MinION™ nanopore sequencing of environmental metagenomes: a synthetic approach.

Environmental metagenomic analysis is typically accomplished by assigning taxonomy and/or function from whole genome sequencing or 16S amplicon sequences. Both of these approaches are limited, however, by read length, among other technical and biological factors. A nanopore-based sequencing platform, MinION™, produces reads that are ≥1 × 104 bp in length, potentially providing for more precise assignment, thereby alleviating some of the limitations inherent in determining metagenome composition from short reads.

Metagenomic analysis of planktonic microbial consortia from a non-tidal urban-impacted segment of James River.

Knowledge of the diversity and ecological function of the microbial consortia of James River in Virginia, USA, is essential to developing a more complete understanding of the ecology of this model river system. Metagenomic analysis of James River's planktonic microbial community was performed for the first time using an unamplified genomic library and a 16S rDNA amplicon library prepared and sequenced by Ion PGM and MiSeq, respectively. From the 0.

The truth about metagenomics: quantifying and counteracting bias in 16S rRNA studies.

Background: Characterizing microbial communities via next-generation sequencing is subject to a number of pitfalls involving sample processing. The observed community composition can be a severe distortion of the quantities of bacteria actually present in the microbiome, hampering analysis and threatening the validity of conclusions from metagenomic studies. We introduce an experimental protocol using mock communities for quantifying and characterizing bias introduced in the sample processing pipeline.

Dissociation of ribosomes into large and small subunits.

Structural and functional studies of ribosomal subunits require the dissociation of intact ribosomes into individual small and large ribosomal subunits. The dissociation of the prokaryotic 70S ribosomes into the 50S and 30S subunits is achieved by dialysis against a buffer containing a lower Mg(2+) concentration. Eukaryotic 80S ribosomes are dissociated into 60S and 40S subunits by incubation in a buffer containing puromycin and higher KCl and Mg(2+) concentrations.

Purification of polysomes.

Isolated polysomes (also known as translating ribosomes or polyribosomes) are mRNA-ribosome complexes that are frequently used for the in vitro study of the regulation of protein synthesis. Here we describe a protocol for the isolation of prokaryotic and plant polysomes by sucrose gradient sedimentation. The protocol allows for the separation of multiple ribosomes attached to mRNA from run-off ribosome monomers.

Purification of 70S ribosomes.

Here we describe the further purification of prokaryotic ribosomal particles obtained after the centrifugation of a crude cell lysate through a sucrose cushion. In this final purification step, a fraction containing ribosomes, ribosomal subunits, and polysomes is centrifuged through a 7%-30% (w/w) linear sucrose gradient to isolate tight couple 70S ribosomes, as well as dissociated 30S and 50S subunits. The tight couples fraction, or translationally active ribosome fraction, is composed of intact vacant ribosomes that can be used in cell-free translation systems.

Isolation of ribosomes and polysomes.

Here we describe a preparative differential centrifugation protocol for the isolation of ribosomes from a crude cell homogenate. The subcellular fraction obtained is enriched in ribosome monomers and polysomes. The protocol has been optimized for the homogenization and collection of the ribosomal fraction from prokaryotic cells, mammalian and plant tissues, reticulocytes, and chloroplasts.

Instruction in metacognitive strategies to increase deaf and hard-of-hearing students' reading comprehension.

The purpose of this intervention study was to examine the use of a metacognitive strategy--the Comprehension, Check, and Repair Strategy--on strategic reading behavior, nonstrategic reading behavior, and reading comprehension of students who are deaf or hard of hearing (D/HH). A multiple baseline design was used across 3 teacher-student dyads. Frequency data were collected on students' strategic reading behavior.

Genomic analyses and the origin of the eukaryotes.

The availability of whole-genome data has created the extraordinary opportunity to reconstruct in fine details the 'tree of life'. The application of such comprehensive effort promises to unravel the enigmatic evolutionary relationships between prokaryotes and eukaryotes. Traditionally, biologists have represented the evolutionary relationships of all organisms by a bifurcating phylogenetic tree.

Rooting the tree of life using nonubiquitous genes.

Insertion and deletion (indel)-based analyses have great potential for rooting the tree of life, but their use has been limited because they require ubiquitous sequences that have not been horizontally/laterally transferred. Very few such sequences exist. Here we describe and demonstrate a new algorithm that can use nonubiquitous sequences for rooting.

Evidence that the root of the tree of life is not within the Archaea.

The Archaea occupy uncommon and extreme habitats around the world. They manufacture unusual compounds, utilize novel metabolic pathways, and contain many unique genes. Many suspect, due to their novel properties, that the root of the tree of life may be within the Archaea, although there is little direct evidence for this root.

Decoding the genomic tree of life.

Genomes hold within them the record of the evolution of life on Earth. But genome fusions and horizontal gene transfer (HGT) seem to have obscured sufficiently the gene sequence record such that it is difficult to reconstruct the phylogenetic tree of life. HGT among prokaryotes is not random, however.

The ring of life provides evidence for a genome fusion origin of eukaryotes.

Genomes hold within them the record of the evolution of life on Earth. But genome fusions and horizontal gene transfer seem to have obscured sufficiently the gene sequence record such that it is difficult to reconstruct the phylogenetic tree of life. Here we determine the general outline of the tree using complete genome data from representative prokaryotes and eukaryotes and a new genome analysis method that makes it possible to reconstruct ancient genome fusions and phylogenetic trees.

Deriving the genomic tree of life in the presence of horizontal gene transfer: conditioned reconstruction.

The horizontal gene transfer (HGT) being inferred within prokaryotic genomes appears to be sufficiently massive that many scientists think it may have effectively obscured much of the history of life recorded in DNA. Here, we demonstrate that the tree of life can be reconstructed even in the presence of extensive HGT, provided the processes of genome evolution are properly modeled. We show that the dynamic deletions and insertions of genes that occur during genome evolution, including those introduced by HGT, may be modeled using techniques similar to those used to model nucleotide substitutions that occur during sequence evolution.

Horizontal gene transfer accelerates genome innovation and evolution.

Horizontal gene transfer (HGT) spreads genetic diversity by moving genes across species boundaries. By rapidly introducing newly evolved genes into existing genomes, HGT circumvents the slow step of ab initio gene creation and accelerates genome innovation. However, HGT can only affect organisms that readily exchange genes (exchange communities).

Horizontal gene transfer in microbial genome evolution.

Horizontal gene transfer is the collective name for processes that permit the exchange of DNA among organisms of different species. Only recently has it been recognized as a significant contribution to inter-organismal gene exchange. Traditionally, it was thought that microorganisms evolved clonally, passing genes from mother to daughter cells with little or no exchange of DNA among diverse species.