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Studying the evolution of chromosome rearrangements in pipid frogs using in situ hybridization
Bergelová, Barbora ; Knytl, Martin (advisor) ; Johnson Pokorná, Martina (referee)
In African pipid frogs we can find at least eight polyploidization events in which a lot of levels of ploidy arose. This group includes diploid, tetraploid, octoploid, and/or dodecaploid species. Due to this great variability in ploidy levels, representatives of the genus Xenopus are excellent model organisms for studying the evolution of whole-genome duplications and chromosomal rearrangements. Currently, little information is known about chromosomal rearrangements within the Xenopus species, specifically, there are only two known cases of large-scale rearrangements. The first is a fusion of chromosomes 9 and 10 in the subgenus Xenopus and the other rearrangement is a non-reciprocal translocation occurring between chromosomes 2 and 9 in the subgenus Silurana. In this diploma thesis, we attempted to expand the knowledge about chromosomal rearrangements using the fluorescence in situ hybridization method. We confirmed the fusion of chromosomes 9 and 10 in other species of the Xenopus genus, such as X. pygmaeus, and proposed a hypothesis about the possibility that this fusion occurred in the common diploid ancestors of this subgenus. We also gained further insights into the origin of non-reciprocal translocation within the Silurana subgenus. This translocation was not detected in the species X....
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Drivers of karyotype evolution in Lepidoptera
PROVAZNÍKOVÁ, Irena
Research of lepidopteran karyotypes and their evolution has been challenging for decades due to their many peculiar characteristics. However, this field has advanced thanks to modern cytogenetic techniques and sequencing technologies. We combined explored possibilities how to detect chromosomal rearrangements, and cytogenetic and genomic approaches to explore evolutionary forces shaping karyotypes of non-model Lepidoptera including representatives of early diverging species. Results obtained in the present thesis point to a possible role of satellite DNA and sexual antagonistic selection in mobilisation of rDNA and sex chromosome turnover, respectively.
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Mechanisms of origin of cryptic rearrangements in human chromosomes and its clinical associations
Šenkyřík, Pavel ; Šolc, Roman (advisor) ; Drábová, Jana (referee)
Chromosomal rearrangements are one of the processes which leads to formation of genetic disorders. Among the mechanisms that cause the rearrangements belong NAHR, NHEJ, FoSTeS and MMBIR. They generate rearrangements of many types and have different requirements for their realization. NAHR is recombination-based mechanism responsible for recurrent rearrangements and operates mainly in repetitive sequences. NHEJ is used for repair of double-strand breaks and generates non-recurrent rearrangements due to its error rate. FoSTeS and MMBIR are replication-based mechanisms able to make both complex rearrangements and less massive non-recurrent rearrangements. Architecture of DNA has influence on all above-mentioned mechanisms. Structures that affect course or effectivity of mechanisms are microhomologies, double-strand breaks, tandem repetitions, hairpins, and loops causing stalling of replication fork.
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Analysis of structure and origin of multiple sex chromosomes in \kur{Leptidea} wood white butterflies
POSPÍŠILOVÁ, Kristýna
Previous studies have shown a dynamic karyotype evolution and the presence of complex sex chromosome systems with 3-4 W chromosomes and 3-6 Z chromosomes in Leptidea wood white butterflies. To dissect the evolutionary history of multiple Z chromosomes of Leptidea species, we used identified and selected bacterial artificial chromosome (BAC) clones containing orthologous genes of Bombyx mori chromosome Z and 17, isolated them from the available BAC library and used them as probes for physical mapping by BAC-FISH, first in L. juvernica, then in the closely related L. sinapis. In both Leptidea species, the majority of BAC clones corresponding to the linkage group Z of the B. mori reference genome hybridized to one chromosome of the complicated sex chromosome multivalent. Thus, we named it as Z1 chromosome. Location of all Z-derived BAC clones was identical in both species suggesting a conserved synteny and gene order between L. juvernica and L. sinapis Z1 chromosome. Moreover, our findings indicate that the Z1 chromosome is probably the ancestral Z chromosome in the genus Leptidea. Results of BAC-FISH mapping with clones corresponding to the linkage group 17 of the B. mori reference genome revealed the fusion/translocation event between an ancestral Z chromosome and the chromosome corresponding to B. mori chromosome 17 and supported a previous hypothesis about the role of chromosomal rearrangements in the formation of multiple sex chromosomes in Leptidea butterflies.
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Neo-sex chromosomes and their evolutionary significance
Košátko, Prokop ; Král, Jiří (advisor) ; Johnson Pokorná, Martina (referee)
Neo-sex chromosomes arise due to rearrangements between ancestral gonosomes and autosomes. Neo-sex chromosomes are valuable systems for the study of sex chromosome evolution. It is possible to use them for analysis of processes driving the formation of differentiated sex chromosomes, especially suppression of recombinations and alosome degeneration. The most important rearrangements forming neo-sex chromosomes are Robertsonian and reciprocal translocations. Speciation events are important consequences of birth of neo-sex chromosomes. The presented study is focused on the evolution of neo-sex chromosomes in drosophilids, muntjacs, and monotremes. Neo-sex chromosomes emerged in many Drosophila species. The genome of D. albomicans carries the youngest known neo-sex chromosome system, which arised only one hundred thousand years ago. Information from research into Drosophila neo-sex chromosomes underlines the importance of Muller's ratchet and background selection at the beginning of sex chromosome differentiation and hitchhiking and deleterious mutations at the end of this process. Genomes of muntjacs carry young and fast evolving neo-sex chromosomes. In several muntjac species, neo-sex chromosomes form a considerable part of the genome. The neo-sex chromosome systems of monotremes consist of many...
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