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Sexuality in wild Agaricus species, classical and molecular analysisCalvo-Bado, Leonides Antonio January 1999 (has links)
No description available.
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ROLE OF THE SEXUAL CYCLE IN DEVELOPMENT OF GENOTYPIC AND PHENOTYPIC DIVERSITY IN Gibberella zeaeBec, Sladana 01 January 2011 (has links)
Gibberella zeae (anamorph Fusarium graminearum) is a homothallic ascomycete pathogen that is responsible for causing Fusarium head blight (FHB) of wheat and small grains. In addition to causing a reduction in yield, harvested grain is frequently contaminated with trichothecene mycotoxins that are harmful for human and animal health. Use of wheat varieties with resistance to FHB is an important strategy to lower its impact. In order to produce varieties with durable resistance, we must understand the origin and degree of genetic diversity present in the pathogen population. In my research, I focused my efforts on an investigation of the role of mating and sexual development in the generation of genotypic and phenotypic variability in G. zeae. The goal of one part of my work was to develop new genetic markers that can be used to monitor out-crossing and genetic diversity in the population. I also optimized gene deletion protocols for G. zeae so that I could produce mutant and control strains to address my research hypothesis that MAT genes play a direct role in pathogenicity. Application of novel repetitive RFLP probes to a group of G. zeae isolates originating from and near Kentucky revealed a surprisingly high degree of diversity in these local populations. Diversity between locations was greater than that within locations, suggesting the relative importance of local inoculum sources. The probes were also useful as genetic markers for segregation analysis. I crossed two genetically closely related, and commonly used, laboratory strains of G. zeae and found that this resulted in transgressive segregation for both aggressiveness and toxigenicity. I showed that the very high and very low levels of aggressiveness and toxigenicity in transgressive segregants are heritable. I also showed that selfing produced a higher degree of diversity in these traits among the progeny than was observed among conidial progeny. This suggests the presence of epigenetic factors that impact pathogenicity. Sexual behavior in G. zeae is under the control of MATing type genes. I deleted the complete MAT1 locus, and the MAT1-1-1, and MAT1-2-1 genes separately. Deletion of each of the targeted sequences produced the expected shifts in fertility phenotype. The mat1KO strains became asexual, while mat1-1-1KO and mat1-2-1KO strains shifted to obligate heterothallism. Deletion of the MAT1-1-1 and MAT1-2-1 genes had a negative effect on aggressiveness and mycotoxin production in planta, but deletion of the complete MAT1 locus had no effect. The set of mutant and ectopic control strains that I generated will be a useful asset that will be made available to the research community.
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The Recombination Enhancer Modulates the Conformation of Chr. III in Budding Yeast: A DissertationBelton, Jon-Matthew 09 December 2014 (has links)
A hierarchy of different chromosome conformations plays a role in many biological systems. These conformations contribute to the regulation of gene expression, cellular development, chromosome transmission, and defects can lead to human disease. The highest functional level of this hierarchy is the partitioning of the genome into compartments of active and inactive chromatin domains (1’s -10’s Mb). These compartments are further partitioned into Topologically Associating Domains (TADs) that spatially cluster co-regulated genes (100’s kb – 1’s Mb). The final level that has been observed is long range loops formed between regulatory elements and promoters (10’s kb – 100’s Mb). At all of these levels, mechanisms that establish these conformations remain poorly understood. To gain new insights into processes that determine chromosome folding I used the mating type switching system in budding yeast to study the chromosome conformation at length scales analogous to looping interaction. I specifically examined the role in chromosome conformation in the mating type switching system. Budding yeast cells can have two sexes: MATa and MATα. The mating types are determined by allele-specific expression of the MAT locus on chromosome III. The MATa allele encodes for transcription factors responsible for the MATa mating type and the MATα allele encodes transcription factors responsible for the MATα mating type. Yeast cells can switch their mating type by a process that repairs a break at MAT using one of two silent loci, HML or HMR, as a donor to convert the allele at the MAT locus. When MATa cells switch they prefer to use HML, which contains the MATα allele, located at the end of the left arm. MATα cells prefer to use HMR, which contains the MATa allele, located on the end of the right arm of chromosome III. The sequences of the HM loci are not important for donor preference. Instead the cell chooses the donor on the left arm in MATa cells and chooses the donor on the right arm in MATα cells. This lack of sequence specificity has led to the hypothesis that the conformation of the chromosome may play a role in donor preference. I found that the conformation of chromosome III is, indeed, different between the two mating types. In MATa cells the chromosomes displays a more crumpled conformation in which the left arm of the chromosome interacts with a large region of the right arm which includes the centromere and the MAT locus. In MATα cells, on the other hand, the left arm of the chromosomes displays a more extend conformation. I found that the Recombination Enhancer (RE), which enhances recombination along the left arm of the chromosome in MATa cells, is responsible for these mating type-specific conformations. Deleting the RE affects the conformation of the chromosomes in both MATa and MATα cells. The left portion of the RE, which is essential for donor preference during the switching reaction in MATa cells, does not contribute to the conformation in MATa. This region does have a minor effect on the conformation in MATα cells. However, I found that the right portion of the RE is responsible for the conformation of chromosome III in both mating types prior to initiation of switching. This work demonstrates that chromosome conformation is determined by specific cis regulatory elements that drive cell-type specific chromosome conformation.
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Molecular analysis of genes acting in fruiting body development in basidiomycetesSrivilai, Prayook 27 September 2006 (has links)
No description available.
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Dermatofyty izolované ze srsti volně žijících hlodavců / Dermatophytes isolated from the hair of free-living rodentsŽárová, Štěpánka January 2020 (has links)
Dermatophytes (order Onygenales, Ascomycota) are microscopic filamentous keratinophilic fungi that can cause skin infections known as dermatophytosis. The most diverse but not very studied genus Arthroderma has been revised recently (Míková 2018) which was essential for further research. This genus comprises mostly species with a supposed reservoir in soil. Lack of information about their ecology and frequent isolation of some species from the hair of free- living mammals (mainly rodents) may testify a strong host association. Rodents could thus represent the hidden reservoir of this species. For this thesis, I have chosen three ecologically distinct rodent species: Mus musculus, Apodemus flavicollis, and Clethrionomys glareolus. I obtained the material by brushing the hair of asymptomatic individuals and used this material for cultivation on selective medium. I identified the isolates of dermatophytes (n = 30) using molecular methods. I used sequences of three highly variable loci (ITS, tubb a tef1α) to incorporate these isolates in the phylogenetic analysis based on the monography of the genus Arthroderma (Míková 2018). I characterized the phenotype of selected strains based on morphological and physiological data including the ability to utilize keratin and the production of siderophores. The...
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Ověření druhových hranic mezi klinicky významnými geofilními druhy Arthroderma / Verification of species boundaries in clinically relevant Arthroderma speciesMíková, Ivana January 2018 (has links)
The genus Arthroderma contains predominantly geophilic dermatophytes (naturally occuring in soil). Some species, especially those from Trichophyton terrestre complex, cause human and animal dermatomycosis. In the past, the species boundaries were determined mainly on the basis of biological species concept using in vitro mating experiments. But these nearly 70-years-old findings have not been tested by means of modern taxonomic methods. In total 194 species of the genus Arthroderma (including all available ex-type strains) originating predominantly in USA, Canada and Europe were studied in this thesis. They were mostly isolated from soil (n = 77), animals (n = 50), human clinical material (n = 41) and cave sediment (n = 9). The main goal of the thesis was to elucidate the species boundaries between species A. insingulare, A. lenticulare and A. quadrifidum, that were classified into the T. terrestre complex because of their seemingly identical asexual stage. Further, this work aimed to resolve the relationship between Arthroderma species using the multigene phylogeny and clarify which species are clinically relevant. A multigene phylogeny of the genus Arthroderma was based on the sequences of the ITS rDNA region, β-tubulin (TUB2) and translation elongation factor 1α (TEF1α) genes. The genus...
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