Local damage detection by nonlinear coda wave interferometry combined with time reversal.

Coda wave interferometry (CWI) is a sensitive ultrasound method for the detection of weak and local changes in complex inhomogeneous media. In a nonlinear modification of the method discussed here, a high-frequency probe coda is compared to its replica obtained in the presence of low-frequency pumping. If, after the filtering-out of low frequencies, the coda signals are different, this is attributed to nonlinear pump-probe interaction induced by contact acoustical nonlinearity in the damaged zone. Actually, the CWI methods are used for global inspection of complex media, such as for example, concrete structures. In this work, a step forward is made; it consists in combining the CWI with the time-reversal (TR) technique in order to allow one to focus the pump wave on a selected area in the structure and to detect and localize a flaw. Time-reverse pump is possible only in pulsed mode due to the spatio-temporal wave compression. By this reason, the particularities of coda wave mixing in conventionally used continuous and pulsed pump mode are considered. It has been experimentally observed that an aftereffect of a pulsed pump provides a nonlinear interaction between pump and probe waves of a sufficient overall level for defect detection with TR. Finally, it was shown that a TR focusing even with the minimal available quality i.e., with only one transducer produces a sufficient contrast allowing to distinguish intact and damaged zones with nonlinear CWI.

Primary Structure of 28S rRNA Gene Confirms Monophyly of Free-Living Heterotrophic and Phototrophic Apicomplexans (Alveolata).

Phylogenetic analysis of large subunit ribosomal RNA (LSU rRNA or 28S rRNA) gene sequences from free-living predatory flagellates Colpodella angusta, Voromonas pontica, and Alphamonas edax (Apicomplexa) confirms their close relationship with chromerids Chromera velia and Vitrella brassicaformis, which possess a functional photosynthetic plastid. Together these organisms form a sister group to parasitic apicomplexans (coccidians and gregarines, or sporozoans sensu lato). This result agrees with the previous conclusion on monophyly of colpodellids and chromerids (chrompodellids) based on phylogenomic data. The revealed relationships demonstrate a complex pattern of acquisition, loss, or modification of plastids and transition to parasitism during alveolate evolution.

Phylogenetic analysis of entomoparasitic nematodes, potential control agents of flea populations in natural foci of plague.

Entomoparasitic nematodes are natural control agents for many insect pests, including fleas that transmit Yersinia pestis, a causative agent of plague, in the natural foci of this extremely dangerous zoonosis. We examined the flea samples from the Volga-Ural natural focus of plague for their infestation with nematodes. Among the six flea species feeding on different rodent hosts (Citellus pygmaeus, Microtus socialis, and Allactaga major), the rate of infestation varied from 0 to 21%. The propagation rate of parasitic nematodes in the haemocoel of infected fleas was very high; in some cases, we observed up to 1,000 juveniles per flea specimen. Our study of morphology, life cycle, and rDNA sequences of these parasites revealed that they belong to three distinct species differing in the host specificity. On SSU and LSU rRNA phylogenies, these species representing three genera (Rubzovinema, Psyllotylenchus, and Spilotylenchus), constitute a monophyletic group close to Allantonema and Parasitylenchus, the type genera of the families Allantonematidae and Parasitylenchidae (Nematoda: Tylenchida). We discuss the SSU-ITS1-5.8S-LSU rDNA phylogeny of the Tylenchida with a special emphasis on the suborder Hexatylina.

[On the phylogenetic position of Hexapoda within the Pancrustacea].

Contemporary views on the phylogeny of arthropods are at odds with the traditional system, which recognizes four independent arthropod classes: Chelicerata, Crustacea, Myriapoda and Insecta. There is compelling evidence that insects in fact comprise a monophyletic lineage with Crustacea within a larger clade of Pancrustacea (=Tetraconata). Which crustacean group is the closest living relative of insects remains an open question. Recent phylogenetic analyses based on multiple genes suggest their sistership with "lower" crustaceans, the Branchiopoda. This relationship was often impeached to be caused by the long branch attraction artifact. We analyzed concatenated data on 77 ribosomal proteins, elongation factor 1 alpha (EF1A), initiation factor 5 alpha (alF5A) and other selected nuclear and mitochondrial proteins. Nuclear protein data supports the monophyly of Hexapoda, the clade uniting entognath and ectognath insects. Hexapoda and Branchiopoda comprise a monophyletic lineage in most analyses. Maxillopoda occupies the sister position to the Hexapoda + Branchiopoda. "Higher" crustaceans, the Malacostraca, in most reconstructions comprise a more basal lineage withinthe Pancrustacea. Molecular synapomorphies in low homoplastic regions are found for the clades Hexapoda Branchiopoda + Maxillopoda and the monophyletic Malacostraca containing the Phyllocarida. Therefore, the sistership of Hexapoda and Branchiopoda and their position within Entomostraca may in fact represent bona fide phylogenetic relationships.

[Molecular phylogeny of gastrotricha based on 18S rRNA genes comparison: rejection of hypothesis of relatedness with nematodes].

Gastrotrichs are meiobenthic free-living aquatic worms whose phylogenetic and intra-group relationships remain unclear despite some attempts to resolve them on the base of morphology or molecules. In this study we analysed complete sequences of the 18S rRNA gene of 15 taxa (8 new and 7 published) to test numerous hypotheses on gastrotrich phylogeny and to verify whether controversial interrelationships from previous molecular data could be due to the short region available for analysis and the poor taxa sampling. Data were analysed using both maximum likelihood and Bayesian inference. Results obtained suggest that gastrotrichs, together with Gnathostomulida, Plathelminthes, Syndermata (Rotifera + Acanthocephala), Nemertea and Lophotrochozoa, comprise a clade Spiralia. Statistical tests reject phylogenetic hypotheses regarding Gastrotricha as close relatives of Nematoda and other Ecdysozoa or placing them at the base of bilaterian tree close to acoels and nemertodermatides. Within Gastrotricha, Chaetonotida and Macrodasyida comprise two well supported clades. Our analysis confirmed the monophyly of the Chaetonotidae and Xenotrichulidae within Chaetonida as well as Turbanellidae and Thaumastodermatidae within Macrodasyida. Mesodasys is a sister group of the Turbanellidae, and Lepidodasyidae appears to be a polyphyletic group as Cephalodasys forms a separate lineage at the base of macrodasyids, whereas Lepidodasys groups with Neodasys between Thaumastodermatidae and Turbanellidae. To infer a more reliable Gastrotricha phylogeny many species and additional genes should be involved in future analyses.

Do we need many genes for phylogenetic inference?

Fifty-six nuclear protein coding genes from Taxonomically Broad EST Database and other databases were selected for phylogenomic-based examination of alternative phylogenetic hypotheses concerning intergroup relationship between multicellular animals (Metazoa) and other representatives of Opisthokonta. The results of this work support sister group relationship between Metazoa and Choanoflagellata. Both of these groups form the taxon Holozoa along with the monophyletic Ichthyosporea or Mesomycetozoea (a group that includes Amoebidium parasiticum, Sphaeroforma arctica, and Capsaspora owczarzaki). These phylogenetic hypotheses receive high statistical support both when utilizing whole alignment and when only 5000 randomly selected alignment positions are used. The presented results suggest subdivision of Fungi into Eumycota and lower fungi, Chytridiomycota. The latter form a monophyletic group that comprises Chytridiales+Spizellomycetales+Blastocladiales (Batrachochytrium, Spizellomyces, Allomyces, Blastocladiella), contrary to the earlier reports based on the analysis of 18S rRNA and a limited set of protein coding genes. The phylogenetic distribution of genes coding for a ubiquitin-fused ribosomal protein S30 implies at least three independent cases of gene fusion: in the ancestors of Holozoa, in heterotrophic Heterokonta (Oomycetes and Blastocystis) and in the ancestors of Cryptophyta and Glaucophyta. Ubiquitin-like sequences fused with ribosomal protein S30 outside of Holozoa are not FUBI orthologs. Two independent events of FUBI replacement by the ubiquitin sequence were detected in the lineage of C. owczarzaki and in the monophyletic group of nematode worms Tylenchomorpha+Cephalobidae. Bursaphelenchus xylophilus (Aphelenchoidoidea) retains a state typical of the rest of the Metazoa. The data emphasize the fact that the reliability of phylogenetic reconstructions depends on the number of analyzed genes to a lesser extent than on our ability to recognize reconstruction artifacts.

[Export of metabolites by the proteins of the DMT and RhtB families and its possible role in intercellular communication].

The earlier published and new experimental data are summarized on the properties of the genes encoding the membrane proteins of the DMT family (RhtA (YbiF), EamA (YdeD), YijE, YddG, YedA, PecM, eukaryotic nucleoside phosphate sugar and hexose phosphate transporters), the RhtB/LysE family (RhtB, RhtC, LeuE, YahN, EamB (YfiK), ArgO (YggA), CmaU), as well as some other families (YicM, YdhC, YdeAB, YdhE (NorE)). These proteins are involved in the export of amino acids, purines, and other metabolites from the cell. The expression of most of the genes encoding these proteins is not induced by the substrates they transport but is controlled by the global regulation systems, such as the Lrp protein, and activated by the signal compounds involved in the intracellular communication. The level of expression, assessed in experiments on translational fusion of the corresponding bacterial genes with the beta-galactosidase gene, depends on the growth phase of the bacterial culture, composition of the medium, and some stress factors, such as pH osmolarity or decreased aeration. The efflux of normal cell metabolites is assumed to be the natural function of these proteins. This function may play a role in density-dependent behavior of cell populations (quorum sensing). It may have been enhanced in the course of evolution via specialization of these proteins in the efflux of compounds derived from metabolic intermediates and adjusted to the role of transmitters.

[Characterization of enterobacteria producing the low-molecular-weight antibiotics microcins]. / Kharakteristika énterobakterii, produtsiruiushchikh mikrotsiny--nizkomolekuliarnye antibiotiki.

A comparative study of the morphological, cultural, physiological, and biochemical properties of the microcinogenic strains EcS 5/98, EcS 6/98, and EcB 214/99 with the known microcin C51 producer Escherichia coli M17(p74) showed that these strains belong to the species E. coli. The strains produced microcins with molecular masses lower than 10 kDa. Microcin biosynthesis was stimulated by a deficiency of nutrients in the cultivation media. Microcins were found to be resistant to thermolysin, but were degraded by pronase, protolichetrem, and the Bacillus mesentericus metalloproteinase. This indicated that microcins are peptides or contain peptides in their molecules. The study of cross immunity to microcins and the sequence of their genetic determinants showed that the microcins of strains EcS 5/98 and EcS 6/98 are of B type, whereas the microcin of strain EcB 214/99 presumably belongs to another type, since it suppresses the growth of the producers of C-type and B-type microcins. The new microcin producers possess antibacterial activity against natural isolates belonging to the genera Escherichia and Salmonella, against a wide range of colicinogenic Escherichia strains, and against the collection Salmonella cultures.

[Expression vector pLF22 for the lactic acid bacteria]. / Vektor pLF22 dlia ékspressii genov v molochnokislykh bakteriiakh.

The construction of the expression vector pLF22 for lactic acid bacteria is described. The vector contains a replicon of the cryptic plasmid pLF1311 from Lactobacillus fermentum and a multiple cloning site of the lacZ' gene integrated with the plasmid rep operon. Such a construction of the vector provides for the constitutive transcription of the cloned sequences lacking the terminators of transcription in all the strains that maintain the replication of the vector. The vector is suitable for a wide range of gram-positive and gram-negative bacteria, including probiotic strains. The efficiency of the vector was verified by expressing the beta-galactosidase gene in a laboratory Escherichia coli strain and the synthetic gene of somatotropin releasing factor (SRF) in the probiotic strains of lactobacilli and enterococci. A recombinant strain with the SRF gene included in the diet of laboratory animals exerted an effect on their physiological and anthropometric parameters and on the histological characteristics of animal tissues.

[Whether variable cleavage of Enoplida (Nematoda) is primitive? Notes to D.A. Voronov article "Comparative embryology of Nematoda and the law of embryologic similarity]. / Primitivno li variabel'noe drobleniie Enoplida (Nematoda)? Zamechanie k stat'e D.A.Voronova "Sravnitel'naia émbriologiia nematod i zakon zarodyshevogo skhodstva".

The early embryonic development of Nematoda proceeds by three ways, which strictly correspond to three phylogenetic lineages. Under the first way the endodermal precursor is localized in the posterior blastomere at the two-cells stage (such a determination is the peculiarity of all the Chromadoria, including Secernentea and Caenorhabditis elegans). Under the second way the endodermal precursor is localized in the anterior blastomere of the egg. This feature is very unusual for Metazoa, but it is the only way of entoderm determination in all the Dorylaimia orders (Mononchida, Mermithida, Trichinellida, Dioctophymida, Dorylaimida). The third way described for the sea Enoplida is characterized with variable location of blastomers and changeable localization of endodermal precursor before eight-cells stage. It is still unknown of these three variants was typical the most recent common ancestor of present Nematoda. D.A. Voronov (2001) produced argument in favour of variable cleavage as primitive one for Nematoda. This opinion is rejected because of the similarity in development between sea Enoplida and C. elegans. Both of them share such features as low-cell gastrula and neurula, identical phylotypic lima bean stage of embryogenesis, identity of some geometrical figures 4 or 8 blastomers, isolating of the endodermal precursor at the eight-cells stage, the lack in development of any plesiomorphous features, which are widely distributed outside Nematoda (under the variable cleavage of Enoplida there are no such locations of blastomers, which are typical for spiral or radial cleavage, there are no embryonic leaves as well). One can see the homology of separate cells at adult Enoplida and Rhabditia. Cell lineage of Triplonchida as far as it is described at Tobrilus gracilis doesn't exclude the hypothesis on their origin from the cleavage similar to one of present Dorylaimia with localization of the endodermal precursor in the anterior blastomere. In view of all the considerations mentioned above one should interpret variable cleavage of Enoplida as derivation from invariant cleavage.

[On the genetic uniformity of the genus Trichoplax (Placozoa)]. / O geneticheskom odnoobrazii v rode Trichoplax (Placozoa).

Fragments of the nuclear and mitochondrial genes for the large-subunit rRNA were compared for Trichoplax sp. and T. adhaerens. High similarity was observed for their sequences, suggesting that different Trichoplax isolates belong to one species.

[Conditionally neutral phylogenetic markers of major taxa: a new aspect of the evolution of macromolecules]. / Uslovno-neitral'nye filogeneticheskie priznaki krupnykh taksonov--novyi aspekt évoliutsii makromolekul.

The current phase of molecular phylogenetics can be named the 18S rRNA gene era, which is now approaching the end. To date, almost all phyla of metazoans and many taxa of protists are represented in databases of 18S rRNA gene sequences. The elements of the phylogenetic tree of Metazoa inferred from 18S rRNA genes are characterized by unequal validity: some of them seem to be well grounded; others are not adequately supported, and probably will be revised later. The validity of phylogenetic reconstruction is influenced by two main factors: (1) erroneous grouping of long branches that occur because of abnormally high evolution rate; (2) deficit of phylogenetically informative characters. A method for overcoming these difficulties is suggested in addition to known tools: using phylogenetic markers that are stable within individual taxa and evolve by punctuated equilibrium. These markers are least influenced by the convergence caused by a high evolution rate of the entire gene. The nature of these markers of ancient taxa, paradoxical from the perspective of neutral evolution, is discussed, as well as their importance for establishing monophyly of both new large-scale taxonomic groups of invertebrates (Bilateria + Rhombozoa + Orthonectida + Myxozoa + Cnidaria + Placozoa and Echinodermata + Hemichordata) and some major taxa of Nematoda.

[Molecular evidence of regression in evolution of metazoa]. / Molekuliarnye svidetel'stva regressa v évoliutsii mnogokletochnykh zhivotnykh.

Molecular data permit to construct phylogenetic trees independently of morphological characters. It allows to consider their evolution without the frames of a priori hypothesis of regularities of morphological evolution and independently of palaeontological data. Cladistic analysis of elements of secondary structure of varible areas V7 and V2 in 18S rRNA with different Protozoa as "external" groups shows that Bilateria + Cnidaria are monophyletic, Ctenophora and Porifera are early derivatives of Metazoa, Trichoplax (Placozoa) is a form related to Cnidaria, while Rhombozoa, Orthonectida and Myxozoa were branched within Bilateria. Morphological reduction with losses of any organs and tissues took place many times in early evolution of Metazoa and Bilateria not only in parasitic species. It occurred both at early and late stages of embryonic development and differentiation. Two alternative scenario of morphological degeneration in Trichoplax and the way of their testing are suggested. The similarity of Ctenophora and Calcarea is discussed. Meridional or oblique position of the third cleavage furrow of ovule can be considered as an evidence of their origin from common ancestor.

[Primary structure of hairpin 35 and 48 small rRNA is proof that Trefusiidae is a subtaxon of marine Enoplida (Nemotoda)]. / Pervichnaia struktura petel' 35 i 48 maloi rRNK svidetel'stvuet, chto Trefusiidae iavliaiutsia subtaksonom morskikh Enoplida (Nematoda).

A rare nucleotide substitution was found in the evolutionarily conserved loop of hairpin 35 of the 18S rRNA gene of marine free-living nematode, Trefusia zostericola (Nematoda: Enoplida). The same substitution was found in all the marine Enoplida studied but not in other nematodes. Such a molecular synapomorphy indicates that marine enoplids are more closely related to T. zostericola than to freshwater Triplonchida. Maximum parsimony, neighbor-joining, and maximum likelihood analyses of complete nucleotide sequences of the gene, with the heterogeneity of nucleotide sites in evolution rates taken into account, support this conclusion. Hence, the hypothesis of particular primitiveness of Trefusiidae among nematodes should be rejected. Phylogenies based on molecular data support the morphological reduction of metanemes in Trefusiidae. Alongside with the unique change in hairpin 35 loop among marine Enoplida (including T. zostericola), hairpin 48 is also modified by a rare transversion which could be found among Mesorhabditoidea nematodes, in related genera Pelodera, Mesorhabditis, Teratorhabditis, Parasitorhabditis, Crustorhabditis, and Distolabrellus, and in 11 orders of Rhodophyta. Rare mutations in hairpins 35 and 48 tend to be fixed correlatively in evolution and could be found in all the Acanthocephala species. X-Ray data show that these regions (H31 and H43, in alternative nomenclature) are spatially brought together in native ribosomes. The nature and distribution of molecular autoapomorphies in phylogenetic trees of high-rank taxa are discussed.

The unusually long small subunit ribosomal RNA gene found in amitochondriate amoeboflagellate Pelomyxa palustris: its rRNA predicted secondary structure and phylogenetic implication.

In order to ascertain a phylogenetic position of the freshwater amitochondriate amoeboflagellate Pelomyxa palustris its small subunit (SSU) rRNA gene was amplified and sequenced. It was shown to be 3502 bp long. The predicted secondary structure of its rRNA includes at least 16 separate expansion zones located in all the variable regions (V1-V9), as well as in some conservative gene regions. Most insertions are represented by sequences of low complexity that have presumably arisen by a slippage mechanism. Relatively conservative, uniformly positioned motifs contained in regions V4 and V7, as well as in some others, made it possible to perform folding. In maximum likelihood, maximum parsimony, and neighbor-joining trees, P. palustris tends to cluster with amitochondriate and secondary lost mitochondria amoebae and amoeboflagellates Entamoeba, Endolimax nana, and Phreatamoeba balamuthi, comprising together with them and aerobic lobose amoebae Vannella, Acanthamoeba, Balamuthia, and Hartmannella a monophyletic cluster. Another pelobiont, Mastigamoeba invertens, does not belong to this cluster. No specific similarity was discovered between the SSU rRNA of P. palustris and amitochondriate taxa of 'Archezoa': Diplomonada, Parabasalia, Microsporidia. Pelomyxa palustris SSU rRNA does not occupy a basal position in the phylogenetic trees and could be ascribed to the so-called eukaryotic 'crown' group if the composition of the latter were not so sensitive to the methods of tree building. Thus, molecular and morphological data suggest that P. palustris represents a secondarily modified eukaryotic lineage.

[A family of shuttle vectors for lactobacilli and other gram-positive bacteria based on the plasmid pLF1311 replicon]. / Semeistvo chelnochnykh vektorov dlia molochnokislykh i drugikh grampolozhitel'nykh bakterii osnovannykh na replikone plazmidy pLF1311.

A set of broad-host-range single-replicon shuttle vectors for cloning nucleotide sequences in gram-positive bacteria (lactobacilli, enterococci, lactococci, bacilli, etc.) was created. The vectors are based on the cryptic plasmid pLF1311 from Lactobacillus fermentum VKM 1311 belonging to a family of the sigma-type pE194-like plasmids. The vectors can replicate in gram-positive bacteria and Escherichia coli. They are stable in many gram-positive bacteria, have small sizes, and allow the selection of recombinants on media with X-Gal. The vectors that contain the region of initiation of the conjugal transfer of plasmid RP4 belonging to the incompatibility group IncP alpha can be mobilized in a great number of bacteria using a helper plasmid from E. coli but not from gram-positive bacteria.

The broad host range plasmid pLF1311 from Lactobacillus fermentum VKM1311.

The complete nucleotide sequence (2389 bp) of the cryptic plasmid pLF1311 from Lactobacillus fermentum VKM1311 was determined. DNA sequence analysis revealed the putative coding regions for a replicative protein (RepB), its repressor (RepA) and double-stranded (dso) and single-stranded (sso) origins. pLF1311 belongs to the pE194 family of rolling circle-replicating plasmids. A derivative of pLF1311 that contains the cat gene of plasmid pC194 of Staphylococcus aureus and the oriT of RP4 was constructed and transferred by conjugative mobilization from Escherichia coli to various Gram-positive bacteria. The stable maintenance of this derivative was shown in some strains of Lactobacillus, Lactococcus, Enterococcus and Bacillus under non-selective conditions.

The novel transmembrane Escherichia coli proteins involved in the amino acid efflux.

A novel gene of Escherichia coli, rhtB, has been characterized. Amplification of this gene provides resistance to homoserine and homoserine lactone. Another E. coli gene, rhtC, provides resistance to threonine. The homologues of RhtB are widely distributed among various eubacteria and archaea, from one to 12 copies of family members that differ in their primary structure were found in the genomes. Most of them are genes that encode hypothetical transmembrane proteins. Experimental data that indicate participation of the rhtB product in the excretion of homoserine have been obtained.