T-even introns and also shown that homing of at least one of the introns has occurred recently between some of the phages in Nature. We also show that intron homing can be highly efficient between related phages if two phages infect the same bacterium but that there also exists counteracting mechanisms that can restrict the spread of introns between phages. In the second paper we have looked at how the presence of introns can affect gene expression in the phage. We find that the efficiency of splicing can be affected by variation of translation of the upstream exon for all three introns in T4. Furthermore, we find that splicing is also compromised upon infection of stationary-phase bacteria. This is the first time that the efficiency of self-splicing of group I introns has been coupled to environmental conditions and the potential effect of this on phage viability is discussed. In the third paper we have characterised two novel freestanding homing endonucleases that in some T-even-like phages replace two of the putative HEGs in T4. We also present a new theory on why it is a selective advantage for freestanding, phage homing endonucleases to cleave both HEG-containing and HEG-less genomes.

Combined low initial DNA damage and high radiation-induced apoptosis confers clinical resistance to long-term toxicity in breast cancer patients treated with high-dose radiotherapy

[EN] Background: Either higher levels of initial DNA damage or lower levels of radiation-induced apoptosis in peripheral blood lymphocytes have been associated to increased risk for develop late radiation-induced toxicity. It has been recently published that these two predictive tests are inversely related. The aim of the present study was to investigate the combined role of both tests in relation to clinical radiation-induced toxicity in a set of breast cancer patients treated with high dose hyperfractionated radical radiotherapy. Methods: Peripheral blood lymphocytes were taken from 26 consecutive patients with locally advanced breast carcinoma treated with high-dose hyperfractioned radical radiotherapy. Acute and late cutaneous and subcutaneous toxicity was evaluated using the Radiation Therapy Oncology Group morbidity scoring schema. The mean follow-up of survivors (n = 13) was 197.23 months. Radiosensitivity of lymphocytes was quantified as the initial number of DNA double-strand breaks induced per Gy and per DNA unit (200 Mbp). Radiation-induced apoptosis (RIA) at 1, 2 and 8 Gy was measured by flow cytometry using annexin V/propidium iodide. Results: Mean DSB/Gy/DNA unit obtained was 1.70 ± 0.83 (range 0.63-4.08; median, 1.46). Radiation-induced apoptosis increased with radiation dose (median 12.36, 17.79 and 24.83 for 1, 2, and 8 Gy respectively). We observed that those "expected resistant patients" (DSB values lower than 1.78 DSB/Gy per 200 Mbp and RIA values over 9.58, 14.40 or 24.83 for 1, 2 and 8 Gy respectively) were at low risk of suffer severe subcutaneous late toxicity (HR 0.223, 95%CI 0.073-0.678, P = 0.008; HR 0.206, 95%CI 0.063-0.677, P = 0.009; HR 0.239, 95%CI 0.062-0.929, P = 0.039, for RIA at 1, 2 and 8 Gy respectively) in multivariate analysis. Conclusions: A radiation-resistant profile is proposed, where those patients who presented lower levels of initial DNA damage and higher levels of radiation induced apoptosis were at low risk of suffer severe subcutaneous late toxicity after clinical treatment at high radiation doses in our series. However, due to the small sample size, other prospective studies with higher number of patients are needed to validate these results.

Radiation induced apoptosis and initial DNA damage are inversely related in locally advanced breast cancer patients

[EN] Background: DNA-damage assays, quantifying the initial number of DNA double-strand breaks induced by radiation, have been proposed as a predictive test for radiation-induced toxicity. Determination of radiation-induced apoptosis in peripheral blood lymphocytes by flow cytometry analysis has also been proposed as an approach for predicting normal tissue responses following radiotherapy. The aim of the present study was to explore the association between initial DNA damage, estimated by the number of double-strand breaks induced by a given radiation dose, and the radio-induced apoptosis rates observed. Methods: Peripheral blood lymphocytes were taken from 26 consecutive patients with locally advanced breast carcinoma. Radiosensitivity of lymphocytes was quantified as the initial number of DNA double-strand breaks induced per Gy and per DNA unit (200 Mbp). Radio-induced apoptosis at 1, 2 and 8 Gy was measured by flow cytometry using annexin V/propidium iodide. Results: Radiation-induced apoptosis increased in order to radiation dose and data fitted to a semi logarithmic mathematical model. A positive correlation was found among radio-induced apoptosis values at different radiation doses: 1, 2 and 8 Gy (p < 0.0001 in all cases). Mean DSB/Gy/DNA unit obtained was 1.70 ± 0.83 (range 0.63-4.08; median, 1.46). A statistically significant inverse correlation was found between initial damage to DNA and radio-induced apoptosis at 1 Gy (p = 0.034). A trend toward 2 Gy (p = 0.057) and 8 Gy (p = 0.067) was observed after 24 hours of incubation. Conclusions: An inverse association was observed for the first time between these variables, both considered as predictive factors to radiation toxicity.

DNA-Doppelstrangbrüche als zentrales Ereignis alkylierungsinduzierter Zytotoxizität

DNA-Doppelstrangbrüche als zentrales Ereignis alkylierungsinduzierter Zytotoxizität Die vorliegende Arbeit befaßt sich mit der Entstehung von DNA-Doppelstrangbrüchen durch gentoxische Agenzien sowie den zytotoxischen Auswirkungen, die DNA-Doppelstrangbrüche für die Säuger-Zelle haben. Im ersten Teil der Arbeit wurden die molekularen Mechanismen untersucht, die am O6-Methylguanin (O6-MeG)-DNA-Schaden, hervorgerufen durch alkylierende Agenzien, ablaufen. Dabei konnte gezeigt werden, das O6-Methylguanin DNA-Methyltransferase (MGMT) O6-MeG/C und O6-MeG/T in vitro mit gleicher Effizienz repariert und daß die Reparatur von O6-MeG nach dem ersten Zellzyklus protektive Auswirkung auf das zelluläre Überleben hat. Im zweiten Teil der vorliegenden Arbeit stand die Induktion von DNA-Doppelstrangbrüchen durch gentoxische Agenzien in Mausfibroblasten und CHO-Zellen im Mittelpunkt. Mit Hilfe der Einzelzellgelelektrophorese (SCGE, Comet Assay) wurde gezeigt, daß alkylierende Substanzen und die durch Elektroporation in Zellen hineingebrachten Restriktionsenzyme PvuII und EcoRI DNA-Doppelstrangbrüche zu induzieren vermögen. Die Induktion und Reparatur von DNA-Doppelstrangbrüchen nach Elektroporation von PvuII war vom p53-Status der Zellen abhängig, da p53-defiziente Zellen im Gegensatz zu p53-profizienten Zellen höhere DNA-Doppelstrangbruchraten über einen längeren Zeitraum aufwiesen. Im dritten Teil wurden die physiologischen Auswirkungen einer Behandlung von Zellen mit Induktoren von DNA-Doppelstrangbrüchen untersucht. Es wurde gezeigt, daß Alkylanzien in Abhängigkeit vom Vorhandensein von MGMT Apoptose induzieren. Mit PvuII elektroporierte p53-knockout Mausfibroblasten zeigten infolgedessen und im Gegensatz zu p53-wildtyp Zellen hohe Apoptoseraten. Die Induktion der Apoptose nach Behandlung mit PvuII wie auch nach g-Bestrahlung ging einher mit einem Abfall der Proteinmenge des antiapoptotischen Bcl-2. Zusammengenommen weisen die Versuchsergebnisse dieser Arbeit darauf hin, daß nach Behandlung von Zellen mit O6-MeG-generierenden Agenzien wie auch nach g-Bestrahlung DNA-Doppelstrangbrüche das ultimative Signal darstellen können.