Metasequencing of V3-V4 Variable Regions of 16S rRNA Gene in Opportunistic Microbiota and Gut Biocenosis in Obese Adolescents.

Opportunistic microorganisms in the gut biocenosis were studied in adolescents with normal body weight and obesity (patients consulted at the Clinical Department of Research Center of Family Health and Human Reproduction Problems). The biological material was studied by standard bacteriological methods, representatives of Enterobacteriaceae family were also characterized using metagenomic sequencing of V3-V4 variable regions of 16S gene rRNA. Gut microbiota of obese adolescents was unbalanced and was characterized by low levels of bifido- and lactoflora representatives, a spectrum of E. coli associations, and high prevalence of opportunistic microorganisms and their associations. Representatives of Enterobacteriaceae family were most often found in the gut microbiota of obese adolescents.

DNAzyme-dependent Analysis of rRNA 2'-O-Methylation.

Guide box C/D small nucleolar RNAs (snoRNAs) catalyze 2'-O-methylation of ribosomal and small nuclear RNA. However, a large number of snoRNA in higher eukaryotes may promiscuously recognize other RNA species and 2'-O-methylate multiple targets. Here, we provide step-by-step guide for the fast and non-expensive analysis of the site-specific 2'-O-methylation using a well-established method employing short DNA oligonucleotides called DNAzymes. These DNA fragments contain catalytic sequences which cleave RNA at specific consensus positions, as well as variable homology arms directing DNAzyme to its RNA targets. DNAzyme activity is inhibited by 2-'O-methylation of the nucleotide adjacent to the cleavage site in the RNA. Thus, DNAzymes, limited only by the consensus of the cleaved sequence, are perfect tools for the quick analysis of snoRNA-mediated RNA 2'-O-methylation. We analyzed snoRNA snR13- and snR47-guided 2'-O-methylation of 25S ribosomal RNA in Saccharomyces cerevisiae to demonstrate the simplicity of the technique and to provide a detailed protocol for the DNAzyme-dependent assay.

Intricacies of assessing the human microbiome in epidemiologic studies.

PURPOSE: In the past decade, remarkable relationships have been documented between dysbiosis of the human microbiota and adverse health outcomes. This review seeks to highlight some of the challenges and pitfalls that may be encountered during all stages of microbiota research, from study design and sample collection, to nucleic acid extraction and sequencing, and bioinformatic and statistical analysis. METHODS: Literature focused on human microbiota research was reviewed and summarized. RESULTS: Although most studies have focused on surveying the composition of the microbiota, fewer have explored the causal roles of these bacteria, archaea, viruses, and fungi in affecting disease states. Microbiome research is in its relatively early years and many aspects remain challenging, including the complexity and personalized aspects of microbial communities, the influence of exogenous and often confounding factors, the need to apply fundamental principles of ecology and epidemiology, the necessity for new software tools, and the rapidly evolving genomic, technological, and analytical landscapes. CONCLUSIONS: Incorporating human microbiome research in large epidemiologic studies will soon help us unravel the intricate relationships that we have with our microbial partners and provide interventional opportunities to improve human health.

Ribosomal protein S6, a target of rapamycin, is involved in the regulation of rRNA genes by possible epigenetic changes in Arabidopsis.

The target of rapamycin (TOR) kinase pathway regulates various biological processes, including translation, synthesis of ribosomal proteins, and transcription of rRNA. The ribosomal protein S6 (RPS6) is one of the well known downstream components of the TOR pathway. Ribosomal proteins have been known to have diverse functions in regulating cellular metabolism as well as protein synthesis. So far, however, little is known about other possible role(s) of RPS6 in plants, besides being a component of the 40 S ribosomal subunit and acting as a target of TOR. Here, we report that RPS6 may have a novel function via interaction with histone deacetylase 2B (AtHD2B) that belongs to the plant-specific histone deacetylase HD2 family. RPS6 and AtHD2B were localized to the nucleolus. Co-expression of RPS6 and AtHD2B caused a change in the location of both RPS6 and AtHD2B to one or several nucleolar spots. ChIP analysis suggests that RPS6 directly interacts with the rRNA gene promoter. Protoplasts overexpressing both AtHD2B and RPS6 exhibited down-regulation of pre-18 S rRNA synthesis with a concomitant decrease in transcription of some of the ribosomal proteins, suggesting their direct role in ribosome biogenesis and plant development. This is consistent with the mutation in rps6b that results in reduction in 18 S rRNA transcription and decreased root growth. We propose that the interaction between RPS6 and AtHD2B brings about a change in the chromatin structure of rDNA and thus plays an important role in linking TOR signaling to rDNA transcription and ribosome biogenesis in plants.

A traffic flow model for bio-polymerization processes.

Bio-polymerization processes like transcription and translation are central to proper function of a cell. The speed at which the bio-polymer grows is affected both by the number of pauses of elongation machinery, as well the number of bio-polymers due to crowding effects. In order to quantify these effects in fast transcribing ribosome genes, we rigorously show that a classical traffic flow model is the limit of a mean occupancy ODE model. We compare the simulation of this model to a stochastic model and evaluate the combined effect of the polymerase density and the existence of pauses on the instantaneous transcription rate of ribosomal genes.

New rRNA gene-based phylogenies of the Alphaproteobacteria provide perspective on major groups, mitochondrial ancestry and phylogenetic instability.

Bacteria in the class Alphaproteobacteria have a wide variety of lifestyles and physiologies. They include pathogens of humans and livestock, agriculturally valuable strains, and several highly abundant marine groups. The ancestor of mitochondria also originated in this clade. Despite significant effort to investigate the phylogeny of the Alphaproteobacteria with a variety of methods, there remains considerable disparity in the placement of several groups. Recent emphasis on phylogenies derived from multiple protein-coding genes remains contentious due to disagreement over appropriate gene selection and the potential influences of systematic error. We revisited previous investigations in this area using concatenated alignments of the small and large subunit (SSU and LSU) rRNA genes, as we show here that these loci have much lower GC bias than whole genomes. This approach has allowed us to update the canonical 16S rRNA gene tree of the Alphaproteobacteria with additional important taxa that were not previously included, and with added resolution provided by concatenating the SSU and LSU genes. We investigated the topological stability of the Alphaproteobacteria by varying alignment methods, rate models, taxon selection and RY-recoding to circumvent GC content bias. We also introduce RYMK-recoding and show that it avoids some of the information loss in RY-recoding. We demonstrate that the topology of the Alphaproteobacteria is sensitive to inclusion of several groups of taxa, but it is less affected by the choice of alignment and rate methods. The majority of topologies and comparative results from Approximately Unbiased tests provide support for positioning the Rickettsiales and the mitochondrial branch within a clade. This composite clade is a sister group to the abundant marine SAR11 clade (Pelagibacterales). Furthermore, we add support for taxonomic assignment of several recently sequenced taxa. Accordingly, we propose three subclasses within the Alphaproteobacteria: the Caulobacteridae, the Rickettsidae, and the Magnetococcidae.

Conserved regulators of nucleolar size revealed by global phenotypic analyses.

Regulation of cell growth is a fundamental process in development and disease that integrates a vast array of extra- and intracellular information. A central player in this process is RNA polymerase I (Pol I), which transcribes ribosomal RNA (rRNA) genes in the nucleolus. Rapidly growing cancer cells are characterized by increased Pol I-mediated transcription and, consequently, nucleolar hypertrophy. To map the genetic network underlying the regulation of nucleolar size and of Pol I-mediated transcription, we performed comparative, genome-wide loss-of-function analyses of nucleolar size in Saccharomyces cerevisiae and Drosophila melanogaster coupled with mass spectrometry-based analyses of the ribosomal DNA (rDNA) promoter. With this approach, we identified a set of conserved and nonconserved molecular complexes that control nucleolar size. Furthermore, we characterized a direct role of the histone information regulator (HIR) complex in repressing rRNA transcription in yeast. Our study provides a full-genome, cross-species analysis of a nuclear subcompartment and shows that this approach can identify conserved molecular modules.

Ribosomal RNA gene transcription mediated by the master genome regulator protein CCCTC-binding factor (CTCF) is negatively regulated by the condensin complex.

CCCTC-binding factor (CTCF) is a ubiquitously expressed "master weaver" and plays multiple functions in the genome, including transcriptional activation/repression, chromatin insulation, imprinting, X chromosome inactivation, and high-order chromatin organization. It has been shown that CTCF facilitates the recruitment of the upstream binding factor onto ribosomal DNA (rDNA) and regulates the local epigenetic state of rDNA repeats. However, the mechanism by which CTCF modulates rRNA gene transcription has not been well understood. Here we found that wild-type CTCF augments the pre-rRNA level, cell size, and cell growth in cervical cancer cells. In contrast, RNA interference-mediated knockdown of CTCF reduced pre-rRNA transcription. CTCF positively regulates rRNA gene transcription in a RNA polymerase I-dependent manner. We identified an RRGR motif as a putative nucleolar localization sequence in the C-terminal region of CTCF that is required for activating rRNA gene transcription. Using mass spectrometry, we identified SMC2 and SMC4, two subunits of condensin complexes that interact with CTCF. Condensin negatively regulates CTCF-mediated rRNA gene transcription. Knockdown of SMC2 expression significantly facilitates the loading of CTCF and the upstream binding factor onto the rDNA locus and increases histone acetylation across the rDNA locus. Taken together, our study suggests that condensin competes with CTCF in binding to a specific rDNA locus and negatively regulates CTCF-mediated rRNA gene transcription.

[Karelian birch (Betula pendula Roth. var. carelica Merkl.) as a model for studying genetic and epigenetic variation related to the formation of patterned wood].

The results of long-term pioneering studies on in vitro micropropagation of Karelian birch patterned forms and simultaneous cytological analysis of plants multiplied using different periods of in vitro culturing are published for the first time. The patterned wood character has been shown to be correlated with the degree of mixoploidy of its somatic tissue, which is higher in the plants obtained from callus cultures during the first years of culturing. Subsequent intracellular selection leads to a decrease in mixoploidy and, hence, in a later expression and lower expressivity of the patterned wood character in regenerant plants. It is also known that extreme growth conditions stimulate the formation of patterned wood. Thus, Karelian birch may serve as a model object for studying the forms of variability (both genetic and epigenetic) that result in patterned wood. The genetic variability is expressed in the variation of the degree of mixoploidy of somatic tissue as a result of various mitotic aberrations. The epigenetic variability is not related to changes in the DNA structure; it is caused by different phenotypic effects of genes located in cells with different ploidy/aneuploidy levels, the ratio between which varies depending on the environmental conditions. The expression of genes, in particular, rRNA genes, is affected by extreme conditions. The appearance of a residual nucleolus at the mitotic metaphase-telophase stages is a cytological expression of this phenomenon.

Regulation of ribosomal RNA gene copy number and its role in modulating genome integrity and evolutionary adaptability in yeast.

The genes encoding ribosomal RNA (rRNA) are the most abundant genes in the eukaryotic genome. They reside in tandem repetitive clusters, in some cases totaling hundreds of copies. Due to their repetitive structure and highly active transcription, the rRNA gene repeats are some of the most fragile sites in the chromosome. A unique gene amplification system compensates for loss of copies, thus maintaining copy number, albeit with some fluctuations. The unusual nature of rRNA gene repeats affects cellular functions such as senescence. In addition, we recently found that the repeat number determines sensitivity to DNA damage. In this review, I would like to introduce a new aspect of the rRNA gene repeat (called rDNA) as a center of maintenance of genome integrity and discuss its contribution to evolution.

[Cluster size polymorphism of active human ribosomal genes and simulation of the conditions of its stability through generations].

Based on selective silver nitrate staining of active ribosomal gene (AcRG) clusters in nucleolus organizer regions (NORs) of human metaphase chromosomes, a technique was developed earlier to estimate the AcRG dosage in individual genomes as a sum of arbitrary units (0-3) ascribed to the silver precipitate (AgNOR) on ten NORs. The AcRG dosage was considered to be an additive quantitative trait determined by five polymorphic autosomal loci (with for allelic forms for each locus). A database was created to contain the data on AcRG cluster variants for more than 1000 individual human genomes. In this study, the population frequencies of AcRG cluster variants were determined. The results agreed with the hypothesis that stabilizing selection acts at the zygotic and/or early embryogenetic stage to restrain the AcRG genomic dosage (copy number) within a range from 14.9 to 23.7 arbitrary units (the cell is unviable when the trait is beyond this range). The average zygotic losses due to selection were estimated at 9.1-9.9% for a real population. A computer model where the AcRG dosage of a progeny results from a random combination of the AgNORs of the five acrocentric chromosome pairs of the parents was developed and used to simulate the formation of a certain AcRG genomic dosage through generations in a human panmictic population with nonoverlapping generations. A combination of stabilizing selection by total AcRG copy number and a certain spontaneous mutation rate (the probability of changes in the cluster size of a NOR as a result of unequal crossingover in meiotic prophase) was shown to be a sufficient condition for the restrain of equilibrium population frequencies of AgNOR size variants in a human panmictic population. Using the model, the most probable spontaneous mutation frequency was predicted to be (2.1-2.3) x 10(-2) per NOR per generation for human AgNORs. The predicted frequency was within the 95% confidence interval of the experimental rate, which was determined by studying the inheritance of AgNOR variants in real families.

Transcript-based cloning of RRP46, a regulator of rRNA processing and R gene-independent cell death in barley-powdery mildew interactions.

Programmed cell death (PCD) plays a pivotal role in plant development and defense. To investigate the interaction between PCD and R gene-mediated defense, we used the 22K Barley1 GeneChip to compare and contrast time-course expression profiles of Blumeria graminis f. sp hordei (Bgh) challenged barley (Hordeum vulgare) cultivar C.I. 16151 (harboring the Mla6 powdery mildew resistance allele) and its fast neutron-derived Bgh-induced tip cell death1 mutant, bcd1. Mixed linear model analysis identified genes associated with the cell death phenotype as opposed to R gene-mediated resistance. One-hundred fifty genes were found at the threshold P value < 0.0001 and a false discovery rate <0.6%. Of these, 124 were constitutively overexpressed in the bcd1 mutant. Gene Ontology and rice (Oryza sativa) alignment-based annotation indicated that 68 of the 124 overexpressed genes encode ribosomal proteins. A deletion harboring six genes on chromosome 5H cosegregates with bcd1-specified cell death and is associated with misprocessing of rRNAs but segregates independent of R gene-mediated resistance. Barley stripe mosaic virus-induced gene silencing of one of the six deleted genes, RRP46 (rRNA-processing protein 46), phenocopied bcd1-mediated tip cell death. These findings suggest that RRP46, a critical component of the exosome core, mediates RNA processing and degradation involved in cell death initiation as a result of attempted penetration by Bgh during the barley-powdery mildew interaction but is independent of gene-for-gene resistance.

[Molecular evolution of ciliates (Ciliophora) and some related groups of protozoans].

The review summarizes current evidence, including the findings related to molecular phylogeny of ciliates (type Ciliophora) and some related groups of protozoans. Based on comparison of the sequences of genes encoding various ribosomal RNAs (rRNAs), the phylogenetic relationships in seven out of eight known classes of ciliates are discussed. The events related to early branching of the eukaryotic tree are briefly presented. The evolutionary history of amitochondrial protists ids considered with regard to reductionistic evolution and archeozoic hypothesis. The phylogenetic relationships among ciliates and sister groups of apicomplexans and dinoflagellates are considered.

Succinate dehydrogenase gene arrangement and expression in Anaplasma phagocytophilum.

DNA sequencing of the region directly downstream of the Anaplasma phagocytophilum (strain MRK) 16S rRNA gene identified homologues of sdhC and sdhD; however, further sequencing by gene walking failed to identify additional sdh gene homologues. The sequence downstream of sdhD identified a partial gene, pep1, predicted to encode a protein >35.3 kDa with 26.3% identity to a hypothetical Ehrlichia canis protein with no known function. The recently completed sequence of the A. phagocytophilum genome confirmed our findings and indicated that the sdhA and sdhB genes are duplicated in a tandem orientation, and located distant from the sdhC and sdhD genes. The expression of the A. phagocytophilum 16S rRNA, sdhC, and sdhD genes was examined by reverse transcriptase PCR which showed that these three genes are expressed as an operon. The pep1 gene was expressed independent of the 16S-sdhCD operon from a promoter between sdhD and pep1. Further analysis of the sdhA and sdhB genes suggested the tandem duplication of the genes in conserved and may be unique to the species A. phagocytophilum. While the conservation of the A. phagocytophilum Sdh proteins, including the residues required for heme- and quinone-binding by SdhC and SdhD, suggests these subunits form an active enzymatic complex, the unusual genomic arrangement and expression pattern of these genes support previous studies (rRNA, ftsZ) indicating that gene rearrangement and operon fragmentation are common in the genomes of Anaplasma and other obligate intracellular bacteria. OMB DISCLAIMER: The findings and conclusions in this report are those of the authors and do not necessarily represent the views of the CDC or the Department of Health and Human Services.

Epigenetic regulation of TTF-I-mediated promoter-terminator interactions of rRNA genes.

Ribosomal RNA synthesis is the eukaryotic cell's main transcriptional activity, but little is known about the chromatin domain organization and epigenetics of actively transcribed rRNA genes. Here, we show epigenetic and spatial organization of mouse rRNA genes at the molecular level. TTF-I-binding sites subdivide the rRNA transcription unit into functional chromatin domains and sharply delimit transcription factor occupancy. H2A.Z-containing nucleosomes occupy the spacer promoter next to a newly characterized TTF-I-binding site. The spacer and the promoter proximal TTF-I-binding sites demarcate the enhancer. DNA from both the enhancer and the coding region is hypomethylated in actively transcribed repeats. 3C analysis revealed an interaction between promoter and terminator regions, which brings the beginning and end of active rRNA genes into close contact. Reporter assays show that TTF-I mediates this interaction, thereby linking topology and epigenetic regulation of the rRNA genes.

Relationship between ribosomal RNA gene transcription activity and motoneuron death: observations of avulsion and axotomy of the facial nerve in rats.

Motoneuron number and expression of cytoplasmic RNA and ribosomal RNA (rRNA) gene transcription activity in the facial nucleus were examined quantitatively and chronologically for up to 4 weeks in rats after facial nerve axotomy and avulsion in order to elucidate interrelationships in axonal changes. The right facial nerves of adult Fischer rats were avulsed at a portion of the outlet or axotomized at a portion of the foramen stylomastoideus. The number of large motoneurons in the facial nucleus was reduced by 40% 2 weeks after avulsion and by 70% 4 weeks after avulsion but displayed a 19% loss even 4 weeks after axotomy. The amount of cytoplasmic RNA decreased significantly and progressively from 1 day after avulsion. rRNA gene transcription activity in the large motoneurons of the facial nucleus decreased significantly beginning 30 min after both axotomy and avulsion, but the severity of the decrease was far more marked in the avulsion group, showing a 59% loss from the control value 4 weeks after avulsion. These findings indicate that rRNA gene transcription activity, expression of cytoplasmic RNA, and the number of motoneurons that survive are interrelated and that the decrease in rRNA gene transcription activity is a very early event in the phenomena observed in the axonal reactions of motoneurons.

[The nucleolus as a regulator of cellular senescence]. / El nucleolo como un regulador del envejecimiento celular.

The nucleolus has been considered originally only as the site for the ribosome synthesis, but now it is well known that it represents a dynamic nuclear structure involved in important cellular processes. Several evidences have demonstrated that the nucleolus regulates the cellular senescence. Specific mutations on the DNAs codifying for nucleolar proteins induced premature senescence from yeast to human. The failure to repress the genes transcription codifying for damaged rRNA, and the mutations in DNA helicases, which minimizes the formation of DNA extra-chromosomal circles codifying for rRNA, modify the nucleolar structure and induce premature senescence in yeast. Similarly, in humans, the reduction of these DNA helicases levels, which are localized in the nucleoli and participate in maintenance of genomic integrity, helps to the development of those diseases associated with premature senescence. Furthermore, the presence in the nucleolus of some telomerase components, indicates that part of the biosynthesis of this enzyme occurred in this nuclear structure; suggesting a communication between the nucleolus and the synthesis of the telomeres in the regulation of cell senescence. On the other hand, the nucleolus sequesters proteins to regulate its own biological activity, from the start to the end of cellular replication. In addition this nuclear structure is involved in the biosynthesis of most cellular ribonucleoprotein particles, as well as in cell cycle regulation, making it central to gene expression. In conclusion, the nucleolus became a multifunctional subnuclear structure involved from cell proliferation to cell senescence.

El nucléolo como un regulador del envejecimiento celular / The nucleolus as a regulator of cellular senescence

El nucléolo, considerado únicamente como el sitio de síntesis de los ribosomas, actualmente representa una estructura nuclear dinámica que participa en la regulación de importantes procesos celulares. Numerosas evidencias han demostrado que el envejecimiento celular es una de las diversas funciones que son controladas por el nucléolo. Las mutaciones en las proteínas de localización nucleolar promueven el envejecimiento prematuro en levaduras y humanos. La carencia de represión en la transcripción de genes que codifican para el ARNr que se encuentran dañados, y las mutaciones en las helicasas del ADN encargadas de minimizar la formación de círculos extra-cromosómicos del ADN que codifica para el ARNr, provocan modificaciones en la estructura del nucléolo e inducen envejecimiento prematuro en levaduras. De igual manera, en los humanos la carencia de las helicasas del ADN localizadas en el nucléolo y que participan en el mantenimiento de la integridad genómica, favorecen el desarrollo de aquellas enfermedades asociadas con el envejecimiento acelerado. Además, la presencia de algunos componentes de la telomerasa en el nucléolo, indica que parte de la biosíntesis de esta enzima se realiza en esta estructura nuclear, sugiriendo una conexión entre el nucléolo y la síntesis de los telómeros en la regulación del envejecimiento celular. Por otra parte, el nucléolo secuestra proteínas para regular su actividad biológica durante el inicio o término de la vida replicativa celular.

The nucleolus has been considered originally only as the site for the ribosome synthesis, but now it is well known that it represents a dynamic nuclear structure involved in important cellular processes. Several evidences have demonstrated that the nucleolus regulates the cellular senescence. Specific mutations on the DNAs codifying for nucleolar proteins induced premature senescence from yeast to human. The failure to repress the genes transcription codifying for damaged rRNA, and the mutations in DNA helicases, which minimizes the formation of DNA extra-chromosomal circles codifying for rRNA, modify the nucleolar structure and induce premature senescence in yeast. Similarly, in humans, the reduction of these DNA helicases levels, which are localized in the nucleoli and participate in maintenance of genomic integrity, helps to the development of those diseases associated with premature senescence. Furthermore, the presence in the nucleolus of some telomerase components, indicates that part of the biosynthesis of this enzyme occurred in this nuclear structure; suggesting a communication between the nucleolus and the synthesis of the telomeres in the regulation of cell senescence. On the other hand, the nucleolus sequesters proteins to regulate its own biological activity, from the start to the end of cellular replication. In addition this nuclear structure is involved in the biosynthesis of most cellular ribonucleoprotein particles, as well as in cell cycle regulation, making it central to gene expression. In conclusion, the nucleolus became a multifunctional subnuclear structure involved from cell proliferation to cell senescence.