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Chromera velia heme pathway localization
RICHTOVÁ, Jitka
This thesis is focused on the localization of the heme pathway in Chromera velia - the closest known photosynthetic relative of apicomplexan parasites. The heme pathway belongs to essential processes in most living organisms. Organisms use enzymes of various evolutionary origins, reflecting their complex evolutionary history. The core of this study represents the combination of computational and experimental localization of the C. velia heme pathway. We showed that the localization of the heme pathway in the cell is driven by multiple factors, including the demand for pathway products, the need for tight regulation of the pathway, and the evolutionary origin of the enzymes
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Role of a SNARE protein in the biogenesis of Giardia intestinalis mitosomes.
Voleman, Luboš ; Doležal, Pavel (advisor) ; Nohýnková, Eva (referee)
SNARE proteins play essential role in most membrane fusions taking place in eukaryotic cell. They are responsible for all fusions that occur across endocytic and secretory pathways. Apart from these processes stand mitochondria and plastids. Fusion of these organelles is directed by specific protein machineries. In this work we review up-to-date information on SNARE mediated membrane fusion and fusion of outer and inner mitochondrial membranes with an emphasis on situation in flagellated protozoan parasite Giradia intestinalis. It was suggested that one of typical SNARE protein in Giardia (GiSec20) is localised to its highly reduced mitochondria called mitosomes. This protein is also essential for surviving of Giardia trophozoites. In this work we show that mitosomal localization of Gisec20 is caused by episomal expression however the protein is localised to endoplasmic reticulum under physiological conditions. Using GFP tag we were able to characterize its targeting signal which showed to be localised in transmembrane domain of GiSec20. This signal targets the protein to mitosomes of G. intestinalis and S. cerevisiae, respectively. Mitosomal localization was prevented by adding 3'UTR to gene sequence and its episomal expression. This suggests existence of targeting mechanism based on information...
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Protein translocation into hydrogenosomes of "Trichomonas vaginalis"
Radhakrishna Makki, Abhijith ; Tachezy, Jan (advisor) ; Hashimi, Hassan (referee) ; JACKSON, Catherine Lynn (referee)
Mitochondria carry out several important functions in eukaryotic cells such as energy metabolism, iron-sulfur cluster assembly, apoptosis, signaling pathways, protein quality control etc. Most mitochondrial proteins are synthesized on the cytosolic ribosomes and transported to the organelles by the cytosolic chaperones and mitochondrial protein import machinery based on specific targeting signals. Although, the basic principles of protein import have been explained, many questions remain unanswered, particularly for highly modified mitochondria such as hydrogenosomes. The aim of the study was to investigate protein translocation into hydrogenosomes of a human parasite, Trichomonas vaginalis (Tv) with a focus on the composition, function and structure of protein translocases and the role of targeting signals. The translocase of the outer membrane (TOM) is responsible for the import of most proteins into the organelle. Even though, the presence of a TOM complex in trichomonad hydrogenosomes was predicted, its components were not known. Moreover, the generic structure of the mitochondrial TOM complex was not resolved. This study showed that the TvTOM complex is highly divergent consisting of two modified core subunits - channel- forming TvTom40 isoforms and a Tom22-like protein, and two...
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Protein translocation into hydrogenosomes of "Trichomonas vaginalis"
Radhakrishna Makki, Abhijith ; Tachezy, Jan (advisor) ; Hashimi, Hassan (referee) ; JACKSON, Catherine Lynn (referee)
Mitochondria carry out several important functions in eukaryotic cells such as energy metabolism, iron-sulfur cluster assembly, apoptosis, signaling pathways, protein quality control etc. Most mitochondrial proteins are synthesized on the cytosolic ribosomes and transported to the organelles by the cytosolic chaperones and mitochondrial protein import machinery based on specific targeting signals. Although, the basic principles of protein import have been explained, many questions remain unanswered, particularly for highly modified mitochondria such as hydrogenosomes. The aim of the study was to investigate protein translocation into hydrogenosomes of a human parasite, Trichomonas vaginalis (Tv) with a focus on the composition, function and structure of protein translocases and the role of targeting signals. The translocase of the outer membrane (TOM) is responsible for the import of most proteins into the organelle. Even though, the presence of a TOM complex in trichomonad hydrogenosomes was predicted, its components were not known. Moreover, the generic structure of the mitochondrial TOM complex was not resolved. This study showed that the TvTOM complex is highly divergent consisting of two modified core subunits - channel- forming TvTom40 isoforms and a Tom22-like protein, and two...
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In silico characterization of the plastid proteomes of \kur{Chromera Velia\kur{}} and \kur{Vitrella brassicaformis\kur{}}
FAITOVÁ, Tereza
This thesis is focused on identification of the plastid proteome in alveolate algae C. velia and V. brassicaformis. Plastids play an important role in wide scale of biochemical processes. Therefore, targeting of involved enzymes with plastid targeting pre-sequences provide us with better view what function plastid has in the metabolism of chromerids and possibly of their close relatives. The first part of the thesis summarizes the current knowledge about alveolates, chromerids, endosymbiosis, and the principles of protein targeting. The second part describes the in silico analyses done in order to predict the plastid proteomes of both chromerid algae, to compare their plastid metabolism, and to determine the phylogenetic origin of nuclear-encoded plastid proteins.
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Glutamate Carboxypeptidase II as a Drug Target and a Molecular Address for Cancer Treatment
Knedlík, Tomáš ; Konvalinka, Jan (advisor) ; Stiborová, Marie (referee) ; Souček, Pavel (referee)
Glutamate carboxypeptidase II (GCPII), also known as prostate-specific membrane antigen (PSMA), is a membrane metallopeptidase overexpressed on most prostate cancer cells. Additionally, GCPII also attracted neurologists' attention because it cleaves neurotransmitter N-acetyl-L-aspartyl-L-glutamate (NAAG). Since NAAG exhibits neuroprotective effects, GCPII may participate in a number of brain disorders, which were shown to be ameliorated by GCPII selective inhibitors. Therefore, GCPII has become a promising target for imaging and prostate cancer targeted therapy as well as therapy of neuronal disorders. Globally, prostate cancer represents the second most prevalent cancer in men. With the age, most men will develop prostate cancer. However, prostate tumors are life threatening only if they escape from the prostate itself and start to spread to other tissues. Therefore, considerable efforts have been made to discover tumors earlier at more curable stages as well as to target aggressive metastatic cancers that have already invaded other tissues and become resistant to the standard treatment. Since patients undergoing a conventional therapy (a combination of chemotherapy and surgery) suffer from severe side effects, more effective ways of treatment are being searched for. Novel approaches include selective...
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Evaluation of the properties of polymer conjugates which specifically bind proteins and can be used in molecular biology
Parolek, Jan ; Konvalinka, Jan (advisor) ; Liberda, Jiří (referee)
During last three decades, a great effort was invested to the development of polymer conjugates of low molecular drugs with the aim to improve the specific targeting of drugs to diseased tissues, cells and organs. The main reason for this effort was the fact that high molecular weight copolymers have a favourite distribution profile in tissues and organisms. A linker between a polymer backbone and drug has very important role: it is possible to synthesize a biodegradable linker, which can be enzymatically hydrolyzed. Conversely, there is a possibility to synthesize an inert linker, resistant to the hydrolysis. Proper choice of the suitable precursor- polymer is also essential, hence it has to accomplish all of the stringent demands for biocompatibility. Macromolecular polymer-drug conjugates tend to accumulate in solid tumors because of the so called enhanced permeability and retention (EPR) effect. There is a whole range of possible applications of high molecular polymer-drug conjugates. In the introduction part of this thesis, I summarize potential use of drugs based on poly(N-(2-hydroxypropyl)methacrylamide) (HPMA) copolymers. Moreover, I introduce some therapeutically important proteins used in experimental drug discovery. In our laboratory, we have developed a concept of HPMA copolymers...
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Role of a SNARE protein in the biogenesis of Giardia intestinalis mitosomes.
Voleman, Luboš ; Doležal, Pavel (advisor) ; Nohýnková, Eva (referee)
SNARE proteins play essential role in most membrane fusions taking place in eukaryotic cell. They are responsible for all fusions that occur across endocytic and secretory pathways. Apart from these processes stand mitochondria and plastids. Fusion of these organelles is directed by specific protein machineries. In this work we review up-to-date information on SNARE mediated membrane fusion and fusion of outer and inner mitochondrial membranes with an emphasis on situation in flagellated protozoan parasite Giradia intestinalis. It was suggested that one of typical SNARE protein in Giardia (GiSec20) is localised to its highly reduced mitochondria called mitosomes. This protein is also essential for surviving of Giardia trophozoites. In this work we show that mitosomal localization of Gisec20 is caused by episomal expression however the protein is localised to endoplasmic reticulum under physiological conditions. Using GFP tag we were able to characterize its targeting signal which showed to be localised in transmembrane domain of GiSec20. This signal targets the protein to mitosomes of G. intestinalis and S. cerevisiae, respectively. Mitosomal localization was prevented by adding 3'UTR to gene sequence and its episomal expression. This suggests existence of targeting mechanism based on information...
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