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Meiotic effect of MutS homolog 6 (Msh6) mutation in two mouse subspecies
Fusek, Karel ; Forejt, Jiří (advisor) ; Reifová, Radka (referee)
To study hybrid sterility our laboratory uses mouse strains PWD/Ph (PWD), derived from Mus musculus musculus wild mice and the common laboratory strain C57BL/6J (B6) mostly of Mus musculus domesticus origin as a model. Crossing between PWD female and B6 male results in sterile male progeny. F1 hybrid males carry defects in the repair mechanisms of asymmetric double-strand DNA breaks (DSBs). Functional interplay of SPO11 and PRDM9 proteins in the meiotic prophase I is necessary for repairs. Its defect leads to incorrect synapse formation between homologous chromosomes, leading to halt in spermatogenesis and thus male sterility. The formation of DSBs and their subsequent repair is essential for first meiotic division. The working hypothesis stems from the findings in yeast model, where supposed antirecombinatorial mechanism of mismatch repair genes Msh6 and Msh2 prevents DSBs repairs during meiosis. Despite the functional mechanism of these two genes is not explicitly known, existence of similar repair system in mice is presumed. Variety of methods was implemented in this thesis. The effects of Msh6 deletion on meiotic prophase I and sperm maturation were performed by designing guide RNAs for CRISPR/Cas9 for creation of three knock-outs in B6 mice. The PCR was used to amplify regions adjacent to the...
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The role of Prdm9 in the house mouse hybrid sterility model
Mukaj, Amisa ; Parvanov, Emil (advisor) ; Děd, Lukáš (referee) ; Reifová, Radka (referee)
(English) Hybrid sterility is a phenomenon representing reproductive isolation between closely related species and thus assuring the process of speciation. Hybrid sterility is a complex polygenic trait and the most significant advance in its study is achieved in Drosophila melanogaster. Nearly half century ago Forejt and Ivanyi mapped the first hybrid sterility genetic locus in vertebrates (Hybrid sterility 1, Hst1) in crosses of wild mice with laboratory inbred strains where the male offspring is sterile. Further mapping of the locus led to discovery of a gene called PR domain zinc finger protein 9 (Prdm9), a histone methyltransferase, whose deficiency causes meiotic arrest and sterility in mice. Furthermore, it was found that Prdm9 defines the hotspot placement in meiotic recombination by posting trimethylation marks on lysine residues 4 and 36 of histone 3 hence explaining the observed defects in its absence during meiosis. Nonetheless, its exact role in molecular mechanism of hybrid sterility is yet unclear. Prdm9 expression is present during the stage of formation of meiotic DNA double-strand breaks and is a hint about the time of hybrid sterility initiation. Phenotypically in the case of male mouse hybrid sterility is observed incomplete chromosome synapsis, meiotic arrest at mid-to-late...
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Genetic interactions of the Prdm9 gene
Šebestová, Lenka ; Trachtulec, Zdeněk (advisor) ; Král, Jiří (referee)
The Prdm9 gene (PR domain containing 9, Meisetz, Hybrid sterility 1) encodes enzyme that trimethylates histone 3 on lysines 4 and 36. These methylation marks determine the positions of DNA double-strand breaks that are repaired by meiotic homologous recombination. In this study, we assayed genetic interactions of Prdm9 with two genes important for spermatogenesis - Mili (Piwil2) involved in piRNA biogenesis and Mybl1 encoding transcription factor that regulates many genes important for prophase I, including piRNA precursors. We crossed laboratory mice carrying mutation in Prdm9 with heterozygotes for mutation in Mybl1 or Mili, and created compound heterozygotes and, in case of Mybl1, also double homozygotes. We assessed body weight and male fertility parameters (weight of testes, sperm count, malformed sperm, percentage of tubules containing spermatocytes and of abnormal nuclei of pachytene spermatocytes) of these mice and compared them to controls. We also investigated the effect of Mybl1 and Mili mutations on fecundity of F1 intersubspecific hybrids. Our results revealed possible interactions of Prdm9 and Mybl1 in the laboratory mouse. Decreased gene dosage of Mybl1 reduced fertility of intersubspecific F1 hybrids. Interaction between Prdm9 and Mili in both laboratory mouse and F1 hybrids remain...
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Genetic conflicts and speciation
Kropáčková, Lucie ; Reifová, Radka (advisor) ; Munclinger, Pavel (referee)
In this thesis I'll examine the role of genetic conflicts in the origin of new species. Genetic conflicts can lead to an origin of reproductive barrier between the emerging species, especially postzygotic reproductive isolation. An example of such conflict could be meiotic drive on sex chromosomes, which distort sex ratio and seems to act a role in a hybrid male sterility. Another example may be genomic imprinting causing an abnormal placenta and embryo development in interspecies hybrids. Coevolution between cytoplasmic and nuclear genes can cause sterility of pollen in hybrids from plants. Similarly, the intracellular bacterium Wolbachia induces cytoplasmic incompatibility in animals. Mobilization of transposons may also lead to hybrid dysgenesis.
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Characterization of the Hstx1 and Hstx2 hybrid sterility candidate genes
Kašíková, Lenka ; Jansa, Petr (advisor) ; Rothová, Olga (referee)
Speciation, the formation of new species, is an essential evolutionary process that causes species diversity on the Earth. At the beginning of this process is the separation of two populations by a reproductive barrier that prevents gene flow between these populations. One of the mechanisms, which enable reproductive isolation, is hybrid sterility (HS). It is a mechanism of postzygotic isolation that is described in a number of eukaryotes. The first discovered gene of hybrid sterility in vertebrates is the mice gene Hst1, later identified as gene Prdm9. By genetic and molecular analysis the locus on the X chromosome was determined, whose interaction with Prdm9 causes sterility or reduced fitness in male hybrids. This locus contains two genetic factors: Hstx1, causing an abnormal morphology of spermatozoa, and Hstx2, causing an arrest in spermatogenesis in pachytene spermatocytes and sterility. In my thesis I focus on the effect of deletion of a candidate hybrid sterility gene Fmr1nb on the X chromosome. The analysis of males B6N.Fmr1nbmut with deletion variants of the Fmr1nb gene showed that Fmr1nb is one of the factors influencing spermatogenesis. An increase in morphologic abnormalities in spermatozoa occurred in males with Fmr1nb gene deletion. This phenotype is identical with Hstx1. The effect...
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Meiotic effect of MutS homolog 6 (Msh6) mutation in two mouse subspecies
Fusek, Karel ; Forejt, Jiří (advisor) ; Reifová, Radka (referee)
To study hybrid sterility our laboratory uses mouse strains PWD/Ph (PWD), derived from Mus musculus musculus wild mice and the common laboratory strain C57BL/6J (B6) mostly of Mus musculus domesticus origin as a model. Crossing between PWD female and B6 male results in sterile male progeny. F1 hybrid males carry defects in the repair mechanisms of asymmetric double-strand DNA breaks (DSBs). Functional interplay of SPO11 and PRDM9 proteins in the meiotic prophase I is necessary for repairs. Its defect leads to incorrect synapse formation between homologous chromosomes, leading to halt in spermatogenesis and thus male sterility. The formation of DSBs and their subsequent repair is essential for first meiotic division. The working hypothesis stems from the findings in yeast model, where supposed antirecombinatorial mechanism of mismatch repair genes Msh6 and Msh2 prevents DSBs repairs during meiosis. Despite the functional mechanism of these two genes is not explicitly known, existence of similar repair system in mice is presumed. Variety of methods was implemented in this thesis. The effects of Msh6 deletion on meiotic prophase I and sperm maturation were performed by designing guide RNAs for CRISPR/Cas9 for creation of three knock-outs in B6 mice. The PCR was used to amplify regions adjacent to the...
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Meiotic homologous recombination and hybrid sterility
Gergelits, Václav ; Forejt, Jiří (advisor) ; Macholán, Miloš (referee) ; Munclinger, Pavel (referee)
(English) Meiotic homologous recombination, homologous chromosomes synapsis, and F1 hybrid sterility (enabling formation of species) are mutually interconnected phenomenons, one being the prerequisite to the latter. In the present thesis, these phenomenons were investigated on a genetic and mechanistic level using a mouse subspecies as a model. Noncrossovers (NCOs, gene conversions), 90% prevalent resolution of Prdm9- determined meiotic double-strand breaks (DSBs), were uniquely identified and characterized on a chromosome-wide level. The mean gene conversion tract length, based on 94 NCOs events, was calculated to be 32 bp. On a local level, the NCOs overlapped the known hotspots of PRDM9-controlled histone trimethylation and DSB formation, indicating their origin in the standard meiotic DSB repair pathway. On chromosome-wide level, NCO and CO distributions differed, in particular COs being relatively preferred over NCOs in subtelomeric regions. A specific subset of nonparental/asymmetric NCOs and COs was underrepresented in our datasets, proposing their problematic repair, hypothetically enabled by sister chromatids, and thus not contributing to indispensable homologous synapsis. Genome-wide crossover (CO) rates, genetically and mechanistically crucial ~10% of DSB repair, were proven to be...
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The role of histone modifications and gene expression in mouse spermatogenesis
Křivánková, Klára ; Mihola, Ondřej (advisor) ; Jansa, Petr (referee)
The production of haploid sperm is a precondition for sexual reproduction of males. PRDM9 protein is a histone methyltransferase which localizes sites of meiotic recombination in many mammals. Mouse males of the C57BL/6J (B6) strain deficient for Prdm9 (Prdm9-/- ) are sterile, while Prdm9-/- males of PWD/Ph (PWD) strain have reduced sperm count. The comparison of the distribution of trimethylation of histone 3 on lysine 36 (H3K36me3) in genome of Prdm9-/- males of these two strains will help to determine the role of this epigenetic modification on meiotic recombination and fertility of Prdm9-/- males. The second part of this thesis is focused on transgenic males. Male offspring from the first generation of B6 female and PWD male crosses (B6PF1) have reduced fertility parameters due to incompatibility of Prdm9 alleles. The fertility parameters of B6PF1 hybrids carrying CHORI-34-289M8 or RP24-346I22 transgene are even lower. The candidate gene, which participates in the reduction of fertility of the transgenic B6PF1 hybrids, was determined as the proteasome subunit encoding gene Psmb1, because its relative transcription level best correlates with sperm count. The reason of lowered fertility thus might be a defect in proteasome assembly. The investigation of the fitness of transgenic animals is...
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Analysis of dosage effect of speciation gene Prdm9 on fertility of mouse hybrids
Flachs, Petr ; Trachtulec, Zdeněk (advisor) ; Stopka, Pavel (referee) ; Král, Jiří (referee)
(eng) The phenomenon of hybrid sterility represents one of the evolutionary mechanisms that enables speciation. Only a few speciation genes have been uncovered. The only one found in mammals is Prdm9 (PR-domain 9). Data in the literature on the involvement of Prdm9 in decreased fertility of various semifertile hybrid males of house mouse subspecies were scarce before the results of this thesis were completed, despite that such males are much more frequent in nature than the fully sterile ones. Utilizing a panel of genetic tools and a battery of phenotyping tests, this thesis shows a central role of Prdm9 in fecundity of hybrids, including many fertility disorders and age dependency. Both increasing and reducing the Prdm9 gene dosage significantly elevated fertility parameters. Surprisingly, even the allele that in one copy causes full hybrid sterility increased F1 hybrid fertility when present in multiple copies. The PRDM9 protein also plays a role in identifying the sites of meiotic recombination. This study also points out the principles of allelic competition in determination of the sites of preferred recombination (hotspots), which suggests a possible link between both previously described Prdm9 roles. This thesis summarizes a set of three logically interconnected publications with the ambition...
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