High-Resolution Mapping of Mitotic Recombination in Saccharomyces Cerevisiae

St. Charles, Jordan Anne

January 2012

<p>Double-stranded DNA breaks are potentially lethal lesions that can be repaired in mitotic cells by either homologous recombination (HR) or non-homologous end- joining (NHEJ) pathways. In the HR pathway, the broken DNA molecule is repaired using either the sister chromatid or the homolog as a template. Mitotic recombination events involving the homolog often result in loss of heterozygosity (LOH) of markers located distal to the crossover. In humans that are heterozygous for a mutation in a tumor suppressor gene, mitotic recombination leading to LOH can be an early step in cancer development.</p><p> In my thesis research, I analyzed mitotic recombination in the yeast Saccharomyces cerevisiae using oligonucleotide-containing microarrays to detect LOH of single-nucleotide polymorphisms (SNPs). In analyzing cells treated with ionizing radiation, I performed the first whole-genome analysis of LOH events done in any organism (Chapter 2). I showed that irradiated cells had between two and three unselected LOH events. I also showed that crossovers were often associated with non- reciprocal exchanges of genetic information (gene conversion events) and that these conversion events were more complex than predicted by standard models of homologous recombination.</p><p> In Chapter 3, I describe my mapping of spontaneous crossovers in a 1.1 Mb region of yeast chromosome IV. This analysis is the first high-resolution mitotic recombination map of a substantial fraction (about 10%) of a eukaryotic genome. I demonstrated the existence of recombination "hotspots" and showed that some of these hotspots were homolog-specific. Two of the strongest hotspots were formed by closely- spaced inverted repeats of retrotransposons. I demonstrated that the hotspot activity was a consequence of a secondary DNA structure formed by these repeats. Additionally, the majority of spontaneous LOH events reflect DNA lesions induced in unreplicated chromosomes during G1 of the cell cycle, indicating that G1-initiated lesions threaten genome stability more than G2-initiated lesions.</p><p> In Chapter 4, I describe mitotic crossovers associated with DNA replication stress induced by hydroxyurea (HU) treatment. Surprisingly, most HU-induced crossovers had conversion tracts indicative of DNA lesions initiated in G1. Additionally, HU- induced recombination events were very significantly associated with solo delta elements, a 330 bp sequence that is repeated several hundred times in the yeast genome.</p> / Dissertation

Pharmacology

Genetics

Mitotic recombination

SNP Microarrays

Yeast

Mapping of UV-Induced Mitotic Recombination in Yeast

Yin, Yi

January 2015

<p>In diploid yeast cells, mitotic recombination is very important for repairing double-strand breaks (DSB). When repair of a DSB results in crossovers, it may cause loss of heterozygosity (LOH) of markers centromere-distal to the DSB in both daughter cells. Gene conversion events unassociated with crossovers cause LOH for an interstitial section of a chromosome. Alternatively, DSBs can initiate break-induced replication (BIR), causing LOH in only one of the daughter cells. Mapping mitotic LOH contributes to understanding of mechanisms for repairing DSBs and distribution of these recombinogenic lesions. Methods for selecting mitotic crossovers and mapping the positions of crossovers have recently been developed in our lab. Our current approach uses a diploid yeast strain that is heterozygous for about 55,000 SNPs, and employs SNP-Microarrays to map LOH events throughout the genome. These methods allow us to examine selected crossovers on chromosome V and unselected mitotic recombination events (crossovers, gene conversion events unassociated with crossovers, and BIR events) at about 1 kb resolution across the genome.</p><p>Mitotic recombination can be greatly induced by UV radiation. However, prior to my research, the nature of the recombinogenic lesions and the distribution of UV-induced recombination events were relatively uncharacterized. Using SNP microarrays, we constructed maps of UV-induced LOH events in G1-synchronized cells. Mitotic crossovers were stimulated 1500-fold and 8500-fold by UV doses of 1 J/m2 and 15 J/m2, respectively, compared to spontaneous events. Additionally, cells treated with 15 J/m2 have about eight unselected LOH events per pair of sectors, including gene conversions associated and unassociated with crossovers as well as BIR events. These unselected LOH events are distributed randomly throughout the genome with no particular hotspots; however, the rDNA cluster was under-represented for the initiation of crossover and BIR events. Interestingly, we found that a high fraction of recombination events in cells treated with 15 J/m2 reflected repair of two sister chromatids broken at roughly the same position. In cells treated with 1 J/m2, most events reflect repair of a single broken sister chromatid (Chapter 2). </p><p>The primary pathway to remove pyrimidine dimers introduced by UV is the nucleotide excision repair (NER) pathway. In NER, the dimer is excised to generate a 30-nucleotide gap that can be replicated to form DSBs if not filled in before DNA replication. The NER gap can also be expanded by Exo1p to form single stranded gaps greater than one kilobase. Alternatively, in the absence of NER, unexcised dimers could result in blocks of DNA replication forks. Resolving the stalled replication fork could lead to recombinogenic breaks. In Chapter 3 and Chapter 4, we analyzed recombination events in strains defective in various steps of processing of UV-induced DNA damage, including exo1 and rad14 mutants. </p><p>In Chapter 3, I show that Exo1p-expanded NER gaps contribute to UV-induced recombination events. Interestingly, I also found that Exo1p is also required for the hotspot activity of a spontaneous crossover hotspot involving a pair of inverted Ty repeats. In addition to its role of expanding a nick to a long single-stranded gap, Exo1p is also a major player in DSB end resection. Therefore, I examined the gene conversion tract lengths in strains deleted for EXO1. I found that, although crossover-associated gene conversion tracts become shorter in the exo1 mutant as expected, noncrossover tract lengths remained unaffected. As a result, noncrossover tracts are longer than crossover tracts in the exo1 mutant while the opposite result was observed in the wild-type strains. I proposed models to rationalize this observation.</p><p>In Chapter 4, to investigate whether the substantial recombinogenic effect in UV in G1-synchronized cells requires NER, we mapped UV-induced LOH events in NER-deficient rad14 diploids treated with 1 J/m2. Mitotic recombination between homologs was greatly stimulated, which suggests that dimers themselves can also cause recombination without processing by NER. We further show that UV-induced inter-homolog recombination events (noncrossover, crossover and BIR) depend on the resolvase Mus81p, and are suppressed by Mms2p-mediated error-free post-replication repair pathway. </p><p>The research described in Chapters, 2, 3, and 4 are in the publications Yin and Petes (2013), Yin and Petes (2014), and Yin and Petes (2015), respectively.</p> / Dissertation

Genetics

Biology

DNA repair

double strand break

loss of heterozygosity

mitotic recombination

S. cerevisiae

ultraviolet light

Mechanistic Roles of Resection Nucleases and DNA Polymerases during Mitotic Recombination in Saccharomyces cerevisiae

Guo, Xiaoge

January 2015

<p>Every living cell faces a multitude of DNA threats in its lifetime because damage to DNA is intrinsic to life itself. A double-strand break (DSB) is the most cytotoxic type of DNA damage and is a potent inducer of chromosomal aberrations. Defects in DSB repair are a major driver of tumorigenesis and are associated with numerous developmental, neurological and immunological disorders. To counteract the deleterious effects of DSBs, organisms have evolved a homologous repair (HR) mechanism that is highly precise. The key to its error-free nature lies in its use of a homologous template in restoring the DSB and its preferential occurrence during late S and G2 phase of the cell cycle when identical sister chromatids are available as templates for repair. However, HR can also engage homologous chromosomes and ectopic substrates that share homology, resulting in mitotic loss-of-heterozygosity (LOH) and unwanted chromosomal aberrations. In this case, understanding of the underlying mechanisms and molecular factors that influence accurate sequence transfer and exchange between two homologous substrates becomes crucial. </p><p>The focus of this dissertation is examination of the genetic factors and molecular processes occurring at early intermediate steps (DNA end resection and DNA synthesis) of mitotic recombination in Saccharomyces cerevisiae. To model DSB repair, we established a unique plasmid-based assay with a small 8-base pair (bp) gap in the middle of an 800-bp plasmid substrate. To delineate the molecular structures of strand exchange intermediates during HR, we used a 2% diverged plasmid substrate relative to a chromosomal repair template to generate mismatch-containing heteroduplex DNA (hetDNA) intermediates. The assay was performed in a mismatch repair (MMR)-defective background allowing hetDNA to persist and to segregate into daughter cells at the next round of replication. Unexpectedly, even when MMR was inactivated, sequence analysis of the recombinants revealed patches of gene conversion and restoration reflecting mismatch correction within hetDNA tracts. We showed that, in this system, MMR and nucleotide excision repair (NER) correct mismatches via two different mechanisms. While mispairing of nucleotides triggers MMR, NER is recruited by the subtle 6-methyladenine mark on the plasmid substrate, leading to coincident correction of mismatches. The methylation marks on the plasmid were acquired from the bacterial host’s native restriction-modification system during plasmid propagation. </p><p>Formation of hetDNA occurs when a plasmid substrate engages the chromosomal template for repair, forming a D-loop intermediate. D-loop extension requires DNA synthesis by DNA polymerase/s. Translesion synthesis (TLS) polymerases have been implicated in HR in both chicken DT40 cells and fruit fly, but not in yeast. This class of polymerases is known for its low fidelity due to a lack of exonuclease domain and is commonly used for lesion bypass and in extending ends with mismatches. We reported for the first time a requirement of Polζ-Rev1 and Polη (TLS polymerases in S. cerevisiae) for completing gap repair. Moreover, gap-repair efficiency suggested that these two polymerases function independently. We concluded that TLS polymerases are involved in either extending the invading 3’ end and/or in the gap-filling process that completes recombination. </p><p>DNA resection of a DSB serves as a primary step to generate a 3’ single-stranded DNA (ssDNA) for subsequent homologous template invasion, but this process has mostly been studied in the absence of a repair template or when downstream HR steps are disabled. To analyze the individual contributions of identified nucleases to DSB resection in the context of repair, we established a chromosomal assay; the substrate size was increased to 4 kilobases (kb) and 85 SNPs were present at ~50 bp intervals. In this chromosomal assay, resection and DNA synthesis influence the length of hetDNA tracts in the final recombinants, allowing these two steps to be analyzed. We specifically focused on synthesis-dependent strand annealing (SDSA) events, where hetDNA reflects DNA synthesis and extent of resection. Our main conclusions are as follows. DNA end resection on the annealing end of NCO products generated by SDSA is not as extensive as one might expect from resection measured in single-strand annealing (SSA) assays. In addition, although the two long-range resection pathways (Sgs1-Dna2 and Exo1) can support recombination in a redundant manner, hetDNA was significantly reduced upon loss of either. End processing of DSBs is predominantly 5’ to 3’, but we also observed loss of sequences (greater than 8 nt but less than 40 nt) at the 3’ termini. We have tested and ruled out the involvement of Mre11 and Polε proofreading activity. Lastly, Pol32 functions as a subunit of Polδ to promote extensive repair synthesis during SDSA. hetDNA tract lengths were significantly shorter in the absence of the Pol32 subunit of Polδ, providing direct evidence that Polδ extends the invading end during HR. Together, this work advances our understanding of how resection nucleases and DNA polymerase/s function to regulate mitotic recombination outcome and influence the molecular patterns of NCOs.</p> / Dissertation

Genetics

DNA polymerase

ectopic HR substrates

hetDNA detection

mitotic recombination

resection

single-molecule sequencing

Análise da variação cariotípica e dos mecanismos de recombinação em leveduras industriais (Saccharomyces cerevisiae) durante o processo de fermentação alcoólica / Analysis of the karyotypic variation and the recombination mechanisms industrial yeast (Saccharomyces cerevisiae) during the alcoholic fermentation process

Duarte, Fabiana de Melo

08 June 2010

Orientador: Gonçalo Amarante Guimarães Pereira, Juan Lucas Argueso Gomes de Almeida / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-16T13:31:37Z (GMT). No. of bitstreams: 1 Duarte_FabianadeMelo_M.pdf: 10932684 bytes, checksum: c31d50d399af1063941a0d931eee8101 (MD5) Previous issue date: 2010 / Resumo: O etanol de cana-de-açúcar brasileiro ocupa um lugar de destaque entre as alternativas energéticas disponíveis atualmente. No processo fermentativo de produção de etanol é utilizada a levedura Saccharomyces cerevisiae, com destaque para a linhagem industrial PE-2, utilizada por cerca de 30% das usinas brasileiras, o que representa 10% da produção mundial. Essa linhagem associa uma alta eficiência na produção de etanol com uma excelente capacidade de adaptação ao ambiente altamente hostil e competitivo das dornas de fermentação. O nosso grupo de pesquisa realizou previamente uma caracterização genética e molecular detalhada de uma linhagem diplóide derivada diretamente de PE-2 (JAY270), o que forneceu inúmeras possibilidades para a manipulação genética dessa levedura com o objetivo de desenvolver linhagens mais produtivas. No entanto, alguns estudos observaram a ocorrência de variação cariotípica nessa linhagem durante o processo fermentativo, o que pode representar uma barreira para a manipulação dessa levedura. Sendo assim, é extremamente importante estudar o comportamento do genoma dessa linhagem durante a produção de etanol. Este projeto de Mestrado teve como objetivo principal a determinação do mecanismo de recombinação genética responsável pela geração de rearranjos cromossômicos na linhagem JAY270 durante a produção de etanol. Foi realizado um experimento de fermentação em escala semi-industrial iniciado com um inóculo puro de JAY270, com duração de 50 dias. A partir de amostras coletadas ao final do processo foram obtidos isolados que foram analisados através de PFGE (Gel de Eletroforese em Campo Pulsado) para identificação de derivados de JAY270 portadores de variação cariotípica. Dos derivados analisados, 36% possuíam algum tipo de rearranjo cromossômico em relação à linhagem inicial, dos quais 11 foram selecionados (FDY1-FDY11) para análises detalhadas. As sequências genômicas de dois derivados haplóides de JAY270 possibilitaram o desenvolvimento de 9 marcadores moleculares para genotipar regiões heterozigotas de JAY270 com o objetivo de identificar eventos de recombinação genética. Os 11 isolados selecionados foram analisados com esses marcadores e, exceto por um deles, todos continuavam heterozigotos em todas as regiões genotipadas. Dois mecanismos de recombinação genética podem ser responsáveis pela geração dos rearranjos, recombinação mitótica, que ocorre em pontos isolados e recombinação meiótica, que envolve todo o genoma simultaneamente em um único ciclo celular. A possibilidade dos rearranjos terem sido gerados por recombinação meiótica foi excluída, visto que a probabilidade dos 10 isolados continuarem heterozigotos em todas as regiões analisadas após um evento de meiose seguido de cruzamento é extremamente baixa (entre 10-24 e 10-14). Sendo assim, concluiu-se que os rearranjos cromossômicos foram gerados durante o crescimento vegetativo, e que, portanto, o mecanismo de recombinação genética responsável pela geração dos mesmos é a recombinação mitótica. Os 11 isolados também foram analisados através de CGH-array, que possibilitou a comparação de sua dosagem gênica com a da linhagem JAY270, que lhes deu origem. Com essa metodologia foi possível detectar eventos de recombinação mitótica que resultaram em perda de heterozigosidade nas extremidades de alguns cromossomos. / Abstract: Brazilian sugar cane ethanol stands out among the energetic alternatives available nowadays. In the fermentation process to produce ethanol it is used the yeast Saccharomyces cerevisiae. One of the most widely adopted strains is the industrial isolate PE-2, currently used by ~30% of Brazilian distilleries, generating ~10% of the world's ethanol supply. This strain combines a high performance in ethanol fermentation and an excellent adaptation to the hostile environment in the fermentation vats. Our research group previously carried out a thorough genetic characterization of an isolate of the PE-2 strain, known as JAY270. This analysis offers several opportunities for the improvement and modification of this strain. However, some studies observed the occurrence of karyotypic variation in this strain during the fermentation process, what can represent a barrier to the genetic manipulation of this yeast. Therefore, it is extremely important to study the genome behavior of this yeast during the ethanol production process. The main objective of this Master's Project was to determinate the genetic recombination mechanism responsible for generating chromosomal rearrangements in JAY270 during the ethanol production. A fermentation experiment in semi-industrial scale was carried out with a pure initial inoculum of JAY270. After 50 days, samples were collected and used to obtain single colony isolates. This isolates were analyzed through PFGE (Pulsed Field Gel Electrophoresis) to the identification of JAY270 derivatives carrying karyotypic variation. Of the analyzed derivatives, 36% had at least one chromosomal rearrangement. 11 of these derivatives were chosen to perform detailed analyses and were called FDY1-FDY11. The genome sequences of two haploid derivatives of JAY270 were used to develop 9 molecular markers to genotype heterozygous regions of JAY270 to identify genetic recombination events. The 11 isolates were analyzed with these markers and, except by one of them, all isolates were heterozygous in all genotyped regions. Two genetic recombination mechanisms can be responsible for generating the rearrangements, mitotic recombination, which occurs in isolate points of the genome, and meiotic recombination, that simultaneously affects all the genome in one single cellular cycle. The probability of the 10 isolates stay heterozygous in all genotyped regions after one event of meiosis followed by mating is extremely low (between 10-24 e 10-14). This result showed that these rearrangements couldn't be generated through meiotic recombination. Therefore, it was possible to conclude that the chromosomal rearrangements were generated during vegetative growth through mitotic recombination. The 11 isolates also were analyzed through CGH-array to compare their gene dosage with the strain JAY270. With this methodology it was possible to detect mitotic recombination events that resulted in loss of heterozygosity in peripheral regions of some chromosomes. / Mestrado / Genetica de Microorganismos / Mestre em Genética e Biologia Molecular

Etanol - Produção

Linhagem industrial

Variação cariotípica

Recombinação mitótica

Ethanol - Production

Industrial strain

Karyotypic variation

Mitotic recombination

Caracterização genética e citológica da recombinação somática em Trichoderma pseudokoningii. / Genetic and cytological characterization of the somatic recombination in Trichoderma pseudokoningii.

Barcellos, Fernando Gomes

28 August 2002

Com o objetivo de se caracterizar o processo de recombinação somática em Trichoderma pseudokoningii foram feitos cruzamentos via anastomose de hifas entre duas linhagens contrastantes para quatro marcadores de auxotrofia, coloração dos conídios e marcadores de RAPD. Foram feitos quatro cruzamentos, sendo analisados um total de 1052 colônias obtidas a partir de suspensões de conídios provenientes das colônias heterocarióticas. Sessenta e oito colônias recombinantes foram analisadas quanto às marcas de auxotrofia em quatro gerações de crescimento, sendo observado que 58 mantiveram o fenótipo recombinante, enquanto que as colônias restantes reverteram para um dos parentais. A maioria das colônias recombinantes se mostrou instável. Entretanto, após 4 gerações de crescimento estas colônias se tornaram estáveis para as marcas de auxotrofia avaliadas. As colônias recombinantes instáveis apresentaram bordas de crescimento irregular, esporulação esparsa e a freqüente formação de setores. Estas colônias recombinantes foram analisadas quanto aos marcadores RAPD, tendo mostrado grande similaridade, em relação ao perfil de bandas apresentado, com a maioria dos primers analisados. Somente com um primer foi possível visualizar a presença de uma banda polimórfica entre os recombinantes e a presença de bandas nos parentais não existentes em alguns recombinantes. Cinco colônias recombinantes foram analisadas quanto ao perfil de bandas cromossomais (PFGE), tendo sido observado que 2 colônias apresentaram padrões cromossomais igual a um dos parentais e 3 colônias apresentaram padrões recombinantes. Nos estudos citológicos verificou-se a formação de conídios uninucleados na conidiogênese, e a presença de conídios verdes maduros multinucleados, devido a prováveis divisões nucleares durante o processo de maturação dos conídios. Observou-se durante a formação dos heterocários a ocorrência de anastomoses e a passagem de núcleos, tendo sido observado a presença de núcleos com várias conformações, sugerindo um movimento ativo dos mesmos. Os resultados acima sugerem a ocorrência de mecanismos de recombinação no heterocário (recombinação somática), diferentes daqueles descritos para o ciclo parassexual ou parameiose, sendo proposto a ocorrência da degradação, no heterocário, dos núcleos de um dos parentais envolvidos nos cruzamentos (parental não prevalente) e a incorporação de segmentos destes em núcleos íntegros do parental prevalente. Se estes eventos realmente estiverem ocorrendo, sugere-se que estes sejam devido a possíveis reações limitadas de incompatibilidade vegetativa, ocasionando processos de lise e morte celular em algumas regiões do micélio heterocariótico. / To understand the somatic recombination process in Trichoderma pseudokoningii, auxotrophic complementary mutant strains were used to produce 4 heterokaryons. These strains were contrasting for four auxotrophic markers, conidia colors and for some RAPD markers. It was analyzed a total of 1052 colonies obtained from conidial suspensions of the heterokaryotic colonies. Stability of auxotrophic markers was evaluated in 68 recombinant colonies after four growing generations. In this analysis, 58 colonies kept the recombinant phenotype, while 10 reverted to one parental strain. Most of the recombinant colonies were initially unstable, but after at least 4 growing generations these recombinants became stable for auxotrophic markers. The unstable recombinant colonies showed irregular growing borders, sparse sporulation and frequent sector formation. The recombinant colonies were analyzed by RAPD technique. These colonies showed high similarity for the most of used primers. However, one primer showed a polymorphic band and some recombinants missing bands observed in parental strains. Chromosomal band profile of 5 recombinants and two parental strains were analyzed by Pulsed Field Gel Electrophoresis technique (PFGE). Two recombinants showed parental profiles and 3 showed recombinant profiles, respectively. In cytological studies of the conidiogenesis was observed the formation of only uninucleated conidia. However, presence of multinucleated mature green conidia was evident, probably due to nuclear divisions in course of maturing process of the conidia. During the process of heterokaryotic mycelium formation was possible to observe the occurrence of anastomosis that showed nuclear transfer. The presence of nuclei in several conformations was observed at the different regions of the heterokaryon, suggesting an active movement. The results presented in this study suggest the occurrence of recombination mechanisms in the heterokayon (somatic recombination), different from those described in classic parasexual cycle or parameiosis. Thus, it was proposed that may occur during this recombinant process the degradation of nuclei from one parental (non-prevalent parental) in the heterokaryon, and that the resulting chromosomal fragments may be incorporated into whole nuclei of the another parental (prevalent parental). If this natural transformation is occurring during this recombination process could be suggested that this event is due to a limited incompatible vegetative reactions, generating cellular lyses and death in some regions of the heterokaryotic mycelium.

cellulolytic fungus

ciclo parassexual

fungo celulolítico

genética microbiana

microbial genetics

mitotic recombination

parasexual cycle

recombinação mitótica

trichoderma

Linhagens de Aspergillus nidulans como biossensores de efeitos genotóxicos e antigenotóxicos de agentes ambientais. / Aspergillus nidulans strains as biosensors of genotoxic and antigenotoxic effects of environmental factors.

Zucchi, Fernando Domingues

09 June 2006

O principal objetivo deste trabalho é o de estabelecer uma estratégia confiável relacionada a genotoxicidade, proteção genômica e recombinação mitótica em Aspergillus nidulans. A genotoxicidade foi induzida por vapor de benzeno e, para testar a proteção genômica, a soja foi usada devido às suas propriedades anticarcinogênicas muito conhecidas. O principal resultado obtido foi que a soja transgênica mostrou maiores propriedades antigenotóxicas do que a soja tradicional. Isto foi duplamente confirmado, tanto através de estratégias de genética clássica, como molecular. Além disso, cada experimento foi repetido três vezes. Principais conclusões foram as seguintes: a) estabelecimento de um protocolo adequado para atender às complexidades dos eventos epigenéticos e, b) a aplicação desse tal protocolo e experimentos afins para testar outros agentes ambientais suspeitos de apresentarem propriedades antigenotóxicas, ou que precisem de sua identificação como tal. Evidentemente, levando-se em conta a grande preocupação relacionada aos alimentos transgênicos e aos muitos produtos de biotecnologia, que entram no mercado, o elenco de prováveis candidatos aos tipos de testes apresentados, será muito grande. Como os resultados obtidos sugerem íntima relação entre metilação de DNA eucariótico, a recombinação mitótica e outros eventos danosos às células, os eventos envolvidos serão epigeneticamente discutidos. / Main aim is to provide a reliable approach to deal with the aspects related to induced genotoxicity, genomic protection and eukaryotic mitotic recombination in Aspergillus nidulans. Genotoxicity was benzene fumes induced, and to test genomic protection soybean has been used on account of its putative anticarcinogenic properties. Main outcome is that transgenic soybean bears higher antigenotoxic properties than traditional soybean. This has been twofold confirmed through basic genetic approaches and molecular approaches, as well. In addition, each experimental approach has been three times repeated. Additional important outcomes are: a- establishment of a reliable protocol to deal with the complexities of the epigenetic events, and b- likely use of present protocol and experimental set-up to test other environmental agents of which antigenotoxic properties are either suspected, or need precise identification. Evidently, on account of present wide concern the transgenic foodstuffs, and many other biotechnological products, as well, are obvious candidates for similar approaches. Obtained results suggest close relationships among eukaryotic DNA methylation, mitotic recombination, and other cells damaging events reputedly leading to carcinogenesis.

Aspergillus nidulans

Aspergillus nidulans

Antigenotoxicidade

Antigenotoxicity

Benzene

Benzeno

DNA methylation

Epigenética

Epigenetics

Genotoxicidade

Genotoxicity

Metilação do DNA

Mitotic recombination

Recombinação mitótica

Caracterização genética e citológica da recombinação somática em Trichoderma pseudokoningii. / Genetic and cytological characterization of the somatic recombination in Trichoderma pseudokoningii.

Fernando Gomes Barcellos

28 August 2002

Com o objetivo de se caracterizar o processo de recombinação somática em Trichoderma pseudokoningii foram feitos cruzamentos via anastomose de hifas entre duas linhagens contrastantes para quatro marcadores de auxotrofia, coloração dos conídios e marcadores de RAPD. Foram feitos quatro cruzamentos, sendo analisados um total de 1052 colônias obtidas a partir de suspensões de conídios provenientes das colônias heterocarióticas. Sessenta e oito colônias recombinantes foram analisadas quanto às marcas de auxotrofia em quatro gerações de crescimento, sendo observado que 58 mantiveram o fenótipo recombinante, enquanto que as colônias restantes reverteram para um dos parentais. A maioria das colônias recombinantes se mostrou instável. Entretanto, após 4 gerações de crescimento estas colônias se tornaram estáveis para as marcas de auxotrofia avaliadas. As colônias recombinantes instáveis apresentaram bordas de crescimento irregular, esporulação esparsa e a freqüente formação de setores. Estas colônias recombinantes foram analisadas quanto aos marcadores RAPD, tendo mostrado grande similaridade, em relação ao perfil de bandas apresentado, com a maioria dos primers analisados. Somente com um primer foi possível visualizar a presença de uma banda polimórfica entre os recombinantes e a presença de bandas nos parentais não existentes em alguns recombinantes. Cinco colônias recombinantes foram analisadas quanto ao perfil de bandas cromossomais (PFGE), tendo sido observado que 2 colônias apresentaram padrões cromossomais igual a um dos parentais e 3 colônias apresentaram padrões recombinantes. Nos estudos citológicos verificou-se a formação de conídios uninucleados na conidiogênese, e a presença de conídios verdes maduros multinucleados, devido a prováveis divisões nucleares durante o processo de maturação dos conídios. Observou-se durante a formação dos heterocários a ocorrência de anastomoses e a passagem de núcleos, tendo sido observado a presença de núcleos com várias conformações, sugerindo um movimento ativo dos mesmos. Os resultados acima sugerem a ocorrência de mecanismos de recombinação no heterocário (recombinação somática), diferentes daqueles descritos para o ciclo parassexual ou parameiose, sendo proposto a ocorrência da degradação, no heterocário, dos núcleos de um dos parentais envolvidos nos cruzamentos (parental não prevalente) e a incorporação de segmentos destes em núcleos íntegros do parental prevalente. Se estes eventos realmente estiverem ocorrendo, sugere-se que estes sejam devido a possíveis reações limitadas de incompatibilidade vegetativa, ocasionando processos de lise e morte celular em algumas regiões do micélio heterocariótico. / To understand the somatic recombination process in Trichoderma pseudokoningii, auxotrophic complementary mutant strains were used to produce 4 heterokaryons. These strains were contrasting for four auxotrophic markers, conidia colors and for some RAPD markers. It was analyzed a total of 1052 colonies obtained from conidial suspensions of the heterokaryotic colonies. Stability of auxotrophic markers was evaluated in 68 recombinant colonies after four growing generations. In this analysis, 58 colonies kept the recombinant phenotype, while 10 reverted to one parental strain. Most of the recombinant colonies were initially unstable, but after at least 4 growing generations these recombinants became stable for auxotrophic markers. The unstable recombinant colonies showed irregular growing borders, sparse sporulation and frequent sector formation. The recombinant colonies were analyzed by RAPD technique. These colonies showed high similarity for the most of used primers. However, one primer showed a polymorphic band and some recombinants missing bands observed in parental strains. Chromosomal band profile of 5 recombinants and two parental strains were analyzed by Pulsed Field Gel Electrophoresis technique (PFGE). Two recombinants showed parental profiles and 3 showed recombinant profiles, respectively. In cytological studies of the conidiogenesis was observed the formation of only uninucleated conidia. However, presence of multinucleated mature green conidia was evident, probably due to nuclear divisions in course of maturing process of the conidia. During the process of heterokaryotic mycelium formation was possible to observe the occurrence of anastomosis that showed nuclear transfer. The presence of nuclei in several conformations was observed at the different regions of the heterokaryon, suggesting an active movement. The results presented in this study suggest the occurrence of recombination mechanisms in the heterokayon (somatic recombination), different from those described in classic parasexual cycle or parameiosis. Thus, it was proposed that may occur during this recombinant process the degradation of nuclei from one parental (non-prevalent parental) in the heterokaryon, and that the resulting chromosomal fragments may be incorporated into whole nuclei of the another parental (prevalent parental). If this natural transformation is occurring during this recombination process could be suggested that this event is due to a limited incompatible vegetative reactions, generating cellular lyses and death in some regions of the heterokaryotic mycelium.

ciclo parassexual

fungo celulolítico

genética microbiana

recombinação mitótica

trichoderma

cellulolytic fungus

microbial genetics

mitotic recombination

parasexual cycle

Linhagens de Aspergillus nidulans como biossensores de efeitos genotóxicos e antigenotóxicos de agentes ambientais. / Aspergillus nidulans strains as biosensors of genotoxic and antigenotoxic effects of environmental factors.

Fernando Domingues Zucchi

09 June 2006

O principal objetivo deste trabalho é o de estabelecer uma estratégia confiável relacionada a genotoxicidade, proteção genômica e recombinação mitótica em Aspergillus nidulans. A genotoxicidade foi induzida por vapor de benzeno e, para testar a proteção genômica, a soja foi usada devido às suas propriedades anticarcinogênicas muito conhecidas. O principal resultado obtido foi que a soja transgênica mostrou maiores propriedades antigenotóxicas do que a soja tradicional. Isto foi duplamente confirmado, tanto através de estratégias de genética clássica, como molecular. Além disso, cada experimento foi repetido três vezes. Principais conclusões foram as seguintes: a) estabelecimento de um protocolo adequado para atender às complexidades dos eventos epigenéticos e, b) a aplicação desse tal protocolo e experimentos afins para testar outros agentes ambientais suspeitos de apresentarem propriedades antigenotóxicas, ou que precisem de sua identificação como tal. Evidentemente, levando-se em conta a grande preocupação relacionada aos alimentos transgênicos e aos muitos produtos de biotecnologia, que entram no mercado, o elenco de prováveis candidatos aos tipos de testes apresentados, será muito grande. Como os resultados obtidos sugerem íntima relação entre metilação de DNA eucariótico, a recombinação mitótica e outros eventos danosos às células, os eventos envolvidos serão epigeneticamente discutidos. / Main aim is to provide a reliable approach to deal with the aspects related to induced genotoxicity, genomic protection and eukaryotic mitotic recombination in Aspergillus nidulans. Genotoxicity was benzene fumes induced, and to test genomic protection soybean has been used on account of its putative anticarcinogenic properties. Main outcome is that transgenic soybean bears higher antigenotoxic properties than traditional soybean. This has been twofold confirmed through basic genetic approaches and molecular approaches, as well. In addition, each experimental approach has been three times repeated. Additional important outcomes are: a- establishment of a reliable protocol to deal with the complexities of the epigenetic events, and b- likely use of present protocol and experimental set-up to test other environmental agents of which antigenotoxic properties are either suspected, or need precise identification. Evidently, on account of present wide concern the transgenic foodstuffs, and many other biotechnological products, as well, are obvious candidates for similar approaches. Obtained results suggest close relationships among eukaryotic DNA methylation, mitotic recombination, and other cells damaging events reputedly leading to carcinogenesis.

Aspergillus nidulans

Antigenotoxicidade

Benzeno

Epigenética

Genotoxicidade

Metilação do DNA

Recombinação mitótica

Aspergillus nidulans

Antigenotoxicity

Benzene

DNA methylation

Epigenetics

Genotoxicity

Mitotic recombination

THE VISUALIZATION, QUANTIFICATION AND MODELING OF GENOMIC INSTABILITY IN THE MOUSE AND IN CULTURED CELLS

LARSON, JON SCOTT

January 2006

No description available.

mutation

genomic instability

placental alkaline phospatase

microsatellite instability

loss of heterozygosity

embryonic stem cells

uniparental disomy

germline mutation

oxidative stress

maternal effect

harlequin mouse

mitotic recombination