Maria Rautian

New European stands of Paramecium pentaurelia, Paramecium septaurelia, and Paramecium dodecaurelia, genetic and molecular studies

New stands of rare species of the Paramecium aurelia complex were found in Europe, i.e. P. pentaurelia and P. dodecaurelia in Italy and P. septaurelia in Germany. The species were identified by mating reactions with the standard strains of each species. Their relationships with some other known strains of particular species were studied by classical strain crosses (survival in F1 and F2 generations) and by comparison of RAPD-PCR fingerprints. The presence of the cosmopolitan species P. tetraurelia in Italy was also recorded.

[Obtaining and characterization of “Holospora curviuscula” and Holospora obtusa, bacterial symbionts of the macronuclei of Paramecium bursaria and Paramecium caudatum].

The symbionts of the macronuclei of Paramecium bursaria and P. caudatum, “Holospora curviuscula” 02AZ16 and H. obtusa 88Ti, respectively, were obtained and investigated. The 16S rDNA nucleotide sequences of “Holospora curviuscula” were obtained for the first time. The differences in 16S rDNA (3.4%) suggest their classification within the genus Holospora. Molecular phylogenetic analysis of the symbionts revealed that these intranuclear symbionts of the ciliates belonged to the order Rickettsiales, forming within a compact cluster of related species.

Electrokaryotypes of Macronuclei of Several Paramecium Species

Abstract A comparative study of macronuclear DNA molecules from the following Paramecium species: the P. aurelia complex, P. caudatum, P. bursaria, P. putrinum and P. multimicronucleatum was performed using pulsed-field gel electrophoresis. The electrophoretic pattern was constant and unique for each species, and is referred to herein as its electrokaryotype. Large differences were observed between Paramecium species according to the range and major size of macronuclear DNA fragments, while different strains of the same species, even belonging to different syngens, were characterized by the same electrokaryotype. In this respect sibling species from the P. aurelia complex are as similar as syngens in other Paramecium species, but are unlike conventional species. The principles and value of electrokaryotype analysis for application to ciliates are discussed.

Redescription of an early-derivative mite, Pentasetacus araucariae (Eriophyoidea, Phytoptidae), and new hypotheses on the eriophyoid reproductive anatomy

A unique set of plesiomorphic characters, and its association with an ancient gymnosperm, Araucaria araucana, have made Pentasetacus araucariae a putative relict of a lineage of gymnosperm-associated mites, itself possibly basal to all extant eriophyoids. However, the suboptimal description of this species is impeding morphological comparisons with other species, which are fundamental to eriophyoid systematics. Herein, we designate a female lectotype from syntype specimens and use additional non-type material to redescribe P. araucariae based on external and internal anatomy using different microscopic and 3D reconstruction techniques. Contrarily to statements in the literature, P. araucariae has undivided empodia in all instars, short spermathecal tubes, and large, globose spermathecae in females, as well as rudimentary genital fovea in immatures. In addition, males of P. araucariae were shown to have genitalic attributes similar to a species of Trisetacus studied in parallel, including two reservoir-like structures, which may represent parts of the genital chamber and of the ductus ejaculatorius, respectively, as well as paired testes and ducti deferentes. This is contrary to previous, limited knowledge on eriophyoids indicating that they possess a single testis. Although their short spermathecal tubes weaken the cladistic relationship between P. araucariae (Pentasetacinae) and conifer-associated Nalepellinae (e.g. Trisetacus) having long tubes, the structural similarities in male genitalia may reinforce it.

Polymorphism within Paramecium sexaurelia (Ciliophora, Oligohymenophorea) and description of a new stand of the species in China.

The presence of Paramecium sexaurelia from the Paramecium aurelia complex was recorded for the first time in China (Beijing). RAPD fingerprints (band patterns) of P. sexaurelia strains, the new strain from China and others from Asia, as well as from Europe and Puerto Rico, showed polymorphism within the species as several groups of genotypes characterized by different band patterns.

Does high intraspecific variability of two genome fragments indicate a recent speciation process of Paramecium dodecaurelia (P. aurelia species complex, Ciliophora, Protozoa)?

Species of the Paramecium aurelia complex show different levels of intraspecific polymorphism, with P. dodecaurelia revealing a high level of intraspecific variation. Paramecium dodecaurelia strains originating from distant localities in the Palaearctic, North America (USA), and Oceania (Hawaii) were studied in terms of intraspecific differentiation and the degree of speciation. Sequences of genes encoding the ITS1–5.8S-ITS2–5’ end of LSU rDNA (1063–1097 bp) and cytochrome c oxidase subunit I mtDNA (638–644 bp) were obtained from 33 strains of P. dodecaurelia, other P. aurelia species, and another species of the genus Paramecium, with Tetrahymena sp. used as an outgroup. In phylograms, the majority of P. dodecaurelia strains from the Palaearctic appear in one cluster, while strains from Japan, Hawaii and the USA are grouped in another cluster, together with some strains from Italy and representatives of the P. aurelia species complex. Our results tend to support the hypothesis that P. dodecaurelia seems to be a polyphyletic species with several haplotypes similar to or even shared with other members of the P. aurelia species complex. However, it is still an open question whether the revealed intraspecific differences within P. dodecaurelia are the result of ongoing speciation, or perhaps they just indicate genetic differentiation within a species that has a wide geographic distribution.

Electrophoretic Karyotype Polymorphism of Sibling Species of the Paramecium aurelia Complex

ABSTRACT. Variability of karyotypes is one of the main mechanisms of speciation in organisms. Electrophoretic karyotypes of the macronucleus (MAC) obtained by pulsed‐field gel electrophoresis were compared for 86 strains of all 15 sibling species of the Paramecium aurelia complex in order to determine if karyotype differences corresponded to biological species boundaries. Because the electrophoretic karyotype of the MAC reflects indirectly the frequency and distribution of fragmentation sites in the micronuclear (MIC) chromosomes, any change in MAC electrophoretic karyotype may be a marker of certain chromosomal mutations in the MIC. Thirteen main variants of electrophoretic MAC karyotypes were observed in this species complex. Ten of them appeared to correspond to biological species, while the three other variants characterized several species each. Intraspecific polymorphism was observed for several species: in some cases a certain variant of MAC karyotype was specific for all strains from the same part of the world. Distribution of the MAC karyotype variants along molecular phylogenetic trees of the P. aurelia complex shows that isolation of each species or group of species of this complex was accompanied by divergence in the molecular organization of the genome.

Strains of Paramecium decaurelia (Ciliophora, Protozoa) from Russia with molecular characteristics of other known strains of the species

The presence of Paramecium decaurelia from the Paramecium aurelia species complex was demonstrated in Yaroslavl, Russia, (European part, northwestern Russia) and in the Altai Mts (Asiatic part of Russia, western Siberia). RAPD-PCR fingerprints of the newly identified strains of P. decaurelia, rare throughout the world, were compared to those characteristic for the other known strains ofthe species. P. decaurelia strains show some polymorphism within species, strains from Russia have 60% similarity of band patterns, and strains from USA and Japan about 70% similarity of band patterns.

Delimiting Species Boundaries within a Paraphyletic Species Complex: Insights from Morphological, Genetic, and Molecular Data on Paramecium sonneborni (Paramecium aurelia species complex, Ciliophora, Protozoa)

The demarcation of boundaries between protist species is often problematic because of the absence of a uniform species definition, the abundance of cryptic diversity, and the occurrence of convergent morphology. The ciliates belonging to the Paramecium aurelia complex, consisting of 15 species, are a good model for such systematic and evolutionary studies. One member of the complex is P. sonneborni, previously known only from one stand in Texas (USA), but recently found in two new sampling sites in Cyprus (creeks running to Salt Lake and Oroklini Lake near Larnaca). The studied Paramecium sonneborni strains (from the USA and Cyprus) reveal low viability in the F1 and F2 generations of interstrain hybrids and may be an example of ongoing allopatric speciation. Despite its molecular distinctiveness, we postulate that P. sonneborni should remain in the P. aurelia complex, making it a paraphyletic taxon. Morphological studies have revealed that some features of the nuclear apparatus of P. sonneborni correspond to the P. aurelia spp. complex, while others are similar to P. jenningsi and P. schewiakoffi. The observed discordance indicates rapid splitting of the P. aurelia-P. jenningsi-P. schewiakoffi group, in which genetic, morphological, and molecular boundaries between species are not congruent.

Species of the Paramecium aurelia Complex in Russia (Western Region of European Russia) with Molecular Characteristics of Paramecium novaurelia

The presence of P. primaurelia, P. biaurelia, P. triaurelia, and P. novaurelia of the P. aurelia complex was revealed in the studied region of Russia. RAPD-PCR fingerprints (band patterns) of newly identified P. novaurelia strains from Russia were compared to those characteristic for the other chosen European strains of the species. The strains revealed intraspecific polymorphism as several groups of genotypes confirming the existence of polymorphism within P. novaurelia.