Ancient saltern metagenomics: tracking changes in microbes and their viruses from the underground to the surface

Microbial communities in hypersaline underground waters derive from ancient organisms trapped within the evaporitic salt crystals and are part of the poorly known subterranean biosphere. Here, we characterized the viral and prokaryotic assemblages present in the hypersaline springs that dissolve Triassic-Keuper evaporite rocks and feed the Añana Salt Valley (Araba/Alava, Basque Country, Spain). Four underground water samples (around 23% total salinity) with different levels of exposure to the open air were analysed by means of microscopy and metagenomics. Cells and viruses in the spring water had lower concentrations than what are normally found in hypersaline environments and seemed to be mostly inactive. Upon exposure to the open air, there was an increase in activity of both cells and viruses as well as a selection of phylotypes. The underground water was inhabited by a rich community harbouring a diverse set of genes coding for retinal binding proteins. A total of 35 viral contigs from 15 to 104 kb, representing partial or total viral genomes, were assembled and their evolutionary changes through the spring system were followed by SNP analysis and metagenomic island tracking. Overall, both the viral and the prokaryotic assemblages changed quickly upon exposure to the open air conditions.     

Will intra‐specific differences in transpiration efficiency in wheat be maintained in a high CO2 world? A FACE study

This study evaluates whether the target breeding trait of superior leaf level transpiration efficiency is still appropriate under increasing carbon dioxide levels of a future climate using a semi‐arid cropping system as a model. Specifically, we investigated whether physiological traits governing leaf level transpiration efficiency, such as net assimilation rates (A_net), stomatal conductance (g_s) or stomatal sensitivity were affected differently between two Triticum aestivum L. cultivars differing in transpiration efficiency (cv. Drysdale, superior; cv. Hartog, low). Plants were grown under Free Air Carbon dioxide Enrichment (FACE, approximately 550 µmol mol^?1 or ambient CO₂ concentrations (approximately 390 µmol mol^?1). Mean A_net (approximately 15% increase) and g_s (approximately 25% decrease) were less affected by elevated [CO₂] than previously found in FACE‐grown wheat (approximately 25% increase and approximately 32% decrease, respectively), potentially reflecting growth in a dry‐land cropping system. In contrast to previous FACE studies, analyses of the Ball et al. model revealed an elevated [CO₂] effect on the slope of the linear regression by 12% indicating a decrease in stomatal sensitivity to the combination of [CO₂], photosynthesis rate and humidity. Differences between cultivars indicated greater transpiration efficiency for Drysdale with growth under elevated [CO₂] potentially increasing the response of this trait. This knowledge adds valuable information for crop germplasm improvement for future climates.     

Correlative Imaging of Fluorescent Proteins in Resin-Embedded Plant Material1

Fluorescent proteins (FPs) were developed for live-cell imaging and have revolutionized cell biology. However, not all plant tissues are accessible to live imaging using confocal microscopy, necessitating alternative approaches for protein localization. An example is the phloem, a tissue embedded deep within plant organs and sensitive to damage. To facilitate accurate localization of FPs within recalcitrant tissues, we developed a simple method for retaining FPs after resin embedding. This method is based on low-temperature fixation and dehydration, followed by embedding in London Resin White, and avoids the need for cryosections. We show that a palette of FPs can be localized in plant tissues while retaining good structural cell preservation, and that the polymerized block face can be counterstained with cell wall probes. Using this method we have been able to image green fluorescent protein-labeled plasmodesmata to a depth of more than 40 μm beneath the resin surface. Using correlative light and electron microscopy of the phloem, we were able to locate the same FP-labeled sieve elements in semithin and ultrathin sections. Sections were amenable to antibody labeling, and allowed a combination of confocal and superresolution imaging (three-dimensional-structured illumination microscopy) on the same cells. These correlative imaging methods should find several uses in plant cell biology.The localization of fluorescent proteins (FPs) in cells and tissues has become one of the major tools in cell biology (Tsien, 1998; Shaner et al., 2005). Advances in confocal microscopy have meant that many proteins can be tagged with appropriate fluorescent markers and tracked as they move within and between cells (Chapman et al., 2005). Additional approaches involving photobleaching and photoactivation of FPs have opened up new avenues for exploring protein dynamics and turnover within cells (Lippincott-Schwartz et al., 2003). However, not all cells are amenable to live-cell imaging, which in plants is usually restricted to surface cells such as the leaf epidermis. An example is the phloem. The delicate nature of sieve elements and companion cells, which are under substantial hydrostatic pressure, has made studies of the fine structure of these cells particularly difficult (Knoblauch and van Bel, 1998). Despite this, significant advances have been made in imaging the phloem through inventive use of imaging protocols that allow living sieve elements to be observed as they translocate assimilates (for review, see Knoblauch and Oparka, 2012). However, determining the precise localization of the plethora of proteins located within the sieve element (SE)-companion cell (CC) complex remains a technical challenge. The phloem is the conduit for long-distance movement of macromolecules in plants, including viral genomes. For several viruses, the entry into the SE-CC complex is a crucial step that determines the capacity for long-distance movement. Identifying the cell types within the phloem that restrict the movement of some viruses is technically challenging due to the small size of phloem cells and their location deep within plant organs (Nelson and van Bel, 1998).The problems associated with imaging proteins in phloem tissues prompted us to explore methods for retaining the fluorescence of tagged proteins within tissues not normally amenable to confocal imaging. Previously, we used superresolution imaging techniques on fixed phloem tissues sectioned on a Vibroslice, providing information on the association between a viral movement protein (MP) and plasmodesmata (PD) within the SE-CC complex (Fitzgibbon et al., 2010). However, we wished to explore the same cells using correlative light and electron microscopy (CLEM), necessitating the development of methods that would allow sequential imaging of cells using fluorescence microscopy and transmission electron microscopy (TEM). To this end, we developed a protocol that retains fluorescent proteins through aldehyde fixation and resin embedding.In the last 10 years there has been significant interest in imaging fluorescent proteins in semithin sections (for review, see Cortese et al., 2009). Luby-Phelps and colleagues (2003) first described a method for retaining GFP fluorescence after fixation and resin embedding, but their method has not seen widespread application. The advent of superresolution imaging techniques (for review, see Bell and Oparka, 2011) has stimulated considerable interest in this field as the retention of fluorescence in thin sections means that cells can be imaged using techniques such as photoactivation light microscopy and stochastic optical reconstruction microscopy, allowing a lateral resolution of less than 10 nm to be achieved (Subach et al., 2009; Xu et al., 2012). A number of studies have described CLEM on the same cells (Luby-Phelps et al., 2003; Betzig et al., 2006; Watanabe et al., 2011). Advances in this field were reviewed recently (Jahn et al., 2012; see contributions in Muller-Reichert and Verkade, 2012). For example, Pfeiffer et al. (2003) were able to image SEs and CCs using high-pressure freezing, followed by freeze substitution in acetone and resin embedding. They then used thick optical sections of the tissue to locate cells of interest, and these were subsequently imaged using TEM. However, there have been few attempts to retain FPs in resin-embedded plant tissues. Thompson and Wolniak (2008) described the retention of mCitrine fused to an SE-plasma membrane protein in glycol methacrylate sections. The fluorescent signal was stable using wide-field microscopy but bleached rapidly under the confocal microscope.To date, cryosections have been the preferred choice for CLEM in mammalian tissues (Watanabe et al., 2011). Recently, Lee et al. (2011) chemically fixed Arabidopsis (Arabidopsis thaliana) seedlings, cut 50-μm sections, and examined these with a confocal microscope. After confocal mapping the sections were embedded in resin and thin sectioned. These authors were able to locate the same PD pit fields using confocal and TEM, providing important information on the localization of a novel PD protein. As general rule, cryosectioning is a time-consuming process, and subcellular details may be obscured in cryosections because of poor tissue contrast (Watanabe et al., 2011). A major problem with imaging FPs in resin sections has been that GFP and its derivatives are quenched by the acidic, oxidizing conditions required for fixation, dehydration, and embedding of delicate specimens (Tsien, 1998; Keene et al., 2008). Recently, however, Watanabe et al. (2011) explored the retention of FPs in Caenorhabditis elegans cells after fixation by different aldehydes and embedding media. These authors tested a range of resins and found that Citrine and tandem dimer Eos (tdEos) could be retained in methacrylate plastic sections. This material was difficult to cut thinly (<70 nm) compared to epoxy-based resins, but the authors obtained valuable correlative images using stimulated emission depletion microscopy and photoactivation light microscopy followed by low-voltage scanning electron microscopy.Because the retention of fluorescent proteins may differ between plant and animal cells, we explored a number of approaches for retaining fluorescent proteins in resin. Using low-temperature conditions (<8°C) during fixation and dehydration, we could retain strong fluorescence prior to tissue embedding. We also explored different embedding media and found that tissue could be effectively polymerized in London Resin (LR) White while retaining sufficient fluorescence for confocal imaging. Using water-dipping lenses, we were able to detect fluorescent proteins in optical sections up to 40 μm below the surface of the block face. Ultrathin sections from the same blocks showed good structural preservation and allowed CLEM. Subsequently, we cut 1- to 2-μm sections and examined these using confocal microscopy and three-dimensional-structured illumination microscopy (3D-SIM). Sections could be counterstained with a number of conventional fluorophores and antibodies, allowing colocalization studies. These simple methods allow successive imaging of FPs with the light and electron microscope, combining the strengths of both imaging platforms. We believe this approach will have significant utility for tissues that are recalcitrant to conventional confocal imaging.     

Molecular characterization of PVAS3: An asparagine synthetase gene from common bean prevailing in developing organs

In common bean, asparagine synthetase (AS; EC 6.3.5.4) is encoded by three members of a multigene family called PVAS1, PVAS2 and PVAS3. Two of these genes, PVAS1 and PVAS2, have been extensively studied, but little is known about PVAS3, remaining unclear whether PVAS3 function is redundant to the other AS or if it plays a specific role in Phaseolus vulgaris metabolism. In this work, we used a molecular approach to characterize PVAS3 expression and to gain some knowledge about its physiological function. We showed that, in contrast to PVAS1 and PVAS2, PVAS3 was expressed in all organs analyzed. Interestingly, PVAS3 was the AS gene most highly expressed in nodules, leaves and pods at the earliest stages of development, and its expression decreased as these organs developed. Expression of PVAS3 parallels the accumulation of AS protein and the asparagine content during the earliest stages of nodule, leaf and pod development, suggesting an important role for PVAS3 in the synthesis of asparagine in that period. Furthermore, PVAS3 was not repressed by light, as most class-II AS genes. Surprisingly, fertilization of nodulated plants with nitrate or ammonium, conditions that induce PVAS1 and PVAS2 and the shift from ureides to amide synthesis, repressed the expression of PVAS3 in nodules and roots. The possible implications of this regulation are discussed.     

Pollen analysis of honeys from the Mamora forest region (NW Morocco)

The present work refers to the pollen analysis of 35 Moroccan honey samples from the Mamora forest region. The samples were directly provided by the beekeepers, all professionals. The quantitative analysis showed that nectar is the main honey source in the samples studied, and that most honeys have a medium-low presence of botanical elements (BEN). The qualitative analysis of the samples showed the presence of 54 taxa belonging to 29 families, and 31 of the samples were unifloral: 24 of eucalyptus, 3 of orange, 2 of Loeflingia, 1 of mint and 1 of Ridolfia segetum. The eucalyptus honeys of the studied region are characterized by their high content in pollen grains (NGP; x¯=180000) and their low honeydew indicator elements content (HDE; x¯=4000); Plantago f. (present in 70% of the samples), Quercus f. and Brassicaceae (50%) and Ceratonia siliqua (30%) could be mentioned among the characteristic accompanying species of this honey type.     

Cocaine Inhibits Dopamine D2 Receptor Signaling via Sigma-1-D2 Receptor Heteromers

Under normal conditions the brain maintains a delicate balance between inputs of reward seeking controlled by neurons containing the D₁-like family of dopamine receptors and inputs of aversion coming from neurons containing the D₂-like family of dopamine receptors. Cocaine is able to subvert these balanced inputs by altering the cell signaling of these two pathways such that D₁ reward seeking pathway dominates. Here, we provide an explanation at the cellular and biochemical level how cocaine may achieve this. Exploring the effect of cocaine on dopamine D₂ receptors function, we present evidence of σ₁ receptor molecular and functional interaction with dopamine D₂ receptors. Using biophysical, biochemical, and cell biology approaches, we discovered that D₂ receptors (the long isoform of the D₂ receptor) can complex with σ₁ receptors, a result that is specific to D₂ receptors, as D₃ and D₄ receptors did not form heteromers. We demonstrate that the σ₁-D₂ receptor heteromers consist of higher order oligomers, are found in mouse striatum and that cocaine, by binding to σ₁ -D₂ receptor heteromers, inhibits downstream signaling in both cultured cells and in mouse striatum. In contrast, in striatum from σ₁ knockout animals these complexes are not found and this inhibition is not seen. Taken together, these data illuminate the mechanism by which the initial exposure to cocaine can inhibit signaling via D₂ receptor containing neurons, destabilizing the delicate signaling balance influencing drug seeking that emanates from the D₁ and D₂ receptor containing neurons in the brain.     

Enterobacteriaceae Isolated from the River Danube: Antibiotic Resistances,with a Focus on the Presence of ESBL and Carbapenemases

In a clinical setting it seems to be normal these days that a relevant proportion or even the majority of different bacterial species has already one or more acquired antibiotic resistances. Unfortunately, the overuse of antibiotics for livestock breeding and medicine has also altered the wild-type resistance profiles of many bacterial species in different environmental settings. As a matter of fact, getting in contact with resistant bacteria is no longer restricted to hospitals. Beside food and food production, the aquatic environment might also play an important role as reservoir and carrier. The aim of this study was the assessment of the resistance patterns of Escherichia coli and Klebsiella spp. out of surface water without prior enrichment and under non-selective culture conditions (for antibiotic resistance). In addition, the presence of clinically important extended spectrum beta lactamase (ESBL) and carbapenmase harboring Enterobacteriaceae should be investigated. During Joint Danube Survey 3 (2013), water samples were taken over the total course of the River Danube. Resistance testing was performed for 21 different antibiotics. Samples were additionally screened for ESBL or carbapenmase harboring Enterobacteriaceae. 39% of all isolated Escherichia coli and 15% of all Klebsiella spp. from the river Danube had at least one acquired resistance. Resistance was found against all tested antibiotics except tigecycline. Taking a look on the whole stretch of the River Danube the proportion of multiresistances did not differ significantly. In total, 35 ESBL harboring Enterobacteriaceae, 17 Escherichia coli, 13 Klebsiella pneumoniae and five Enterobacter spp. were isolated. One Klebsiella pneumoniae harboring NMD-1 carbapenmases and two Enterobacteriaceae with KPC-2 could be identified. Human generated antibiotic resistance is very common in E. coli and Klebsiella spp. in the River Danube. Even isolates with resistance patterns normally associated with intensive care units are present.     

The mutational dynamics of the SARS-CoV-2 virus in serial passages in vitro

Since its outbreak in 2019, Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) keeps surprising the medical community by evolving diverse immune escape mutations in a rapid and effective manner. To gain deeper insight into mutation frequency and dynamics, we isolated ten ancestral strains of SARS-CoV-2 and performed consecutive serial incubation in ten replications in a suitable and common cell line and subsequently analysed them using RT-qPCR and whole genome sequencing. Along those lines we hoped to gain fundamental insights into the evolutionary capacity of SARS-CoV-2 in vitro. Our results identified a series of adaptive genetic changes, ranging from unique convergent substitutional mutations and hitherto undescribed insertions. The region coding for spike proved to be a mutational hotspot, evolving a number of mutational changes including the already known substitutions at positions S:484 and S:501. We discussed the evolution of all specific adaptations as well as possible reasons for the seemingly inhomogeneous potential of SARS-CoV-2 in the adaptation to cell culture. The combination of serial passage in vitro with whole genome sequencing uncovers the immense mutational potential of some SARS-CoV-2 strains. The observed genetic changes of SARS-CoV-2 in vitro could not be explained solely by selectively neutral mutations but possibly resulted from the action of directional selection accumulating favourable genetic changes in the evolving variants, along the path of increasing potency of the strain. Competition among a high number of quasi-species in the SARS-CoV-2 in vitro population gene pool may reinforce directional selection and boost the speed of evolutionary change.