Molecular complexity of Paramecium symbiont lambda deoxyribonucleic acid: evidence for the presence of a multicopy genome

The Genome Sequence of "Candidatus Fokinia solitaria": Insights on Reductive Evolution in Rickettsiales

"Candidatus Fokinia solitaria" is an obligate intracellular endosymbiont of a unicellular eukaryote, a ciliate of the genus Paramecium. Here, we present the genome sequence of this bacterium and subsequent analysis. Phylogenomic analysis confirmed the previously reported positioning of the symbiont within the "Candidatus Midichloriaceae" family (order Rickettsiales), as well as its high sequence divergence from other members of the family, indicative of fast sequence evolution. Consistently with this high evolutionary rate, a comparative genomic analysis revealed that the genome of this symbiont is the smallest of the Rickettsiales to date. The reduced genome does not present flagellar genes, nor the pathway for the biosynthesis of lipopolysaccharides (present in all the other so far sequenced members of the family "Candidatus Midichloriaceae") or genes for the Krebs cycle (present, although not always complete, in Rickettsiales). These results indicate an evolutionary trend toward a stronger dependence on the host, in comparison with other members of the family. Two alternative scenarios are compatible with our results; "Candidatus Fokinia solitaria" could be either a recently evolved, vertically transmitted mutualist, or a parasite with a high host-specificity.

Characterization of the genome of the small free-living amoeba Acanthamoeba castellanii

The cellular DNAs of Acanthamoeba castellanii have been characterized by their behaviour in CsC1 density gradients, by their thermal denaturation and by their renaturation kinetics. Whole-cell DNA exhibits, on CsC1 density gradients, a major peak with a density of 1.717 g/cm3 (major component) and a minor peak with a density of 1.692 g/cm3 (minor component). The major component is nuclear and the minor component is of cytoplasmic origin. The latter contains mitochondrial DNA as well as an extramitochondrial DNA fraction. Reiterated sequences make up approximately 14% of the total and are mainly cytoplasmic. They are characterized by three families of nucleotide sequences. The mitochondrial DNA exhibits a complex renaturation pattern. The fast renaturing component has a calculated complexity of 4.107 daltons. The slower renaturing component has a kinetic complexity tentatively estimated as 1.1010 daltons. The melting profile of mitochondrial DNA suggests heterogeneity in base composition.

Isolation of intracellular symbiotes by immune lysis of flagellate protozoa and characterization of their DNA

A new method dependent on immune lysis is described for the isolation of intracellular symbiotes from two species of flagellate protozoa Blastocrithidia culicis and Crithidia oncopelti. The symbiote-containing flagellates are exposed to complement and antisera prepared in rabbits against symbiote-free organisms. The immune lysis seems to weaken the plasma membranes of the flagellates so that subsequent application of gentle shearing force liberates the intracellular entities in an undamaged condition. The symbiotes are then separated from other cellular components by DNAse digestion and differential centrifugation. The average recovery of symbiotes isolated by this method is 20%. Light and electron microscopy establishes the structural integrity and numerical abundance of isolated symbiotes in the final fractions. Integrity of symbiotes is further indicated by the high activity of a marker enzyme, uroporphyrinogen I synthetase. The DNA's of symbiote-containing and symbiote-free flagellates, and of isolated symbiotes were purified and compared after isopycnic centrifugation. The comparison establishes the presence of DNA's in symbiotes of both species. The guanine-cytosine (G-C) content of symbiote DNA differs from that of host DNA's in C. oncopelti, but resembles that of kinetoplast DNA in B. culicis. The latter observation was further shown by heat denaturation study. Renaturation kinetics indicate that the genome complexity of symbiote DNA in B. culicis is similar to that of bacteria.

Kappa and other endosymbionts in Paramecium aurelia

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The molecular complexity of mu and pi symbiont DNA of Paramecium aurelia

The molecular size of mu and pi symbionts of Parameciumaurelia has been calculated from renaturation kinetic data. Observed values were 0.78 x 10(9) daltons for mu particle DNA and 0.81 x 10(9) daltons for pi particle DNA. Estimates of analytical complexity were 4.45 x 10(9) and 5.05 x 10(9) daltons respectively. Based on these data, mu and pi symbionts appear to possess multiple genomes and contain a minimum of 5 or 6 copies of each DNA sequence.