Jaroslav Kulda scite author profile

Giardia intestinalis is a binucleated diplomonad possessing four pairs of flagella of distinct location and function. Its pathogenic potential depends on the integrity of a complex microtubular cytoskeleton that undergoes a profound but poorly understood reorganization during cell division. We examined the cell division of G. intestinalis with the aid of light and electron microscopy and immunofluorescence methods and present here new observations on the reorganization of the flagellar apparatus in the dividing Giardia. Our results demonstrated the presence of a flagellar maturation process during which the flagella migrate, assume different position, and transform to different flagellar types in progeny until their maturation is completed. For each newly assembled flagellum it takes three cell cycles to become mature. The mature flagellum of Giardia is the caudal one that possesses a privileged basal body at which the microtubules of the adhesive disk nucleate. In contrast to generally accepted assumption that each of the two diplomonad mastigonts develops separately, we found that they are developmentally linked, exchanging their cytoskeletal components at the early phase of mitosis. The presence of the flagellar maturation process in a metamonad protist Giardia suggests that the basal body or centriole maturation is a universal phenomenon that may represent one of the core processes in a eukaryotic cell.The flagella of eukaryotic protists undergo a remarkable morphogenetic transformation called flagellar developmental cycle, whereby a flagellum passes through a maturation process before assuming its final position in the cell. In contrast to nucleus and some other organelles, which complete their development in a single cell cycle, it is now evident that in many groups of protists flagella require more than one cell cycle to mature (2,26). In this respect, the behavior of flagellar structures in unicellular eukaryotes closely resembles that of centrioles in animal cells (3,25).On division of a flagellate, each daughter cell receives one half of parent flagella and/or basal bodies, while the other half arise de novo. This semiconservative distribution has been known for a long time (reviewed in reference 14). However, until a pioneering study of Melkonian et al. (24) it was not clear how unicellular protists maintain the structural and functional heterogeneity of their flagellar apparatus during division. The observations of Melkonian et al. (24) on the biflagellate heterokont green alga Nephroselmis olivacea provided the first evidence that the heterogeneous flagellar apparatus is conserved in progeny through transformation of a flagellar type during cell division and that a newly formed flagellum requires more than one cell cycle to complete its development. The flagellar transformation has been later found in other groups of unicellular algae (reviewed in reference 2) and in representatives of other taxonomic groups of flagellated freeliving protists (reviewed in reference 26). There are, however, several m...

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Mechanisms of in vitro development of resistance to metronidazole in Trichomonas vaginalis

Rasoloson

Vaňáčová

Tomková

et al. 2002

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Mechanisms of in vitro development of resistance to metronidazole in Trichomonas vaginalisDominique Rasoloson, SB te) pa! nka Van) a! c) ova! , Eva Tomkova! , Jakub Ra! zga, Ivan Hrdy! , Jan Tachezy and Jaroslav Kulda Development of resistance against metronidazole and mechanisms responsible for this process were studied in a sexually transmitted pathogen of humans, Trichomonas vaginalis. Monitoring of changes in metabolism and protein expression that accompanied increasing resistance of strains derived from a common drug-susceptible parent (TV 10-02) showed the multistep character of the process. The aerobic type of resistance known to occur in isolates from patients non-responsive to treatment appeared at the earliest stage, followed by development of the anaerobic type of resistance which was accompanied by gradual loss of hydrogenosomal proteins associated with drug-activating pathways [pyruvate:ferredoxin oxidoreductase (PFOR), hydrogenase, ferredoxin]. Unexpectedly, the loss of PFOR did not result in acquisition of full anaerobic resistance, thus indicating an alternative source of electrons required for the drug activation. These data suggest involvement of the oxidative decarboxylation of malate in hydrogenosomes, catalysed by NAD Mdependent malic enzyme and subsequent transfer of reduced equivalents to the drug via NADH :ferredoxin oxidoreductase and ferredoxin. Accordingly, all components of this pathway were eliminated before the resistance was fully developed. Resistant Trichomonas vaginalis compensated the impaired function of hydrogenosomes by enhanced conversion of pyruvate to lactate in the cytosol. Further analysis of the two key enzymes involved in metronidazole activation by Northern blotting and assay for nascent mRNA showed that the insufficient expression of the PFOR protein results from decreased gene transcription, while down-regulation of malic enzyme is controlled at the mRNA level.

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New evolutionary lineages, unexpected diversity, and host specificity in the parabasalid genus Tetratrichomonas

Čepička

Hampl

Kulda

et al. 2006

Molecular Phylogenetics and Evolution

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Jaroslav Kulda

Trichomonads, hydrogenosomes and drug resistance

Critical Taxonomic Revision of Parabasalids with Description of one New Genus and three New Species

Cell Division of Giardia intestinalis : Flagellar Developmental Cycle Involves Transformation and Exchange of Flagella between Mastigonts of a Diplomonad Cell

Mechanisms of in vitro development of resistance to metronidazole in Trichomonas vaginalis

New evolutionary lineages, unexpected diversity, and host specificity in the parabasalid genus Tetratrichomonas

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