Pleiotropic effect of thyroid hormones on gene expression in fish as exemplified from the blue bream Ballerus ballerus (Cyprinidae): Results of transcriptomic analysis.

A pronounced pleiotropic effect of thyroid hormones on the regulation of gene expression in fish in postembryogenesis was demonstrated for the first time using larvae and juveniles of the blue bream Ballerus ballerus as an example. Genome-wide transcriptome sequencing (RNA-seq) identified 1212 differentially expressed genes in the brain and liver of fish kept in triiodothyronine solution (0.25 ng/mL). Our data show that the regulation of gene expression by thyroid hormones is widespread in nature: it involves not only the structural genes but also the regulatory genes. A significant number of genes under the control of thyroid hormones are involved in the determination of morphological traits.

ArdA genes from pKM101 and from B. bifidum chromosome have a different range of regulated genes.

The ardA genes are present in a wide variety of conjugative plasmids and play an important role in overcoming the restriction barrier. To date, there is no information on the chromosomal ardA genes. It is still unclear whether they keep their antirestriction activity and why bacterial chromosomes contain these genes. In the present study, we confirmed the antirestriction function of the ardA gene from the Bifidobacterium bifidum chromosome. Transcriptome analysis in Escherichia coli showed that the range of regulated genes varies significantly for ardA from conjugative plasmid pKM101 and from the B. bifidum chromosome. Moreover, if the targets for both ardA genes match, they often show an opposite effect on regulated gene expression. The results obtained indicate two seemingly mutually exclusive conclusions. On the one hand, the pleiotropic effect of ardA genes was shown not only on restriction-modification system, but also on expression of a number of other genes. On the other hand, the range of affected genes varies significally for ardA genes from different sources, which indicates the specificity of ardA to inhibited targets. Author Summary. Conjugative plasmids, bacteriophages, as well as transposons, are capable to transfer various genes, including antibiotic resistance genes, among bacterial cells. However, many of those genes pose a threat to the bacterial cells, therefore bacterial cells have special restriction systems that limit such transfer. Antirestriction genes have previously been described as a part of conjugative plasmids, and bacteriophages and transposons. Those plasmids are able to overcome bacterial cell protection in the presence of antirestriction genes, which inhibit bacterial restriction systems. This work unveils the antirestriction mechanisms, which play an important role in the bacterial life cycle. Here, we clearly show that antirestriction genes, which are able to inhibit cell protection, exist not only in plasmids but also in the bacterial chromosomes themselves. Moreover, antirestrictases have not only an inhibitory function but also participate in the regulation of other bacterial genes. The regulatory function of plasmid antirestriction genes also helps them to overcome the bacterial cell protection against gene transfer, whereas the regulatory function of genomic antirestrictases has no such effect.

[Antimodification activity of the ArdA and Ocr proteins].

The ArdA and Ocr antirestriction proteins, whose genes are in transmissible plasmids (ardA) and bacteriophage genomes (0.3 (ocr)), specifically inhibit type I restriction-modification enzymes. The Ocr protein (T7 bacteriophage) was shown to inhibit both restriction (endonuclease) and modification (methylase) activities of the EcoKI enzyme in a broad range of intracellular concentrations (starting from 10-20 molecules per cell). In contrast to Ocr, the ArdA protein (ColIb-P9 transmissible plasmid) inhibited both of the EcoKI activities only at high intracellular concentrations (30000-40000 molecules per cell). When the ArdA concentration was several fold lower, only endonuclease activity of EcoKI was inhibited. It was assumed that a poorer ArdA ability to inhibit EcoKI modification activity is related to the substantial difference in life cycle between transmissible plasmids (symbiosis with the bacterial cell) and bacteriophages (infection and lysis of bacteria). The Ocr and ArdA mutants that inhibited exclusively endonuclease activity of EcoKI were obtained. Antirestriction proteins incapable of homodimerization were assumed to inhibit only endonuclease activity of type I restriction-modification enzymes.

[Antirestriction proteins ardA and Ocr as effective inhibitors of the type I restriction-modification enzymes].

Genes encoding antirestriction proteins (antirestrictases, inasmuch as the antirestriction proteins inhibit the activity of restriction-modification systems, but have no proper enzyme activity, the name antirestrictase is only tentative) are included in the composition of conjugative plasmids (genes ardABC) and some bacteriophages (genes ocr and darA). Antirestriction proteins inhibit of the type I restriction-modification enzymes and thus protect unmodified DNA of plasmids and bacteriophages from degradation. Antirestriction proteins belong to the "protein mimicry of DNA" family: the spatial structure is like the B-form of DNA, and therefore the antirestriction proteins operated on the principle of concurrent inhibition replacing DNA in the complex with the restriction-modification enzyme. Based on the prepared in vitro mutant forms of ArdA and Ocr, and also on natural proteins ArdA selectively inhibiting restriction activity of the type I enzymes, but not affecting their methylase activity, we have developed a model of complex formation between the antirestriction proteins and the restriction-modification enzymes R2M2S. Antirestriction proteins are capable of competing displacement of the DNA strand from two sites which are situated as follows: 1) in S-subunit (enzyme contact with the specific DNA site) and 2) in R-subunit (through this unit translocation of the DNA strand occurs followed by its degradation). Analysis of estriction and antimodification activities of proteins ArdA and Ocr depending on the expression level of genes ardA and ocr was performed (the cloning of the genes was done under strictly regulated promoter).

[Antirestriction and antimodification activities of the T7 Ocr protein: effect of mutations in interface].

Antirestriction protein Ocr (bacteriophage T7) is specific inhibitor of the type I restriction-modification enzymes. The bacteriophage T7 0.3 (ocr) gene is cloned in pUC18 vector. It was shown that T7 Ocr protein inhibits both restriction and modification activities of the type I restriction-modification enzyme (EcoKI) in Escherichia coli K12 cells. The mutation form of Ocr-Ocr F53D A57E, which inhibits only the restriction activity of EcoKI-enzyme, was constructed. The T7 0.3 (ocr) and the Photorhabdus luminescens luxCDABE genes were cloned in pZ-series vectors with the P(ltet0-1) promoter which is tightly repressible by the TetR repressor. Controlling the expression of the lux-genes encoding bacterial luciferase demonstrates that the P(ltet0-1) promoter can be regulated over and up to 5000 fold range by supplying anhydrotetracycline (aTc) to the E. coli MG1655Z1 tetR+ cells. It was determined the dependence of the effectiveness of the antirestriction activity of the Ocr and Ocr F53D A57E proteins on the intracellular concentration. It was shown that the values of the dissociation constants K(d) for Ocr and Ocr F53D A57E proteins with EcoKI enzyme differ in 1000 times: Kd (Ocr) = 10(-10) M, K(d) (Ocr F53D A57E) = 10(-7) M.

[Polymorphism of the mitochondrial DNA control region in eight sturgeon species and development of a system for DNA-based species identification].

Intraspecific and interspecific nucleotide sequence variations of the mtDNA control region (D-loop) were studied with mtDNAs isolated from tissue specimens of more than 1400 sturgeons of nine species: Russian sturgeon Acipenser gueldenstaedtii, Persian sturgeon A. persicus, Siberian sturgeon A. baerii, Amur sturgeon A. schrenkii, Fringebarbel sturgeon A. nudiventris, sterlet A. ruthenus, stellate sturgeon A. stellatus, beluga Huso huso, and kaluga H. dauricus. The results were used to analyze the interspecific variation of the mtDNA control region in the given set of species and to develop a test system of ten species-specific primers, which allowed genetic identification intravital tissue specimens, spawn, and food products of eight species. The system proved suitable for multiplex PCR. A method was developed for the first time to reliably differentiate the A. baerii mitotype and the baerii-like mitotype of A. gueldenstaedtii. It was found that, although genetically separate, A. gueldenstaedtii and A. persicus are relatively young species and have common mitochondrial haplotypes, precluding their identification via mtDNA analysis alone. To develop a system for species identification of A. gueldenstaedtii and A. persicus, it is necessary to study the polymorphism of nuclear markers.

Gene Expression in the Three-Spined Stickleback (Gasterosteus aculeatus) of Marine and Freshwater Ecotypes.

Three-spine stickleback (Gasterosteus aculeatus) is a well-known model organism that is routinely used to explore microevolution processes and speciation, and the number of studies related to this fish has been growing recently. The main reason for the increased interest is the processes of freshwater adaptation taking place in natural populations of this species. Freshwater three-spined stickleback populations form when marine water three-spined sticklebacks fish start spending their entire lifecycle in freshwater lakes and streams. To boot, these freshwater populations acquire novel biological traits during their adaptation to a freshwater environment. The processes taking place in these populations are of great interest to evolutionary biologists. Here, we present differential gene expression profiling in G. aculeatus gills, which was performed in marine and freshwater populations of sticklebacks. In total, 2,982 differentially expressed genes between marine and freshwater populations were discovered. We assumed that differentially expressed genes were distributed not randomly along stickleback chromosomes and that they are regularly observed in the "divergence islands" that are responsible for stickleback freshwater adaptation.

Differential miRNA expression in the three-spined stickleback, response to environmental changes.

miRNAs play important role in the various physiological and evolutionary processes, however, there is no data allowing comparison of evolutionary differences between various ecotypes adapted to different environmental conditions and specimen demonstrating immediate physiological response to the environmental changes. We compared miRNA expression profiles between marine and freshwater stickleback populations of the three-spined stickleback to identify the evolutionary differences. To study the immediate physiological response to foreign environment, we explored the changes induced by transfer of marine sticklebacks into freshwater environment and vice versa. Comparative analysis of changes in miRNA expression suggested that they are driven by three independent factors: (1) non-specific changes in miRNA expression under different environmental conditions; (2) specific response to freshwater conditions in the marine stickleback ecotype; (3) specific response to extreme osmotic conditions for both marine and freshwater ecotypes during the contact with non-native environment. Gene Ontology enrichment analysis of differential expressed miRNA targets supports our current hypothesis.

Metagenomic analysis of microbial community of a parasitoid wasp Megaphragma amalphitanum.

The vast majority of multicellular organisms coexist with bacterial symbionts that may play various roles during their life cycle. Parasitoid wasp Megaphragma amalphitanum (Hymenoptera: Trichogrammatidae) belongs to the smallest known insects whose size is comparable with some bacteria. Using 16S rRNA gene sequencing and Whole Genome Sequencing (WGS), we described microbiota diversity for this arthropod and its potential impact on their lifecycle. Metagenomic sequences were deposited to SRA database which is available at NCBI with accession number SRX2363723 and SRX2363724. We found that small body size and limited lifespan do not lead to a significant reduction of bacterial symbionts diversity. At the same time, we show here a specific feature of microbiota composition in M. amalphitanum - the absence of the Rickettsiaceae family representatives that are known to cause sex-ratio distortion in arthropods and well represented in other populations of parasitoid wasps.

[Antirestriction and antimodification activities of the ArdA protein encoded by the IncI1 transmissive plasmids R-64 and ColIb-P9].

Proteins of the Ard family are specific inhibitors of type I restriction-modification enzymes. The ArdA of R64 is highly homologous to ColIb-P9 ArdA, differing only by four amino acid residues of the overall 166. However, unlike ColIb-P9 ArdA, which inhibits both the endonuclease and the methylase activities of EcoKI, the R64 ArdA protein inhibits only the endonuclease activity of this enzyme. The mutant forms of R64 ArdA--A29T, S43A, and Y75W, capable of partially reversing the protein to ColIb-P9 ArdA form--were produced by directed mutagenesis. It was demonstrated that only Y75W mutation of these three variants essentially influenced the functional activity of ArdA: the antimodification activity was restored to approximately 90-99%. It is assumed that R64 ArdA inhibits formation of the complex between unmodified DNA and the R subunit of the type I restriction-modification enzyme EcoKI (R2M2S), which translocates and cleaves DNA. ColIb-P9 ArdA protein is capable of forming the DNA complex not only with the R subunit, but also with the S subunit, which contacts sK site (containing modified adenine residues) in DNA. ArdA bound to the specific sK site inhibits concurrently the endonuclease and methylase activities of EcoKI (R2M2S), while ArdA bound to the nonspecific site in the R subunit blocks only its endonuclease activity.

Identification of novel microRNA genes in freshwater and marine ecotypes of the three-spined stickleback (Gasterosteus aculeatus).

The three-spined stickleback (Gasterosteus aculeatus L.) is an important model organism for studying the molecular mechanisms of speciation and adaptation to salinity. Despite increased interest to microRNA discovery and recent publication on microRNA prediction in the three-spined stickleback using bioinformatics approaches, there is still a lack of experimental support for these data. In this paper, high-throughput sequencing technology was applied to identify microRNA genes in gills of the three-spined stickleback. In total, 595 miRNA genes were discovered; half of them were predicted in previous computational studies and were confirmed here as microRNAs expressed in gill tissue. Moreover, 298 novel microRNA genes were identified. The presence of miRNA genes in selected 'divergence islands' was analysed and 10 miRNA genes were identified as not randomly located in 'divergence islands'. Regulatory regions of miRNA genes were found enriched with selective SNPs that may play a role in freshwater adaptation.

IncI1 plasmid R64 encodes the ArsR protein that alleviates type I restriction.

The host-controlled EcoK restriction of unmodified phage lambda was five-fold alleviated in the wild-type Escherichia coli strain K12 carrying the R64 plasmid of the incompatibility group I1. The relevant gene was mapped between the origin of vegetative replication (rep, oriV) and the tet(r) gene about 60 kbp downstream from the origin of transfer, oriT. We cloned this gene inside the 613 bp long EcoRI-PstI fragment and sequenced it. Only one 351 bp long open reading frame (ORF) starting at 124 bp from the beginning of the insert was found in the sequence. Computer search in the current databases revealed that the putative protein is identical to the ArsR protein specified by the IncFI plasmid R773. ArsR is a repressor of the arsenical resistance (ars) operon, arsRDABC. There are no arsABC genes in the R64 plasmid since plasmid R64- (or pSR8)-mediated resistance of E. coli K12 cells to the arsenicals arsenate and arsenite was not detected. The gene arsR and the antirestriction genes ard (ardA and ardB) are non-homologous. However, comparison of the deduced amino acid sequence of ArsR with the ArdA and ArdB sequences revealed only one small region of similarity, a 9 amino acid motif found in different antirestriction proteins that is hypothesized to be an interaction site for antirestriction proteins with restriction endonucleases.

[Antirestriction activity of the IncI1 transmissive plasmid R64 ArdA protein]. / Antirestriktsionnaia aktivnost' belka ArdA, kodiruemogo transmissivnoi plazmidoi R64.

The transmissive plasmid IncI1 R64 contains the ardA gene encoding the ArdA antirestriction protein. The R64 ardA gene locating in the leading region of plasmid R64 has been cloned and their sequence has been determined. Antirestriction proteins belonging to the Ard family are specific inhibitors of type I restriction-modification enzymes. The IncI1 ColIb-P9 and R64 are closely related plasmids, and the latter specifies an ArdA homologue that is predicted to be 97.6% (162 residues from 166) identical at the amino acid sequence level with the ColIb = P9 equivalent. However, the R64 ArdA selectively inhibits the restriction activity of EcoKi enzyme leaving significant levels of modification activity under conditions in which restriction was almost completely prevented. The ColIb-P9 ArdA inhibits restriction endonuclease and methyltransferase activities simultaneously. It is hypothesized that the ArdA protein forms two complexes with the type I restriction-modification enzyme (R2M2S): (1) with a specific region in the S subunit involved in contact with the sK site in DNA; and (2) with nonspecific region in the R subunit involved in DNA translocation and degradation by restriction endonuclease. The association of the ColIb-P9 ArdA with the specific region inhibits restriction endonuclease and methyltransferase activities simultaneously, whereas the association of the R64 ArdA with a nonspecific region inhibits only restriction endonuclease activity of the R2M2S enzyme.

[Alleviation of type I restriction in Escherichia coli K12 in the presence of the arsR gene from pKW301 of Acidiphilium multivorum AIU 301]. / Oslablenie restriktsii tipa I u Escherichia coli K12 v prisutstvii gena arsR pKW301 Acidiphilium multivorum AIU 301.

A study was made of the antirestriction activity of Acidiphilium multivorum AIU 301 ArsR, a repressor of the ars operon which confers resistance to arsenite and arsenate and is on pKW301. In Escherichia coli, arsR cloned under the control of Plac in a multi-copy vector alleviated restriction of nonmodified lambda DNA by a factor of 120, six times more efficiently than its analogs of conjugal plasmids R64 (incI1) and R773 (incFI). Amino acid sequence analysis showed that the three ArsR proteins have a homologous region of 38 residues, including the antirestriction motif, in their N domains, whereas the motif is in the C domain in the Ard proteins. The other regions are nonhomologous, and pKW301 ArsR is 33 residues shorter than R64 and R773 ArsRs. The total charge is -4 in pKW301 ArsR and +2 in R64 and R733 ArsRs. A total negative charge was assumed to contribute to the antirestriction activity.

[Role of "anti-restriction" motif in functional activity of anti-restriction protein ArdA pKM101 (incN)]. / Rol' "antirestriktsionnogo" motiva v funktsional'noi aktivnosti antirestriktazy ArdA pKM101 (incN).

A number of mutant forms of the antirestriction protein ArdA encoded by the ardA gene located in a transmissive IncN plasmid pKM101 have been constructed. Proteins belonging to the Ard family are specific inhibitors of type I restriction--modification enzymes. Single mutational substitutions of negatively charged amino acid residues located in the "antirestriction motif" with hydrophobic alanine, E134A, E137A, D144A, or a double substitution E134A, E137A do not affect the antirestriction activity (Ard) of ArdA but almost completely abolish the antimodification activity (Amd). Mutational substitutions F107D and A110D in the assumed interface ArdA, which determines contact between monomers in the active dimer (Ard)2, cause an approximately 100-fold decrease in the antirestriction protein activity. It is hypothesized that the ArdA protein forms two complexes with the type I restriction--modification enzyme (R2M2S): (1) with a specific region in the S subunit involved in contact with the sK site in DNA; and (2) with a nonspecific region in the R subunit involved in DNA translocation and degradation by restriction endonucleases. The association of ArdA with the specific region inhibits restriction endonuclease and methyltransferase activities simultaneously, whereas the association of ArdA with a nonspecific region inhibits only restriction endonuclease activity of the R2M2S enzyme.

[Attenuation of type I restriction in Escherichia coli: effect of the ard gene in UV-irradiated cells]. / Oslablenie restriktsii I tipa u Escherichia coli: deistvie gena ard v UF-obluchennykh kletakh.

The effect of conjugative plasmids ColIb-P9 (incI1) and pKM 101 (incN), containing the active ard gene, on the efficiency of EcoK restriction of nonmodified phage lambda .0 in UV-irradiated Escherichia coli cells was studied. ard-Dependent antirestriction enzyme activity was shown to decrease in UV-irradiated cells. The efficiency of action of the ard plasmid gene on lambda .0 was also shown not to depend on cell helicases RecBCD and UvrD, in contrast to the UV-induced alleviation of EcoK restriction (SOS alleviation).

[Lux-regulon from Vibrio fisheri reduces type 1 restriction in Escherichia coli K12 cells]. / Lux-regulon Vibrio fisheri oslabliaet restriktsiiu 1-go tipa v kletkakh Escherichia coli K12.

The EcoK restriction of nonmodified phage lambda.0 controlled by Escherichia coli K12 lon- cells is alleviated 10-20-fold in the presence of a hybrid plasmid containing the entire lux regulon of Vibrio fischeri. The La protease participates in degradation of the regulatory LuxR-LuxI proteins; therefore, transcription of the right lux operon begins significantly earlier than in the lon+ bacteria and is characterized by high content of the N-(3-oxohexanoyl) homoserine lactone autoinducer in medium. The effect of lux-induced alleviation of type I restriction in the lon mutants of E.coli K12 is proposed to depend on the reduction at the intracellular level of S-adenosylmethionine, one of the LuxI synthase substrates responsible for autoinducer synthesis.

[Cloning and expression of the lux-operon of Photorhabdus luminescens, strain Zm1: nucleotide sequence of luxAB genes and basic properties of luciferase]. / Klonirovanie i ékspressiia lux-operona Photorhabdus luminescens, shtamm Zm1: nukleotidnaia posledovatel'nost' genov luxAB i osnovye kharakteristiki liutsiferazy.

A chromosomal fragment of bacteria Photorhabdus luminescence Zm1, which contains the lux operon, was cloned into the vector pUC18. The hybrid clone containing plasmid pXen7 with the EcoRI fragment approximately 7-kb was shown to manifest a high level of bioluminescence. By subcloning and restriction analysis of the EcoRI fragment, the location of luxCDABE genes relative to restriction sites was determined. The nucleotide sequence of the DNA fragment containing the luxA and luxB genes encoding alpha- and beta-subunits of luciferase was determined. A comparison with the nucleotide sequences of luxAB genes in Hm and Hw strains of Ph. luminescence revealed 94.5 and 89.7% homology, respectively. The enterobacterial repetitive intergenic sequence (ERIC) of 126 bp typical for Hw strains was identified in the spacer between the luxD and luxA genes. The lux operon of Zm1 is assumed to emerge through recombination between Hm and Hw strains. Luciferase of Ph. luminescence was shown to possess a high thermal stability: its activity decreased by a factor of 10 at 44 degrees C for 30 min, whereas luciferases of marine bacteria Vibrio fischeri and Vibrio harveyi were inactivated by one order of magnitude at 44 degrees C for 1 and 6 min, respectively. The lux genes of Ph. luminescence are suggested for use in gene engineering and biotechnology.