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  • 1.
    Alneberg, Johannes
    et al.
    KTH, Skolan för kemi, bioteknologi och hälsa (CBH), Genteknologi. KTH, Centra, Science for Life Laboratory, SciLifeLab.
    Karlsson, Christofer M. G.
    Linnaeus Univ, Ctr Ecol & Evolut Microbial Model Syst, EEMiS, Kalmar, Sweden..
    Divne, Anna-Maria
    Uppsala Univ, Dept Cell & Mol Biol, SciLifeLab, Uppsala, Sweden..
    Bergin, Claudia
    Uppsala Univ, Dept Cell & Mol Biol, SciLifeLab, Uppsala, Sweden..
    Homa, Felix
    Uppsala Univ, Dept Cell & Mol Biol, SciLifeLab, Uppsala, Sweden..
    Lindh, Markus V.
    Linnaeus Univ, Ctr Ecol & Evolut Microbial Model Syst, EEMiS, Kalmar, Sweden.;Lund Univ, Dept Biol, Lund, Sweden..
    Hugerth, Luisa
    KTH, Skolan för kemi, bioteknologi och hälsa (CBH), Genteknologi. KTH, Centra, Science for Life Laboratory, SciLifeLab.
    Ettema, Thijs J. G.
    Uppsala Univ, Dept Cell & Mol Biol, SciLifeLab, Uppsala, Sweden..
    Bertilsson, Stefan
    Uppsala Univ, Dept Ecol & Genet, Sci Life Lab, Limnol, Uppsala, Sweden..
    Andersson, Anders F.
    KTH, Skolan för kemi, bioteknologi och hälsa (CBH), Genteknologi. KTH, Centra, Science for Life Laboratory, SciLifeLab.
    Pinhassi, Jarone
    Linnaeus Univ, Ctr Ecol & Evolut Microbial Model Syst, EEMiS, Kalmar, Sweden..
    Genomes from uncultivated prokaryotes: a comparison of metagenome-assembled and single-amplified genomes2018Inngår i: Microbiome, ISSN 0026-2633, E-ISSN 2049-2618, Vol. 6, artikkel-id 173Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Background: Prokaryotes dominate the biosphere and regulate biogeochemical processes essential to all life. Yet, our knowledge about their biology is for the most part limited to the minority that has been successfully cultured. Molecular techniques now allow for obtaining genome sequences of uncultivated prokaryotic taxa, facilitating in-depth analyses that may ultimately improve our understanding of these key organisms. Results: We compared results from two culture-independent strategies for recovering bacterial genomes: single-amplified genomes and metagenome-assembled genomes. Single-amplified genomes were obtained from samples collected at an offshore station in the Baltic Sea Proper and compared to previously obtained metagenome-assembled genomes from a time series at the same station. Among 16 single-amplified genomes analyzed, seven were found to match metagenome-assembled genomes, affiliated with a diverse set of taxa. Notably, genome pairs between the two approaches were nearly identical (average 99.51% sequence identity; range 98.77-99.84%) across overlapping regions (30-80% of each genome). Within matching pairs, the single-amplified genomes were consistently smaller and less complete, whereas the genetic functional profiles were maintained. For the metagenome-assembled genomes, only on average 3.6% of the bases were estimated to be missing from the genomes due to wrongly binned contigs. Conclusions: The strong agreement between the single-amplified and metagenome-assembled genomes emphasizes that both methods generate accurate genome information from uncultivated bacteria. Importantly, this implies that the research questions and the available resources are allowed to determine the selection of genomics approach for microbiome studies.

  • 2.
    Alneberg, Johannes
    et al.
    KTH, Skolan för kemi, bioteknologi och hälsa (CBH), Genteknologi. KTH, Centra, Science for Life Laboratory, SciLifeLab.
    Sundh, John
    Science for Life Laboratory, Department of Biochemistry and Biophysics, Stockholm University, Solna, Sweden.
    Bennke, Christin
    Leibniz Institute for Baltic Sea Research, Warnemünde, Germany.
    Beier, Sara
    Leibniz Institute for Baltic Sea Research, Warnemünde, Germany.
    Lundin, Daniel
    Centre for Ecology and Evolution in Microbial Model Systems, Linnaeus University, Kalmar, Sweden.
    Hugerth, Luisa
    KTH, Centra, Science for Life Laboratory, SciLifeLab. KTH, Skolan för bioteknologi (BIO).
    Pinhassi, Jarone
    Centre for Ecology and Evolution in Microbial Model Systems, Linnaeus University, Kalmar, Sweden.
    Kisand, Veljo
    University of Tartu, Institute of Technology, Tartu, Estonia.
    Riemann, Lasse
    Section for Marine Biological Section, Department of Biology, University of Copenhagen, Helsingør, Denmark.
    Jürgens, Klaus
    Leibniz Institute for Baltic Sea Research, Warnemünde, Germany.
    Labrenz, Matthias
    Leibniz Institute for Baltic Sea Research, Warnemünde, Germany.
    Andersson, Anders F.
    KTH, Skolan för kemi, bioteknologi och hälsa (CBH), Genteknologi. KTH, Centra, Science for Life Laboratory, SciLifeLab.
    BARM and BalticMicrobeDB, a reference metagenome and interface to meta-omic data for the Baltic SeaManuskript (preprint) (Annet vitenskapelig)
    Abstract [en]

    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.

  • 3.
    Hugerth, Luisa
    KTH, Skolan för bioteknologi (BIO), Genteknologi. Science for Life Laboratory.
    High-throughput DNA Sequencingin Microbial Ecology: Methods and Applications2016Doktoravhandling, med artikler (Annet vitenskapelig)
    Abstract [en]

    Microorganisms play central roles in planet Earth’s geochemical cycles, in food production, and in health and disease of humans and livestock. In spite of this, most microbial life forms remain unknown and unnamed, their ecological importance and potential technological applications beyond the realm of speculation. This is due both to the magnitude of microbial diversity and to technological limitations. Of the many advances that have enabled microbiology to reach new depth and breadth in the past decade, one of the most important is affordable high-throughput DNA sequencing. This technology plays a central role in each paper in this thesis.

    Papers I and II are focused on developing methods to survey microbial diversity based on marker gene amplification and sequencing. In Paper I we proposed a computational strategy to design primers with the highest coverage among a given set of sequences and applied it to drastically improve one of the most commonly used primer pairs for ecological surveys of prokaryotes. In Paper II this strategy was applied to an eukaryotic marker gene. Despite their importance in the food chain, eukaryotic microbes are much more seldom surveyed than bacteria. Paper II aimed at making this domain of life more amenable to high-throughput surveys.

    In Paper III, the primers designed in papers I and II were applied to water samples collected up to twice weekly from 2011 to 2013 at an offshore station in the Baltic proper, the Linnaeus Microbial Observatory. In addition to tracking microbial communities over these three years, we created predictive models for hundreds of microbial populations, based on their co-occurrence with other populations and environmental factors.

    In paper IV we explored the entire metagenomic diversity in the Linnaeus Microbial Observatory. We used computational tools developed in our group to construct draft genomes of abundant bacteria and archaea and described their phylogeny, seasonal dynamics and potential physiology. We were also able to establish that, rather than being a mixture of genomes from fresh and saline water, the Baltic Sea plankton community is composed of brackish specialists which diverged from other aquatic microorganisms thousands of years before the formation of the Baltic itself.

  • 4.
    Hugerth, Luisa
    et al.
    KTH, Skolan för bioteknologi (BIO), Genteknologi. Science for Life Laboratory.
    Lindh, Markus
    Centre for Ecology and Evolution in Microbial model Systems - Linnaeus University.
    Sjöqvist, Conny
    KTH, Skolan för bioteknologi (BIO), Genteknologi.
    Carina, Bunse
    Centre for Ecology and Evolution in Microbial model Systems - Linnaeus University.
    Legrand, Catherine
    Centre for Ecology and Evolution in Microbial model Systems - Linnaeus University.
    Pinhassi, Jarone
    Centre for Ecology and Evolution in Microbial model Systems - Linnaeus University.
    Andersson, Anders
    KTH, Skolan för bioteknologi (BIO), Genteknologi.
    Seasonal dynamics and interactions among Baltic Sea prokaryoticand eukaryotic plankton assemblagesManuskript (preprint) (Annet vitenskapelig)
    Abstract [en]

    One of the main goals of microbial ecology is to identify the mechanismsthat regulate patterns in community structure at temporal scalescompatible with populations’ turnover times across complete seasonalcycles. Here, we examined high-frequency temporal dynamics of marineplankton from a sampling effort covering 2011-2013, roughly twice weekly,comprising 144 samples. Bacterial and eukaryotic communities wereprofiled by 16S and 18S high-throughput sequencing, respectively.Interestingly, we found that no combination of the measured environmentalparameters could predict a significant proportion of the variation inpopulation dynamics of bacterioplankton, and even less so for eukaryoticplankton. Large differences in physicochemical conditions and communitycomposition typical of temperate climates mean that different regimes canquickly succeed each other over the year, with the relative importance ofdifferent drivers changing equally rapidly. Nevertheless, our approachrevealed interesting recurrent co-occurrence patterns across distinctenvironmental changes. Hence, we could make abundance predictions formore than half of the most frequent OTUs based on interactions with otherOTUs. These results suggests that a complex set of biotic interactions arecontributing to temporal patterns among planktonic assemblages despiterapid changes in environmental conditions.

  • 5. Wampach, Linda
    et al.
    Heintz-Buschart, Anna
    Hogan, Angela
    Muller, Emilie E. L.
    Narayanasamy, Shaman
    Laczny, Cedric C.
    Hugerth, Luisa
    KTH, Skolan för bioteknologi (BIO), Genteknologi. KTH, Centra, Science for Life Laboratory, SciLifeLab.
    Bindl, Lutz
    Bottu, Jean
    Andersson, Anders F.
    KTH, Skolan för bioteknologi (BIO), Genteknologi. KTH, Centra, Science for Life Laboratory, SciLifeLab.
    de Beaufort, Carine
    Wilmes, Paul
    Colonization and Succession within the Human Gut Microbiome by Archaea, Bacteria, and Microeukaryotes during the First Year of Life2017Inngår i: Frontiers in Microbiology, ISSN 1664-302X, E-ISSN 1664-302X, Vol. 8, artikkel-id 738Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Perturbations to the colonization process of the human gastrointestinal tract have been suggested to result in adverse health effects later in life. Although much research has been performed on bacterial colonization and succession, much less is known about the other two domains of life, archaea, and eukaryotes. Here we describe colonization and succession by bacteria, archaea and microeukaryotes during the first year of life (samples collected around days 1, 3, 5, 28, 150, and 365) within the gastrointestinal tract of infants delivered either vaginally or by cesarean section and using a combination of quantitative real-time PCR as well as 16S and 18S rRNA gene amplicon sequencing. Sequences from organisms belonging to all three domains of life were detectable in all of the collected meconium samples. The microeukaryotic community composition fluctuated strongly over time and early diversification was delayed in infants receiving formula milk. Cesarean section-delivered (CSD) infants experienced a delay in colonization and succession, which was observed for all three domains of life. Shifts in prokaryotic succession in CSD infants compared to vaginally delivered (VD) infants were apparent as early as days 3 and 5, which were characterized by increased relative abundances of the genera Streptococcus and Staphylococcus, and a decrease in relative abundance for the genera Bifidobacterium and Bacteroides. Generally, a depletion in Bacteroidetes was detected as early as day 5 postpartum in CSD infants, causing a significantly increased Firmicutes/Bacteroidetes ratio between days 5 and 150 when compared to VD infants. Although the delivery mode appeared to have the strongest influence on differences between the infants, other factors such as a younger gestational age or maternal antibiotics intake likely contributed to the observed patterns as well. Our findings complement previous observations of a delay in colonization and succession of CSD infants, which affects not only bacteria but also archaea and microeukaryotes. This further highlights the need for resolving bacterial, archaeal, and microeukaryotic dynamics in future longitudinal studies of microbial colonization and succession within the neonatal gastrointestinal tract.

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