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Immunomodulatory potential of Sertoli cell progenitors during heart regeneration after injury in Xenopus
Žabková, Světlana ; Krylov, Vladimír (advisor) ; Procházka, Jan (referee)
The high percentage of mortality associated with cardiovascular diseases shows the importance of studying cardiac muscle regeneration. An interesting approach for heart regeneration may be the use of a cell culture of Sertoli progenitor cells and peritubular myoid cells derived from juvenile testes of Xenopus tropicalis that was named XtiSC. These cells were found to share a number of characteristics which are typical for mesenchymal stem cells. Mesenchymal stems cells are well-known for their immunomodulatory and anti-inflammatory abilities that promote heart regeneration. The goal of this master thesis was to test the immunomodulatory potential of Sertoli progenitor cells during heart regeneration after heart apex amputation in Xenopus tropicalis without macrophages. The reason for macrophages depletion was the assumption that XtiSC behave like macrophages in many aspects. Clodronate encapsulated in liposomes was chosen as a tool for macrophage depletion. It was confirmed that XtiSC can positively influence heart regeneration in a classic model of heart regeneration, but also in a model with depletion of macrophages. It was revealed that Xenopus tropicalis adults without macrophages injected with XtiCS into the hindlimb skeletal muscle 3 days before apical resection showed reduced fibronectin...
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Preparation of X. tropicalis recombinant growth factors and their characterization in testicular tissue culture.
Borecká, Marianna ; Krylov, Vladimír (advisor) ; Drobná Krejčí, Eliška (referee)
In our Laboratory of Developmental Biology there was established a long term culture derived from Xenopus tropicalis testes. It contains pre-Sertoli cells mostly. They compose a feeder layer allowing cultivation of stem cells, revealing the morphology of spermatogonial stem cells. This diploma thesis was focused on a preparation of two growth factors, FGF2 (fibroblast growth factor 2) and GDNF (glial cell line-derived neurotrophic factor), with the subsequent characterization of their influence at cell culture mentioned above. Factors were selected on the basis of the microenvironmental niche theory, according which FGF2 and GDNF are the most important factors for spermatogonial stem cells proliferation and self-renewal. FGF2 recombinant factor was gained using the expression plasmid pET-15b. Its characterization in the testicular culture brought surprising result. Even a low concentration of FGF2 factor (2.5ng/ml) caused cell detaching and dying. Similar result was previously shown in differentiating osteoblast culture only. More experiments need to be done to prove if apoptose take place and why do testicular cells act this way. Key words: Xenopus tropicalis, FGF2, GDNF, SSC, pre-Seroli cells
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Physical mapping of genome regions without linkage map using BAC clones in Xenopus tropicalis
Špirhanzlová, Petra ; Krylov, Vladimír (advisor) ; Marec, František (referee)
Xenopus leavis was a favorite model organism during the 20th. century, but nowadays it has been replaced by diploid Xenopus tropicalis, which has not only shorter generation time, but also smaller genom. One of the disadvantages of Xenopus tropicalis is the lack of full physical and linkage map. According to JGI genome database (assembly 4.1) there are unmapped regions on short arm of the chromosome 2 and 7 . Several BAC clones ( with a single or dual-end sequence) has been found to be located within this region, according to a recent assembly 7.1. However , it isn't clear whether 100bp length of BAC ends is enough to place entire BAC clone into the genom of Xenopus tropicalis. In order to prove correct inclusion of these BAC clones into JGI database, several BAC clones, which are supposed to be located on short arm of chromosome 2, were picked. Using fluorescence in situ hybridisation, the signal of these BAC clones was localised on the short arm of chromosome 1 instead of chromosome 2 and in most cases they had opposite orientation. It means that the 100bp lenght of BAC ends propably isn't sufficient to place entire BAC clone on chromosome. New working protocol of BAC DNA isolation and labeling was established.
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Genetic mapping in Xenopus
Seifertová, Eva ; Krylov, Vladimír (advisor) ; Ráb, Petr (referee) ; Marec, František (referee)
The diploid amphibian Xenopus tropicalis represents a significant model organism for studies of early development, genes function and evolution. Such techniques as gynogenesis, injection of morpholino antisense oligonucleotide into fertilized eggs or transgenesis were established. In the recent ten years, many efforts have been made to complete the sequence information. X. tropicalis genome has been sequenced but the completion of its assembly only on the basis of sequence data has been impossible. Therefore, our first work was focused on one of approaches for a genome completing- genetic mapping. First of all, the genetic map of Xenopus tropicalis was established pursuant linkage and physical positions of markers. Since the map contained gaps, we developed a new method for genetic mapping based on the next generation sequencing of laser microdissected arm. Using Illumina next generation sequencing of fifteen copies of a short arm of chromosome 7, we obtained new insights into its genome by localizing previously unmapped genes and scaffolds as well as recognizing mislocalized portions of the genome assembly. This was the first time laser microdissection and sequencing of specific chromosomal regions has been used for the purpose of genome mapping. These data were also used in the evolution study of...
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Preparation of Xenopus tropicalis transgenic testicular stem cell culture.
Vegrichtová, Markéta ; Tlapáková, Tereza (advisor) ; Drobná Krejčí, Eliška (referee)
Testicular stem cells (TSCs) are relatively accessible potential source of pluripotent cells, which are particularly important for their application in regenerative medicine. Xenopus tropicalis is a useful model organism to study the migration and differentiation potential of stem cells. This amphibian is characteristic by outer fecundation and embryonic development of a great amount of embryos after fertilization. Oocytes and embryos are large enough (about 1 mm) to be suitable for micromanipulation micromanipulations. Laboratory of Developmental Biology, Faculty of Science, Charles University in Prague succeeded in the establishment of a mixed cell culture of TSCs growing on feeder layer of pre- Sertoli cells. This culture was derived from the testes of juvenile Xenopus tropicalis male. In the study of their differentiation potential it was found, that leukemia inhibitory factor (LIF) is the decisive factor allowing rapid proliferation of stem cells and their forming into characteristic colonies. This protein is produced by both types of cells which are present in the culture. The mouse LIF has the same positive effect on the proliferative potential of stem cells, which points at the evolutionary conservation of metabolic pathways associated with the maintenance of the stemness. RT-PCR analysis...
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In vitro differentiation of Xenopus tropicalis and Mus musculus testicular somatic cells.
Hlaviznová, Michaela ; Tlapáková, Tereza (advisor) ; Hovořáková, Mária (referee)
Sertoli cells (SCs) are somatic cells of testicular tissue that are involved in spermatogenesis and maturation of germ cells. They are currently being extensively studied for their immunomodulatory abilities, and recent studies have shown that they share some properties with mesenchymal stromal cells (MSCs). Detailed characterization of SCs and clarification of their role in testicular tissue is crucial for potential use of SCs as a therapeutic tool in regenerative medicine. Cell culture of Xenopus tropicalis immature Sertoli cells (XtiSCs) and Mus musculus (mSCs) Sertoli cells were established in the Laboratories of Developmental Biology and Immunoregulations, Faculty of Science, Charles University. Previous research has characterized XtiSCs and demonstrated their multipotent potential by in vitro differentiation into a mesodermal line. Following this research, one of the goals of the diploma project was the induction of in vitro differentiation of XtiSC into other cell types, which would verify the differentiation potential of XtiSCs. The mSC expression profile confirmed the somatic origin of this culture as well as the transcription of Sertoli cell gene markers. Differentiation of mSCs along the mesodermal line into osteoblasts, chondrocytes and adipocytes has been successfully induced in vitro....
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Differentiation of Sertoli cell progenitors and preparation of testicular 3D cultures of Xenopus tropicalis.
Slováková, Lucie ; Tlapáková, Tereza (advisor) ; Hovořáková, Mária (referee)
Sertoli cells represent the only somatic cell type within the seminiferous tubules with direct contact to germ cells. Sertoli cells significantly contribute to the development of the testicular niche in a male embryo. Their role during postnatal life is in the regulation and nutrition of germ cells and the formation of the blood-testis barrier to protect these cells. In our laboratory, we have been successful in establishing a cell line of X. tropicalis immature Sertoli cells (XtiSCs) derived from juvenile testes of X. tropicalis. The objective of this thesis was to induce the differentiation process of XtiSCs into mature Sertoli cells. In vitro experiments using several factors or primary culture from adult male X. tropicalis did not show any mature markers in differentiated XtiSCs. Another experiment using cell culture derived from pubertal mice was partially successful in the induction of the differentiation process. These results indicate that XtiSCs do have some differentiation potential into mature Sertoli cells. Part of this work was to test the ability of testicular cells isolated from juvenile males of X. tropicalis to form de novo organoids. In vitro experiments were successful when these cells were cultured in a three-layer matrigel.
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Genetic mapping in Xenopus
Seifertová, Eva
The diploid amphibian Xenopus tropicalis represents a significant model organism for studies of early development, genes function and evolution. Such techniques as gynogenesis, injection of morpholino antisense oligonucleotide into fertilized eggs or transgenesis were established. In the recent ten years, many efforts have been made to complete the sequence information. X. tropicalis genome has been sequenced but the completion of its assembly only on the basis of sequence data has been impossible. Therefore, our first work was focused on one of approaches for a genome completing- genetic mapping. First of all, the genetic map of Xenopus tropicalis was established pursuant linkage and physical positions of markers. Since the map contained gaps, we developed a new method for genetic mapping based on the next generation sequencing of laser microdissected arm. Using Illumina next generation sequencing of fifteen copies of a short arm of chromosome 7, we obtained new insights into its genome by localizing previously unmapped genes and scaffolds as well as recognizing mislocalized portions of the genome assembly. This was the first time laser microdissection and sequencing of specific chromosomal regions has been used for the purpose of genome mapping. These data were also used in the evolution study of...
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Study of regenerative potential of Sertoli cell progenitors in Xenopus tropicalis tadpoles after tail amputation.
Wróblová, Aneta ; Krylov, Vladimír (advisor) ; Procházka, Jan (referee)
African clawed frogs (Xenopus) represent an ideal model organism for study of regeneration mechanisms. In frogs, complete regeneration occurs in the tadpole stage. In later stages the regeneration capacity is lost. The Laboratory of Developmental biology was successful in establishment of cell culture called Xenopus tropicalis immature Sertoli cells (XtiSCs) derived from X. tropicalis testes. These cells are common progenitors of Sertoli cells and peritubular myoid cells. XtiSCs show similar characteristics as mesenchymal stem cells. MSCs hold interest of scientists for their immunomodulatory properties and multipotent differential and regeneration potential. In this thesis, we studied regeneration and migration potential of XtiSCs after X. tropicalis tadpole's tail amputation in developmental stage 47 - 50. Transgenic XtiSCs culture expressing RFP was prepared to facilitate transplantation experiments. Transplantation experiments showed preferential migration of XtiSCs into the site of injury. XtiSCs transplantations in X. laevis tadpoles with downregulated NO synthases eNOS and nNOS revealed their migratory dependence on nitric oxide signalization. Imunocytochemical staining of XtiSCs in vitro showed positive iNOS, nNOS and Pax7 expression. Imunohistochemical staining of tadpole's tail vibratome...
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Regenerative potential of Sertoli cell progenitors regarding heart injury in Xenopus tropicalis
Onhajzer, Jakub ; Krylov, Vladimír (advisor) ; Procházka, Jan (referee)
Cardiac failure is one of the leading cause of deaths worldwide. Potential therapeutic approach, which overcome invasive organ transplantation and delivery of immunosuppressive drugs, is lacking nowadays. However, research of mesenchymal stem cells (MSCs) therapy displays immunomodulation potential, which can further promote variety of organ regeneration without need of drug treatment. Xenopus tropicalis immature Sertoli cells (XtiSCs) culture was established in our laboratory from juvenile Xenopus tropicalis male. XtiSCs possess immunomodulatory capacity and differentiation to cardiomyocytes after the treatment with the inhibitor of glycogen synthase kinase-3 (GSK-3) CHIR99021. To test the survival rate of transplanted XtiSCs we firstly microinjected treated cells directly inside tadpole's heart. XtiSCs proliferated there for the whole tested time period (30 days). However, after direct heart XtiSCs injection and subsequent cardiac injury in adult frog, no cells were localized in wound area. Thus, we focused on remote control of cardiac regeneration using XtiSCs without CHIR99021 treatment. We injected cells inside skeletal muscle bed and confirmed their survival and proliferation. Moreover, if cells were transplanted 3 days before heart injury, it resulted in significant reduction of fibronectin...
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