Movement of a prawn a Hidden Markov Model approach

Abstract This thesis presents the basic theory for hidden Markov models and standard inference algorithms for these. The performance for these algorithms are examined with the help of a small test problem and the algorithms are found to operate properly. An application of hidden Markov models for modelling the movements of a prawn is implemented. This model is shown to be significantly better to use for the problem than a more simple model, where all movements are independent. The model also proves useful for finding the time points for where the prawn changed direction. As a brief example of how this model can be used, logistic regression is used to find that the distance to neighbouring prawns have an effect on the probability of changing direction

De novo extraction of microbial strains from metagenomes reveals intra-species niche partitioning

Background We introduce DESMAN for De novo Extraction of Strains from MetAgeNomes. Metagenome sequencing generates short reads from throughout the genomes of a microbial community. Increasingly large, multi-sample metagenomes, stratified in space and time are being generated from communities with thousands of species. Repeats result in fragmentary co-assemblies with potentially millions of contigs. Contigs can be binned into metagenome assembled genomes (MAGs) but strain level variation will remain. DESMAN identifies variants on core genes, then uses co-occurrence across samples to link variants into strain sequences and abundance profiles. These strain profiles are then searched for on non-core genes to determine the accessory genes present in each strain. Results We validated DESMAN on a synthetic twenty genome community with 64 samples. We could resolve the five E. coli strains present with 99.58% accuracy across core gene variable sites and their gene complement with 95.7% accuracy. Similarly, on real fecal metagenomes from the 2011 E. coli (STEC) O104:H4 outbreak, the outbreak strain was reconstructed with 99.8% core sequence accuracy. Application to an anaerobic digester metagenome time series reveals that strain level variation is endemic with 16 out of 26 MAGs (61.5%) examined exhibiting two strains. In almost all cases the strain proportions were not statistically different between replicate reactors, suggesting intra-species niche partitioning. The only exception being when the two strains had almost identical gene complement and, hence, functional capability. Conclusions DESMAN will provide a provide a powerful tool for de novo resolution of fine-scale variation in microbial communities. It is available as open source software from https://github.com/chrisquince/DESMAN

Effects of allochthonous dissolved organic matter input on microbial composition and nitrogen cycling genes at two contrasting estuarine sites

Heterotrophic bacteria are important drivers of nitrogen (N) cycling and the processing of dissolved organic matter (DOM). Projected increases in precipitation will potentially cause increased loads of riverine DOM to the Baltic Sea and likely affect the composition and function of bacterioplankton communities. To investigate this, the effects of riverine DOM from two different catchment areas (agricultural and forest) on natural bacterioplankton assemblages from two contrasting sites in the Baltic Sea were examined. Two microcosm experiments were carried out, where the community composition (16S rRNA gene sequencing), the composition of a suite of N-cycling genes (metagenomics) and the abundance and transcription of ammonia monooxygenase (amoA) genes involved in nitrification (quantitative PCR) were investigated. The river water treatments evoked a significant response in bacterial growth, but the effects on overall community composition and the representation of N-cycling genes were limited. Instead, treatment effects were reflected in the prevalence of specific taxonomic families, specific N-related functions and in the transcription of amoA genes. The study suggests that bacterioplankton responses to changes in the DOM pool are constrained to part of the bacterial community, whereas most taxa remain relatively unaffected.Peer reviewe

BARM and BalticMicrobeDB, a reference metagenome and interface to meta-omic data for the Baltic Sea

The Baltic Sea is one of the world’s largest brackish water bodies and is characterised by pronounced physicochemical gradients where microbes are the main biogeochemical catalysts. Meta-omic methods provide rich information on the composition of, and activities within, microbial ecosystems, but are computationally heavy to perform. We here present the Baltic Sea Reference Metagenome (BARM), complete with annotated genes to facilitate further studies with much less computational effort. The assembly is constructed using 2.6 billion metagenomic reads from 81 water samples, spanning both spatial and temporal dimensions, and contains 6.8 million genes that have been annotated for function and taxonomy. The assembly is useful as a reference, facilitating taxonomic and functional annotation of additional samples by simply mapping their reads against the assembly. This capability is demonstrated by the successful mapping and annotation of 24 external samples. In addition, we present a public web interface, BalticMicrobeDB, for interactive exploratory analysis of the dataset

Ninety-nine de novo assembled genomes from the moose (Alces alces) rumen microbiome provide new insights into microbial plant biomass degradation.

The moose (Alces alces) is a ruminant that harvests energy from fiber-rich lignocellulose material through carbohydrate-active enzymes (CAZymes) produced by its rumen microbes. We applied shotgun metagenomics to rumen contents from six moose to obtain insights into this microbiome. Following binning, 99 metagenome-assembled genomes (MAGs) belonging to 11 prokaryotic phyla were reconstructed and characterized based on phylogeny and CAZyme profile. The taxonomy of these MAGs reflected the overall composition of the metagenome, with dominance of the phyla Bacteroidetes and Firmicutes. Unlike in other ruminants, Spirochaetes constituted a significant proportion of the community and our analyses indicate that the corresponding strains are primarily pectin digesters. Pectin-degrading genes were also common in MAGs of Ruminococcus, Fibrobacteres and Bacteroidetes and were overall overrepresented in the moose microbiome compared with other ruminants. Phylogenomic analyses revealed several clades within the Bacteriodetes without previously characterized genomes. Several of these MAGs encoded a large numbers of dockerins, a module usually associated with cellulosomes. The Bacteroidetes dockerins were often linked to CAZymes and sometimes encoded inside polysaccharide utilization loci, which has never been reported before. The almost 100 CAZyme-annotated genomes reconstructed in this study provide an in-depth view of an efficient lignocellulose-degrading microbiome and prospects for developing enzyme technology for biorefineries

Nevrological manifestations in patiens with West Nile fever

Гарячка Західного Нілу (ГЗН) є найпоширенішим зооантропонозним трансмісивним «комариним» захворюванням у групі природно осередкових інфекцій. Вірус ГЗН належить до роду Flavivirus родини Flaviviridae, поширений на усіх континентах за винятком Антарктиди. В Європі основним видом комарів, які передають вірус ГЗН людям, є Culex pipiens. Інфікування описане також при вертикальній передачі від матері до дитини та парентеральним шляхом. За філогенетичними властивостями вірусу розрізняють кілька генетичних груп – генотипів, деякі з яких містять підгрупи, що обумовлює нерівномірний територіальний розподіл та тяжкість клінічної маніфестації ГЗН

Critical Assessment of Metagenome Interpretation:A benchmark of metagenomics software

International audienceIn metagenome analysis, computational methods for assembly, taxonomic profilingand binning are key components facilitating downstream biological datainterpretation. However, a lack of consensus about benchmarking datasets andevaluation metrics complicates proper performance assessment. The CriticalAssessment of Metagenome Interpretation (CAMI) challenge has engaged the globaldeveloper community to benchmark their programs on datasets of unprecedentedcomplexity and realism. Benchmark metagenomes were generated from newlysequenced ~700 microorganisms and ~600 novel viruses and plasmids, includinggenomes with varying degrees of relatedness to each other and to publicly availableones and representing common experimental setups. Across all datasets, assemblyand genome binning programs performed well for species represented by individualgenomes, while performance was substantially affected by the presence of relatedstrains. Taxonomic profiling and binning programs were proficient at high taxonomicranks, with a notable performance decrease below the family level. Parametersettings substantially impacted performances, underscoring the importance ofprogram reproducibility. While highlighting current challenges in computationalmetagenomics, the CAMI results provide a roadmap for software selection to answerspecific research questions

Bioinformatic Methods in Metagenomics

Microbial organisms are a vital part of our global ecosystem. Yet, our knowledge of them is still lacking. Direct sequencing of microbial communities, i.e. metagenomics, have enabled detailed studies of these microscopic organisms by inspection of their DNA sequences without the need to culture them. Furthermore, the development of modern high- throughput sequencing technologies have made this approach more powerful and cost-effective. Taken together, this has shifted the field of microbiology from previously being centered around microscopy and culturing studies, to largely consist of computational analyses of DNA sequences. One such computational analysis which is the main focus of this thesis, aims at reconstruction of the complete DNA sequence of an organism, i.e. its genome, directly from short metagenomic sequences. This thesis consists of an introduction to the subject followed by five papers. Paper I describes a large metagenomic data resource spanning the Baltic Sea microbial communities. This dataset is complemented with a web-interface allowing researchers to easily extract and visualize detailed information. Paper II introduces a bioinformatic method which is able to reconstruct genomes from metagenomic data. This method, which is termed CONCOCT, is applied on Baltic Sea metagenomics data in Paper III and Paper V. This enabled the reconstruction of a large number of genomes. Analysis of these genomes in Paper III led to the proposal of, and evidence for, a global brackish microbiome. Paper IV presents a comparison between genomes reconstructed from metagenomes with single-cell sequenced genomes. This further validated the technique presented in Paper II as it was found to produce larger and more complete genomes than single-cell sequencing.Mikrobiella organismer är en vital del av vårt globala ekosystem. Trots detta är vår kunskap om dessa fortfarande begränsad. Sekvensering direkt applicerad på mikrobiella samhällen, så kallad metagenomik, har möjliggjort detaljerade studier av dessa mikroskopiska organismer genom deras DNA-sekvenser. Utvecklingen av modern sekvenseringsteknik har vidare gjort denna strategi både mer kraftfull och mer kostnadseffektiv. Sammantaget har detta förändrat mikrobiologi-fältet, från att ha varit centrerat kring mikroskopi, till att till stor del bero på dataintensiva analyser av DNA-sekvenser. En sådan analys, som är det huvudsakliga fokuset för den här avhandlingen, syftar till att återskapa den kompletta DNA-sekvensen för en organism, dvs. dess genom, direkt från korta metagenom-sekvenser. Den här avhandlingen består av en introduktion till ämnet, följt av fem artiklar. Artikel I beskriver en omfattande databas för metagenomik över Östersjöns mikrobiella samhällen. Till denna databas hör också en webbsida som ger forskare möjlighet att lätt extrahera och visualisera detaljerad information. Artikel II introducerar en bioinformatisk metod som kan återskapa genom från metagenom. Denna metod, som kallas CONCOCT, används för data från Östersjön i artikel III och Artikel V. Detta möjliggjorde återskapandet av ett stort antal genom. Analys av dessa genom presenterad i Artikel III ledde till hypotesen om, och belägg för, ett globalt brackvattenmikrobiom. Artikel IV innehåller en jämförelse mellan genom återskapade från metagenom och individuellt sekvenserade genom. Detta validerade metoden som presenterades i Artikel II ytterligare då denna metod visade sig producera större och mer kompletta genom än sekvensering av individuella celler.QC 20180516</p