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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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Evolution of mitochondrial protein import
Dohnálek, Vít ; Doležal, Pavel (advisor) ; Novotný, Marian (referee)
1 Abstract Even though mitochondria possess their own genome and ribosomes, majority of mitochondrial proteins is encoded in the nucleus and translated by cytosolic ribosomes. Hence it was necessary to establish transport complexes allowing the import of proteins from the cytosol. These complexes are best described in yeast. However, we are encountering organisms lacking many of the subunits of these complexes with increasing frequency. Therefore, we are presenting the overview of the distribution of the subunits within eukaryotic organisms. We specifically take a closer look at parasitic protist Giardia intestinalis that is well known for its extreme reductions of the import complexes. There have been only few subunits identified so far. Porin Tom40, that is responsible for translocating all the incoming proteins across the outer mitochondrial membrane, has been identified despite the high divergence, while homolog of Sam50 hasn't been successfully identified yet. Sam50 is however believed to be necessary for insertion of Tom40 into the membrane. Vast part of this thesis is dedicated to this phenomenon that is highly uncommon and maybe unique among the eukaryotic organisms.
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Protein import into mitochondria and peroxisomes of parasitic protists
Žárský, Vojtěch ; Tachezy, Jan (advisor) ; Hampl, Vladimír (referee)
The presented thesis includes three related projects, that are linked by a common interest in the evolution of eukaryotic organelles and machineries that import proteins into these compartments. The first project considers the possibility of peroxisomes (eukaryotic organelles known in aerobic organisms) being conserved in two related anaerobic protists: a free-living amoeba Mastigamoeba balamuthi and a parasite Entamoeba histolytica. The most important hint for the presence of peroxisomes was the discovery of proteins that are homologous to known components of the peroxisomal protein import machinery. The second project aims to characterize the unknown protein translocase of the inner membrane (TIM) in the mitosomes (extremely reduced mitochondria) of an anaerobic protozoan Giardia intestinalis. We have discovered an important subunit of the mitosomal translocase (Tim44), which usually tethers the Hsp70/PAM (presequence translocase-associated motor) complex to the TIM translocon. The last project shows that the protein translocase of the outer mitochondrial membrane in trypanosomatids is related to a typical eukaryotic channel Tom40. This finding is important because the absence of Tom40 was previously considered an ancestral feature of trypanosomatids.
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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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Genomic and Cellular Integration in the Tripartite Nested Mealybug Symbiosis
HUSNÍK, Filip
The PhD thesis is composed of three publications on genomic, metabolic, and cellular integration between the host and its symbionts in the tripartite nested mealybug system. The articles revealed a path to an intimate endosymbiosis that can be compared to what we think happened before (and to some extent after) bacterial ancestors of key eukaryotic organelles, mitochondria and plastids, became highly integrated into their host cells. I argue that these much younger symbioses may tell us something about how the mitochondria and plastids came to be, at the very least by revealing what types of evolutionary events are possible as stable intracellular relationships proceed along the path of integration.
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