Use of low-coverage, large-insert, short-read data for rapid and accurate generation of enhanced-quality draft Pseudomonas genome sequences

Next-generation genomic technology has both greatly accelerated the pace of genome research as well as increased our reliance on draft genome sequences. While groups such as the Genomics Standards Consortium have made strong efforts to promote genome standards there is a still a general lack of uniformity among published draft genomes, leading to challenges for downstream comparative analyses. This lack of uniformity is a particular problem when using standard draft genomes that frequently have large numbers of low-quality sequencing tracts. Here we present a proposal for an "enhanced-quality draft" genome that identifies at least 95% of the coding sequences, thereby effectively providing a full accounting of the genic component of the genome. Enhanced-quality draft genomes are easily attainable through a combination of small- and large-insert next-generation, paired-end sequencing. We illustrate the generation of an enhanced-quality draft genome by re-sequencing the plant pathogenic bacterium Pseudomonas syringae pv. phaseolicola 1448A (Pph 1448A), which has a published, closed genome sequence of 5.93 Mbp. We use a combination of Illumina paired-end and mate-pair sequencing, and surprisingly find that de novo assemblies with 100x paired-end coverage and mate-pair sequencing with as low as low as 2-5x coverage are substantially better than assemblies based on higher coverage. The rapid and low-cost generation of large numbers of enhanced-quality draft genome sequences will be of particular value for microbial diagnostics and biosecurity, which rely on precise discrimination of potentially dangerous clones from closely related benign strains.     

Forward chemical genetic screens in Arabidopsis identify genes that influence sensitivity to the phytotoxic compound sulfamethoxazole

The rise of high mountain chains is widely seen as one of the factors driving rapid diversification of land plants and the formation of biodiversity hotspots. Supporting evidence was reported for the impact of the rapid rise of the Andean mountains but this hypothesis has so far been less explored for the impact of the “roof of the world”. The formation of the Himalaya, and especially the rise of the Qinghai–Tibetan Plateau in the recent 20 million years, altered the monsoon regimes that dominate the current climates of South East Asia. Here, we infer the hypothesis that the rise of Himalaya had a strong impact on the plant diversity in the biodiversity hotspot of the Southwest Chinese Mountains. Our analyses of the diversification pattern of the derived fern genus Lepisorus recovered evidence for changes in plant diversity that correlated with the strengthening of South East Asian monsoon. Southwest China or Southwest China and Japan was recovered as the putative area of origin of Lepisorus and enhancing monsoon regime were found to shape the early diversification of the genus as well as subsequent radiations during the late Miocene and Pliocene. We report new evidence for a coincidence of plant diversification and changes of the climate caused by the uplift of the Himalaya. These results are discussed in the context of the impact of incomplete taxon sampling, uncertainty of divergence time estimates, and limitations of current methods used to assess diversification rates.     

百草枯对木质素降解菌产酶及其生物化学变化的影响

为研究外源活性氧对木质素降解菌的影响,本实验对外源百草枯诱导下的杂色云芝(Coriolus versicolor)产酶及其生物化学过程进行了研究。将一定浓度的百草枯加入培养7 d的杂色云芝菌培养液中,连续培养148 h,测定其胞外木质素降解酶、胞内抗氧化酶的活性及生物化学参数的变化。与对照相比,30μmol/L的百草枯能够显著促进杂色云芝锰依赖过氧化物酶(MnP)、木质素过氧化物酶(LiP)和漆酶(Lac)的活性,3种酶活性分别提高了1.3、7和2.5倍;在连续培养的前48 h,30μmol/L的百草枯促进了胞内超氧化物歧化酶(SOD)、过氧化氢酶(CAT)的活性。百草枯对于胞外木质素降解酶活性的促进作用比对胞内抗氧化酶活性的促进作用明显。百草枯的加入促进了胞外酚类化合物与甲醛的浓度的增加,而丙二醛的浓度在培养的前24 h内增加,随后下降。结果表明,百草枯的加入对白腐菌产生了氧化胁迫,但菌株的抗氧化系统能够有效地进行氧化剂的清除,从而阻止氧化剂对机体的氧化伤害。百草枯作为外源氧化胁迫剂,可以增加木质素降解酶活性,有利于木质素的降解。     

The evolutionary landscape of the chromatin modification machinery reveals lineage specific gains,expansions, and losses

Model organisms such as yeast, fly, and worm have played a defining role in the study of many biological systems. A significant challenge remains in translating this information to humans. Of critical importance is the ability to differentiate those components where knowledge of function and interactions may be reliably inferred from those that represent lineage‐specific innovations. To address this challenge, we use chromatin modification (CM) as a model system for exploring the evolutionary properties of their components in the context of their known functions and interactions. Collating previously identified components of CM from yeast, worm, fly, and human, we identified a “core” set of 50 CM genes displaying consistent orthologous relationships that likely retain their interactions and functions across taxa. In addition, we catalog many components that demonstrate lineage specific expansions and losses, highlighting much duplication within vertebrates that may reflect an expanded repertoire of regulatory mechanisms. Placed in the context of a high‐quality protein–protein interaction network, we find, contrary to existing views of evolutionary modularity, that CM complex components display a mosaic of evolutionary histories: a core set of highly conserved genes, together with sets displaying lineage specific innovations. Although focused on CM, this study provides a template for differentiating those genes which are likely to retain their functions and interactions across species. As such, in addition to informing on the evolution of CM as a system, this study provides a set of comparative genomic approaches that can be generally applied to any biological systems. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Next-generation mapping of Arabidopsis genes

Next‐generation genomic sequencing technologies have made it possible to directly map mutations responsible for phenotypes of interest via direct sequencing. However, most mapping strategies proposed to date require some prior genetic analysis, which can be very time‐consuming even in genetically tractable organisms. Here we present a de novo method for rapidly and robustly mapping the physical location of EMS mutations by sequencing a small pooled F₂ population. This method, called Next Generation Mapping (NGM), uses a chastity statistic to quantify the relative contribution of the parental mutant and mapping lines to each SNP in the pooled F₂ population. It then uses this information to objectively localize the candidate mutation based on its exclusive segregation with the mutant parental line. A user‐friendly, web‐based tool for performing NGM analysis is available at http://bar.utoronto.ca/NGM . We used NGM to identify three genes involved in cell‐wall biology in Arabidopsis thaliana, and, in a power analysis, demonstrate success in test mappings using as few as ten F₂ lines and a single channel of Illumina Genome Analyzer data. This strategy can easily be applied to other model organisms, and we expect that it will also have utility in crops and any other eukaryote with a completed genome sequence.     

1H, 13C and 15N resonance assignments of the rhodanese domain of YgaP from Escherichia coli

Rhodanese domain is a ubiquitous structural module commonly found in bacterial, archaeal and eukaryotic cells. Growing evidence indicates that rhodanese domains act as the carrier of reactive sulfur atoms by forming persulfide intermediates in distinct metabolic pathways. YgaP, a membrane protein consisting of a rhodanese domain and a C-terminal transmembrane segment, is the only membrane-associated rhodanese in Escherichia coli. Herein, we report the resonance assignments of ¹H, ¹³C and ¹⁵N atoms of rhodanese domain of YgaP. Totally, chemical shifts of more than 95% of the atoms were assigned.     

Analysis of the Cystic Fibrosis Lung Microbiota via Serial Illumina Sequencing of Bacterial 16S rRNA Hypervariable Regions

The characterization of bacterial communities using DNA sequencing has revolutionized our ability to study microbes in nature and discover the ways in which microbial communities affect ecosystem functioning and human health. Here we describe Serial Illumina Sequencing (SI-Seq): a method for deep sequencing of the bacterial 16S rRNA gene using next-generation sequencing technology. SI-Seq serially sequences portions of the V5, V6 and V7 hypervariable regions from barcoded 16S rRNA amplicons using an Illumina short-read genome analyzer. SI-Seq obtains taxonomic resolution similar to 454 pyrosequencing for a fraction of the cost, and can produce hundreds of thousands of reads per sample even with very high multiplexing. We validated SI-Seq using single species and mock community controls, and via a comparison to cystic fibrosis lung microbiota sequenced using 454 FLX Titanium. Our control runs show that SI-Seq has a dynamic range of at least five orders of magnitude, can classify >96% of sequences to the genus level, and performs just as well as 454 and paired-end Illumina methods in estimation of standard microbial ecology diversity measurements. We illustrate the utility of SI-Seq in a pilot sample of central airway secretion samples from cystic fibrosis patients.     

1H, 13C and 15N resonance assignments of RNA pyrophosphohydrolase RppH from Escherichia coli

The mRNA degradation is an important regulatory mechanism which controls gene expression by limiting the number of translation times. Previous studies demonstrated that this process is essential for organisms. Escherichia coli RNA pyrophosphohydrolase (RppH) is an enzyme that triggers mRNA degradation by removing the 5′ pyrophosphate, which is a rate-determining step. In order to understand the molecular mechanism of the biological function, the structural information of RppH is required. Herein, we report the resonance assignments of ¹H, ¹⁵N, ¹³C atoms of the E. coli RppH.     

Structural and biochemical analyses of shikimate dehydrogenase AroE from Aquifex aeolicus: implications for the catalytic mechanism

The shikimate biosynthetic pathway is essential to microorganisms, plants, and parasites but absent from mammals. Therefore, shikimate dehydrogenase (SD) and other enzymes in the pathway are attractive targets for developing nontoxic antimicrobial agents, herbicides, and antiparasite drugs. SD catalyzes the fourth reaction in the pathway, the nicotinamide adenine dinucleotide phosphate- (NADP-) dependent reduction of 3-dehydroshikimic acid to shikimic acid (SA), as well as its reverse, by the transfer of a hydride. Previous structural studies reveal that the enzyme exists in two major conformations, an open and a closed form. For the reaction to occur, it is believed that the catalytic complex assumes the closed conformation. Nonetheless, the only structure containing both SA and NADP+ exhibits an open conformation (PDB entry 2EV9). Here, we present two crystal structures of Aquifex aeolicus SD, including a ternary complex with both SA and NADP+, which assumes the closed conformation and therefore contains a catalytically competent active site. On the basis of preexisting and novel structural and biochemical data, a catalytic mechanism is proposed.