Analysis of bacterial communities in a municipal duck pond during a phytoplankton bloom and isolation of Anatilimnocola aggregata gen. nov., sp. nov., Lacipirellula limnantheis sp. nov. and Urbifossiella limnaea gen. nov., sp. nov. belonging to the phylum Planctomycetes

Waterbodies such as lakes and ponds are fragile environments affected by human influences. Suitable conditions can result in massive growth of phototrophs, commonly referred to as phytoplankton blooms. Such events benefit heterotrophic bacteria able to use compounds secreted by phototrophs or their biomass as major nutrient source. One example of such bacteria are Planctomycetes, which are abundant on the surfaces of marine macroscopic phototrophs; however, less data are available on their ecological roles in limnic environments. In this study, we followed a cultivation-independent deep sequencing approach to study the bacterial community composition during a cyanobacterial bloom event in a municipal duck pond. In addition to cyanobacteria, which caused the bloom event, members of the phylum Planctomycetes were significantly enriched in the cyanobacteria-attached fraction compared to the free-living fraction. Separate datasets based on isolated DNA and RNA point towards considerable differences in the abundance and activity of planctomycetal families, indicating different activity peaks of these families during the cyanobacterial bloom. Motivated by the finding that the sampling location harbours untapped bacterial diversity, we included a complementary cultivation-dependent approach and isolated and characterized three novel limnic strains belonging to the phylum Planctomycetes.     

Characterization of Planctomyces limnophilus and development of genetic tools for its manipulation establish it as a model species for the phylum Planctomycetes

Planctomycetes represent a remarkable clade in the domain Bacteria because they play crucial roles in global carbon and nitrogen cycles and display cellular structures that closely parallel those of eukaryotic cells. Studies on Planctomycetes have been hampered by the lack of genetic tools, which we developed for Planctomyces limnophilus.     

Identification and targeted cultivation of abundant novel freshwater sphingomonads and analysis of their population substructure

Little is known with respect to bacterial population structures in freshwater environments. Using complementary culture-based, cloning, and high-throughput Illumina sequencing approaches, we investigated microdiverse clusters of bacteria that comprise members with identical or very similar 16S rRNA gene sequences. Two 16S rRNA phylotypes could be recovered by cultivation in low-nutrient-strength liquid media from two lakes of different trophic status. Both phylotypes were found to be physiologically active in situ throughout most of the year, as indicated by the presence of their rRNA sequences in the samples. Analyses of internal transcribed spacer (ITS1) sequences revealed the presence of seven different sequence types among cultured representatives and the cloned rrn fragments. Illumina sequencing yielded 8,576 ITS1 sequences that encompassed 15 major and numerous rare sequence types. The major ITS1 types exhibited distinct temporal patterns, suggesting that the corresponding Sphingomonadaceae lineages occupy different ecological niches. However, since strains of the same ITS1 type showed highly variable substrate utilization patterns, the potential mechanism of niche separation in Sphingomonadaceae cannot be explained by substrate utilization alone and may be related to other traits.     

Toward Cloning of the Magnetotactic Metagenome: Identification of Magnetosome Island Gene Clusters in Uncultivated Magnetotactic Bacteria from Different Aquatic Sediments

In this report, we describe the selective cloning of large DNA fragments from magnetotactic metagenomes from various aquatic habitats. This was achieved by a two-step magnetic enrichment which allowed the mass collection of environmental magnetotactic bacteria (MTB) virtually free of nonmagnetic contaminants. Four fosmid libraries were constructed and screened by end sequencing and hybridization analysis using heterologous magnetosome gene probes. A total of 14 fosmids were fully sequenced. We identified and characterized two fosmids, most likely originating from two different alphaproteobacterial strains of MTB that contain several putative operons with homology to the magnetosome island (MAI) of cultivated MTB. This is the first evidence that uncultivated MTB exhibit similar yet differing organizations of the MAI, which may account for the diversity in biomineralization and magnetotaxis observed in MTB from various environments.Magnetotactic bacteria (MTB) synthesize magnetosomes, which are membrane-enclosed organelles comprising crystals of magnetite (Fe₃O₄) or, less commonly, greigite (Fe₃S₄) (3) that are aligned in intracellular chains along dedicated cytoskeletal structures (26, 36, 38). Magnetic alignment along the magnetic field lines of the earth facilitates navigation in the stratified environment within freshwater and marine sediments (3, 13). MTB do not form a coherent phylogenetic group, but the trait of magnetotaxis is found in species within different phylogenetic clades, including Alphaproteobacteria, Deltaproteobacteria, Gammaproteobacteria, and the Nitrospira phylum (1, 3, 10, 41). Different species produce magnetosome crystals with a multitude of different morphologies displaying a broad variety of intracellular arrangements, including one, two, or multiple chains (3, 14). The perfectly shaped magnetosome crystals and highly ordered chain structures cannot be synthesized by chemical methods as yet. Therefore, an understanding of the genetic mechanisms controlling magnetosome formation is also of great interest for the inorganic production of advanced magnetic nanomaterials (3, 13, 28).Most genes controlling magnetosome formation and magnetotaxis in Magnetospirillum gryphiswaldense and other freshwater magnetospirilla are clustered within four major operons (mamAB, mamGFDC, mms6, and mamXY) (18, 34, 37, 49) that are part of a large genomic magnetosome island (MAI) (49). It was recently shown that the MAI is also conserved in marine MTB, including the MV-1 magnetotactic vibrio strain and the MC-1 magnetic coccus strain. The homologous genomic regions display similar gene contents and, to a lesser extent, a conserved gene synteny (23). It has been suggested that the MAI was transferred horizontally between different MTB (37). However, the divergence between the MAI regions of strain MV-1, strain MC-1, and the magnetospirilla suggests that the events of horizontal gene transfer (HGT) did not occur very recently.Despite continued efforts by many laboratories, the majority of MTB are still not available in pure culture. In particular, the huge diversity of uncultivated species with respect to different morpho- and phylotypes and, in particular, magnetosome crystal shapes is not nearly fully represented by cultivated species. Thus, understanding of the genetic diversity of the magnetotaxis and magnetosome biosynthetic machinery has to rely on culture-independent techniques such as the metagenomic analysis of environmental MTB (24).It has been demonstrated that single genes and even entire operons can be cloned and functionally expressed from uncultivated soil or marine bacteria by using large insert libraries that provide contiguous sections from single organisms (4, 21, 22). The potential to identify and clone genes for metabolic pathways with relevance for biotechnological applications has already been demonstrated in metagenomic projects, such as the identification of polyketide synthase genes from microbial consortia of marine sponges (25) or other environmental samples (8, 31). The cost of sequencing and the challenges that are associated with the management of vast datasets, however, preclude comprehensive genomic studies of highly complex communities. Consequently, approaches that are based on the analysis of a group of bacteria with reduced species diversity are favored. This requires that the sample material is enriched for the target organisms before DNA preparation, for example, by flow sorting, centrifugation, or other physical enrichment techniques (32, 42) or by focusing on natural communities with reduced species diversity (48).Unlike other uncultivated bacteria, MTB exhibit magnetically directed swimming behavior, which enables their selective enrichment from environmental samples without the need of cultivation (16). This approach was utilized in a number of earlier studies uncovering the morphological and phylogenetic diversity of MTB found in environmental populations (10, 43, 45-47). However, these investigations were confined to PCR-based analysis of 16S rRNA genes, ultrastructural studies, and fluorescence in situ hybridization.In this study we used an improved magnetic collection technique to selectively harvest large numbers of uncultivated MTBs, which allowed the extraction of genomic DNA for the construction of large insert metagenomic libraries from different aquatic habitats. Large parts of the MAI from two uncultivated MTB were identified by hybridization using heterologous magnetosome gene probes and end sequencing. We demonstrate for the first time that uncultivated MTB exhibit a clustered organization of magnetosome genes which resembles that of cultivated species and yet displays variations that may account for the observed diversity in biomineralization and magnetotaxis in MTB from various environments. The levels of similarity between and synteny of magnetosome genes of uncultivated and cultivated MTB provide further evidence for HGT.     

Comparative analysis of magnetosome gene clusters in magnetotactic bacteria provides further evidence for horizontal gene transfer

The organization of magnetosome genes was analysed in all available complete or partial genomic sequences of magnetotactic bacteria (MTB), including the magnetosome island (MAI) of the magnetotactic marine vibrio strain MV‐1 determined in this study. The MAI was found to differ in gene content and organization between Magnetospirillum species and strains MV‐1 or MC‐1. Although a similar organization of magnetosome genes was found in all MTB, distinct variations in gene order and sequence similarity were uncovered that may account for the observed diversity of biomineralization, cell biology and magnetotaxis found in various MTB. While several magnetosome genes were present in all MTB, others were confined to Magnetospirillum species, indicating that the minimal set of genes required for magnetosome biomineralization might be smaller than previously suggested. A number of novel candidate genes were implicated in magnetosome formation by gene cluster comparison. Based on phylogenetic and compositional evidence we present a model for the evolution of magnetotaxis within the Alphaproteobacteria, which suggests the independent horizontal transfer of magnetosome genes from an unknown ancestor of magnetospirilla into strains MC‐1 and MV‐1.     

The 1st EMBO workshop on PVC bacteria—Planctomycetes–Verrucomicrobia–Chlamydiae superphylum: Exceptions to the bacterial definition?

The PVC superphylum is a phylogenetically supported collection of various related bacterial phyla that comprise unusual characteristics and traits. The ‘PVC’ abbreviation derives from Planctomycetes, Verrucomicrobia and Chlamydiae as members of this superphylum, while additional bacterial phyla are related. There has recently been increasing and exciting interest in the cell biology, physiology and ecology of members of this superphylum, including evolutionary implications of the complex cell organization of some species. It is timely that international researchers in the PVC superphylum field met to discuss these developments. The first meeting entirely dedicated to those bacteria, the EMBO workshop “PVC superphylum: Exceptions to the bacterial definition” was held at the Heidelberg University to catalyze the formation of a vital scientific community supporting PVC-bacterial research. More than 45 investigators from more than 20 countries (PIs, senior scientists and students) attended the meeting and produced a great starting point for future collaborative research. This Special Issue will focus on the EMBO-PVC meeting. This Perspective briefly summarizes the history of PVC-research, focusing on the key findings and provides a brief summary of the meeting with a focus on the major questions that arose during discussion and that might influence the research in the years to come.     

Diversity analysis of magnetotactic bacteria in Lake Miyun,northern China,by restriction fragment length polymorphism

Magnetotactic bacteria (MTB) synthesize intracellular nano-scale crystals of magnetite or greigite within magnetosomes. MTB are ubiquitous in limnic and marine environments. In order to understand the diversity of MTB better, sediment samples were examined from Lake Miyun near Beijing by restriction fragment length polymorphism (RFLP). First, in silico analysis was used to evaluate the effectiveness of 12 sets of restriction endonucleases for distinguishing MTB sequences retrieved from the GenBank database. It was found that the tested restriction endonucleases had different power in the ability to differentiate the operational taxonomic units (OTUs) of MTB. Specifically, of the 12 sets of enzymes, MspI plus RsaI was found to be the most effective for correctly differentiating the OTUs of selected MTB sequences and it could detect 16 OTUs with appropriate OTUmin and OTUmax values (96.7% and 97.7%, respectively). The MspI plus RsaI RFLP analysis was then utilized to investigate the diversity of MTB in Lake Miyun sediment and it identified 8 OTUs (74.5% of the whole library) as MTB. Among these, 5 were affiliated to Alphaproteobacteria, while the rest belonged to the Nitrospira phylum. Interestingly, OTUs C, D and I displayed 91.8–98.4% similarity to “Magnetobacterium bavaricum”. Together, these results demonstrated that the MspI plus RsaI RFLP analysis was useful for studying the diversity and change in community composition of uncultivated MTB from environmental samples.     

Replication properties of human adenovirus in vivo and in cultures of primary cells from different animal species

Oncolytic adenoviruses have emerged as a promising approach for the treatment of tumors resistant to other treatment modalities. However, preclinical safety studies are hampered by the lack of a permissive nonhuman host. Screening of a panel of primary cell cultures from seven different animal species revealed that porcine cells support productive replication of human adenovirus type 5 (Ad5) nearly as efficiently as human A549 cells, while release of infectious virus by cells from other animal species tested was diminished by several orders of magnitude. Restriction of productive Ad5 replication in rodent and rabbit cells seems to act primarily at a postentry step. Replication efficiency of adenoviral vectors harboring different E1 deletions or mutations in porcine cells was similar to that in A549 cells. Side-by-side comparison of the viral load kinetics in blood of swine and mice injected with Ad5 or a replication-deficient adenoviral vector failed to provide clear evidence for virus replication in mice. In contrast, evidence suggests that adenovirus replication occurs in swine, since adenoviral late gene expression produced a 13.5-fold increase in viral load in an individual swine from day 3 to day 7 and 100-fold increase in viral DNA levels in the Ad5-infected swine compared to the animal receiving a replication-deficient adenovirus. Lung histology of Ad5-infected swine revealed a severe interstitial pneumonia. Although the results in swine are based on a small number of animals and need to be confirmed, our data strongly suggest that infection of swine with human adenovirus or oncolytic adenoviral vectors is a more appropriate animal model to study adenoviral pathogenicity or pharmacodynamic and toxicity profiles of adenoviral vectors than infection of mice.     

From genome mining to phenotypic microarrays: Planctomycetes as source for novel bioactive molecules

Most members of the phylum Planctomycetes share many unusual traits that are unique for bacteria, since they divide independent of FtsZ through asymmetric budding, possess a complex life cycle and comprise a compartmentalized cell plan. Besides their complex cell biological features Planctomycetes are environmentally important and play major roles in global matter fluxes. Such features have been successfully employed in biotechnological applications such as the anaerobic oxidation of ammonium in wastewater treatment plants or the utilization of enzymes for biotechnological processes. However, little is known about planctomycetal secondary metabolites. This is surprising as Planctomycetes have several key features in common with known producers of small bioactive molecules such as Streptomycetes or Myxobacteria: a complex life style and large genome sizes. Planctomycetal genomes with an average size of 6.9 MB appear as tempting targets for drug discovery approaches. To enable the hunt for bioactive molecules from Planctomycetes, we performed a comprehensive genome mining approach employing the antiSMASH secondary metabolite identification pipeline and found 102 candidate genes or clusters within the analyzed 13 genomes. However, as most genes and operons related to secondary metabolite production are exclusively expressed under certain environmental conditions, we optimized Phenotype MicroArray protocols for Rhodopirellula baltica and Planctomyces limnophilus to allow high throughput screening of putative stimulating carbon sources. Our results point towards a previously postulated relationship of Planctomycetes with algae or plants, which secrete compounds that might serve as trigger to stimulate the secondary metabolite production in Planctomycetes. Thus, this study provides the necessary starting point to explore planctomycetal small molecules for drug development.