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Organelle proteomics of parasitic protists
Jedelský, Petr ; Tachezy, Jan (advisor) ; Kolářová, Libuše (referee) ; Půta, František (referee)
Advances in DNA sequencing led to a technological breakthrough, that allowed analyzis of complete genomes including those of parasitic protists Trichomonas vaginalis and Giardia intestinalis . These organisms are studied not only for their clinical importance, but also from the evolutionary point of view for their adaptation to anaerobic environment. Genome sequencing and annotations of predicted proteins alone did not bring detail view into functioning of their mitochondrion related organelles in G. intestinalis mitosomes, notparticipating in energetic metabolism, in T. vaginalis hydrogenosomes, producing molecular hydrogen and ATP by means of substrate phosphorylation. Traditional methods based on a fractionation by ultracentrifuging in density gradient and subsequent biochemical and enzymological analyzes were extended by one and twodimensional electrophoresis with subsequent identification of proteins by mass spectrometry. Methods of multidimensional separation of peptides produced by specific proteolysis of a complex mixture...
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Protein translocase in the mitosomes of Giardia intestinalis.
Fixová, Ivana ; Doležal, Pavel (advisor) ; Zubáčová, Zuzana (referee)
During the transformation of the bacterial endosymbiont into current mitochondria the protein import apparatus had to be created de novo. The reduced mitochondria (mitosomes) of the parasitic protist Giardia intestinalis represent unique cellular model for the examination of these fundamental transport processes. As the main objective of this project I will try to characterize the motor complex, which propels the protein transport, and also the translocation channel in the inner mitosomal membrane. To this aim I will exploit the presence of two membrane components Pam16 and Pam18, which were discovered in our laboratory, and which constitute the functional core of the motor complex. Based on the information from the analogous systems of yeast and mammalian mitochondria, these two components should physically interact with so far unknown translocation channel. In all other eukaryotes this channel is formed by a conserved protein Tim23. The absence of this protein in the genome of G. intestinalis suggests presence of completely novel, or maybe the original-bacterial protein. Having in hand this simplified mitochodrial model the project has potential to bring not only new data in parasite biology but also generate new information on the function and evolution of mitochondrial protein import.
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Characterization of unique proteins of Giardia intestinalis and their role in mitosomal biogenesis.
Zemanová, Tereza ; Doležal, Pavel (advisor) ; Rada, Petr (referee)
The unicellular parasite Giardia intestinalis is one of the organisms carrying mitochondrion-related organelle known as mitosome, which is adapted to the microaerobic lifestyle. The only known fuction of the mitosome is the synthesis of the iron-sulphur clusters. The research of the mitosomal proteome provides new information on the biogenesis and function of this unusual organelle. One of the means of the mitosome research is the analysis of the interactome of the known mitosomal proteins. The state-of- the-art method of the interactome approach is the use of the chemical crosslinking and the subsequent immunoaffinity isolation of the complexes, containing the protein of interest. In this thesis, the interactomes of GiTom40 and GiMOMP35 were characterized with the bioinformatic tools. The cellular localization of four of the chosen proteins was determined by the fluorescent microscopy. One of the proteins, the predicted dynein intermediate chain DIC6939, was phylogenetically classified as an axonemal dynein. The superresolution microsopy was utilized to observe the possible colocalization of DIC6939 with the mitosomes and blue native PAGE led to the visualization of its native complexes. In this work, the optimal conditions for DIC6939 interactome isolation were succesfully determined. The outcome...
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Investigation of newly discovered protein GL50803_16424 in Giardia intestinalis.
Pelc, Josef ; Doležal, Pavel (advisor) ; Pyrih, Jan (referee)
The anaerobic unicellular eukaryotic organism Giardia intestinalis is a worldwide parasite. Giardiasis, the intestinal disease caused by Giardia, is one of the most common parasitic disease in the developed part of the world, that causes health problems not only to humans but also to animals. This organism is also interesting for its many unique cellular features. One of them is the presence of mitosomes - the organelles derived from mitochondria. Analogously to mitochondria, mitosome is limited by two membranes and shares the mode of the protein transport. However, mitosome does not have its own genome and as far as we know, there is only one pathway of the iron-sulfur cluster biosynthesis in this organelle. Using the in vivo enzymatic tagging technique, several novel mitosomal proteins were identified, including GL50803_16424. The protein GL50803_16424 attracted our attention by interacting with components of all mitosomal subcompartments: the outer membrane, the membrane and the matrix. In addition, the expression of HA-tagged GL50803_16424 resulted in the formation of peculiar structures near the mitosomes never seen before in G. intestinalis. Bioinformatic approaches revealed that the GL50803_16424 has domain similar to the myelodysplasia- myeloid leukemia factor 1-interacting protein. Our...
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Organelle proteomics of parasitic protists
Jedelský, Petr ; Tachezy, Jan (advisor) ; Kolářová, Libuše (referee) ; Půta, František (referee)
Advances in DNA sequencing led to a technological breakthrough, that allowed analyzis of complete genomes including those of parasitic protists Trichomonas vaginalis and Giardia intestinalis . These organisms are studied not only for their clinical importance, but also from the evolutionary point of view for their adaptation to anaerobic environment. Genome sequencing and annotations of predicted proteins alone did not bring detail view into functioning of their mitochondrion related organelles in G. intestinalis mitosomes, notparticipating in energetic metabolism, in T. vaginalis hydrogenosomes, producing molecular hydrogen and ATP by means of substrate phosphorylation. Traditional methods based on a fractionation by ultracentrifuging in density gradient and subsequent biochemical and enzymological analyzes were extended by one and twodimensional electrophoresis with subsequent identification of proteins by mass spectrometry. Methods of multidimensional separation of peptides produced by specific proteolysis of a complex mixture...
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Mitochondria of anaerobic protists
Stoklasa, Michal ; Tachezy, Jan (advisor) ; Rada, Petr (referee)
Mitochondria are organelles of endosymbiotic origin, known as the energy center of every eukaryotic cell. Main function is the production of adenosin triphosphate (ATP), which is used as an energy source for most metabolic reactions occuring in the cell. Furthermore, mitochondria play significant role in apoptosis and we can find here a number of biochemical pathways such as β-oxidation of fatty acids, synthesis of iron- sulfur clusters, heme, steroids etc. Most of the mitochondrial metabolic functions have been lost during the adaptation to oxygen-poor environment in some of the parasitic (Giardia intestinalis, Entamoeba histolytica) or free-living protists (Sawyeria marylandensis, Mastigamoeba balamuthi). These organisms possess reduced mitochondrial organelles such as hydrogenosome or mitosome. The aim of this thesis is to summarize the information about these reduced mitochondrial organelles of anaerobic protists and to describe their specific metabolism. Key words: mitochondrion, hydrogenosome, mitosome
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Reductive Evolution of Mitochondria - Related Organelles in Anaerobic Protist
Rada, Petr ; Tachezy, Jan (advisor) ; Embley, Martin (referee) ; Eliáš, Marek (referee)
Charles University in Prague, Faculty of Science Department of Parasitology Ph.D. study program: Parasitology Abstract of the Ph.D. Thesis Reductive Evolution of Mitochondria - Related Organelles in Anaerobic Protist Petr Rada Supervisor: Prof. RNDr. Jan Tachezy,Ph.D. Advisor: Doc. RNDr. Ivan Hrdý, Ph.D. Praha, 2011 1 ABSTRACT Trichomonas vaginalis and Giardia intestinalis are parasitic protists of the Excavata group. Both contain anaerobic forms of mitochondria called hydrogenosomes (Trichomonas) and mitosomes (Giardia). Hydrogenosomes produce hydrogen and ATP by substarte level phosphorylation and mitosomes represent the highly-reduced form of mitochondria that do not participate in cellular energy metabolism and ATP generation. Both types of organelles lost the majority of mitochondrial pathways and their genomes during the mitochondrion to hydrogenosome transition. Consequently, hydrogenosomes and mitosomes facilitate translocation of nuclearly encoded proteins into the matrix of the organelle as well as exchange of metabolites and ions across their membranes. Little is known about the membrane machineries required for the biogenesis of the organelle and metabolite exchange and the limited knowledge of mitosomal proteomes has been mostly gained from genomic analysis and localization studies of a few...
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Protein translocase in the mitosomes of Giardia intestinalis.
Fixová, Ivana ; Doležal, Pavel (advisor) ; Zubáčová, Zuzana (referee)
During the transformation of the bacterial endosymbiont into current mitochondria the protein import apparatus had to be created de novo. The reduced mitochondria (mitosomes) of the parasitic protist Giardia intestinalis represent unique cellular model for the examination of these fundamental transport processes. As the main objective of this project I will try to characterize the motor complex, which propels the protein transport, and also the translocation channel in the inner mitosomal membrane. To this aim I will exploit the presence of two membrane components Pam16 and Pam18, which were discovered in our laboratory, and which constitute the functional core of the motor complex. Based on the information from the analogous systems of yeast and mammalian mitochondria, these two components should physically interact with so far unknown translocation channel. In all other eukaryotes this channel is formed by a conserved protein Tim23. The absence of this protein in the genome of G. intestinalis suggests presence of completely novel, or maybe the original-bacterial protein. Having in hand this simplified mitochodrial model the project has potential to bring not only new data in parasite biology but also generate new information on the function and evolution of mitochondrial protein import.
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