Scanning confocal laser microscopy (SCLM) was used to visualize fully hydrated microbial biofilms. The improved rejection of out-of-focus haze and the increased resolution of SCLM made it preferable to conventional phase microscopy for the analysis of living biofflms. The extent of image improvement was dependent on the characteristics of individual biofilms and was most apparent when films were dispersed in three dimensions, when they were thick, and when they contained a high number of cells. SCLM optical sections were amenable to quantitative computer-enhanced microscopy analyses, with minimal interference originating from overlying or underlying cell material. By using SCLM in conjunction with viable negative fluorescence staining techniques, horizontal (xy) and sagittal (xz) sections of intact bioMflms of Pseudomonas aeruginosa, Pseudomonasfluorescens, and Vibrio parahaemolyticus were obtained. These optical sections were then analyzed by image-processing techniques to assess the distribution of cellular and noncellular areas within the biofilm matrices. The Pseudomonas biofllms were most cell dense at their attachment surfaces and became increasingly diffuse near their outer regions, whereas the Vibrio biofilms exhibited the opposite trend. BioMflms consisting of different species exhibited distinctive arrangements of the major biofilm structural components (cellular and extracellular materials and space). In general, biofilms were found to be highly hydrated, open structures composed of 73 to 98% extracellular materials and space. The use of xz sectioning revealed more detail of biofilm structure, including the presence of large void spaces within the Vibrio biofilms. In addition, three-dimensional reconstructions of biofilms were constructed and were displayed as stereo pairs. Application of the concepts of architectural analysis to mixed-or pure-species biofilms will allow detailed examination of the relationships among biofilm structure, adaptation, and response to stress.Biofilms are organized multicellular systems with structural and functional architecture which influence metabolic processes, response to nutrients, resistance to antimicrobial agents, predation, and other factors. Structural studies of microbial biofilms and their formation have been performed by using light microscopy to examine wet mounts (16,23), by using transmission and scanning electron microscopy (12)(13)(14)(15)24), and by developing conceptual models (12). Electron microscopy techniques are laborious and can produce artifacts resulting from sample preparation and limit three-dimensional (3D) reconstruction of biofilms. Light microscopy used in conjunction with computer-enhanced microscopy (CEM) is an effective tool, but it is best applied during the early phases of biofilm development (7,16,19,20). Scanning confocal laser microscopy (SCLM) offers the promise of detailed visualization of thick microbiological samples in cases in which application of traditional phase or fluorescence microscopy is limited. SCLM allows eliminat...
Background: Only recently has the environment been clearly implicated in the risk of antibiotic resistance to clinical outcome, but to date there have been few documented approaches to formally assess these risks.Objective: We examined possible approaches and sought to identify research needs to enable human health risk assessments (HHRA) that focus on the role of the environment in the failure of antibiotic treatment caused by antibiotic-resistant pathogens.Methods: The authors participated in a workshop held 4–8 March 2012 in Québec, Canada, to define the scope and objectives of an environmental assessment of antibiotic-resistance risks to human health. We focused on key elements of environmental-resistance-development “hot spots,” exposure assessment (unrelated to food), and dose response to characterize risks that may improve antibiotic-resistance management options.Discussion: Various novel aspects to traditional risk assessments were identified to enable an assessment of environmental antibiotic resistance. These include a) accounting for an added selective pressure on the environmental resistome that, over time, allows for development of antibiotic-resistant bacteria (ARB); b) identifying and describing rates of horizontal gene transfer (HGT) in the relevant environmental “hot spot” compartments; and c) modifying traditional dose–response approaches to address doses of ARB for various health outcomes and pathways.Conclusions: We propose that environmental aspects of antibiotic-resistance development be included in the processes of any HHRA addressing ARB. Because of limited available data, a multicriteria decision analysis approach would be a useful way to undertake an HHRA of environmental antibiotic resistance that informs risk managers.Citation: Ashbolt NJ, Amézquita A, Backhaus T, Borriello P, Brandt KK, Collignon P, Coors A, Finley R, Gaze WH, Heberer T, Lawrence JR, Larsson DG, McEwen SA, Ryan JJ, Schönfeld J, Silley P, Snape JR, Van den Eede C, Topp E. 2013. Human health risk assessment (HHRA) for environmental development and transfer of antibiotic resistance. Environ Health Perspect 121:993–1001; http://dx.doi.org/10.1289/ehp.1206316
Confocal laser scanning microscopy (CLSM), transmission electron microscopy (TEM), and soft X-ray scanning transmission X-ray microscopy (STXM) were used to map the distribution of macromolecular subcomponents (e.g., polysaccharides, proteins, lipids, and nucleic acids) of biofilm cells and matrix. The biofilms were developed from river water supplemented with methanol, and although they comprised a complex microbial community, the biofilms were dominated by heterotrophic bacteria. TEM provided the highestresolution structural imaging, CLSM provided detailed compositional information when used in conjunction with molecular probes, and STXM provided compositional mapping of macromolecule distributions without the addition of probes. By examining exactly the same region of a sample with combinations of these techniques (STXM with CLSM and STXM with TEM), we demonstrate that this combination of multimicroscopy analysis can be used to create a detailed correlative map of biofilm structure and composition. We are using these correlative techniques to improve our understanding of the biochemical basis for biofilm organization and to assist studies intended to investigate and optimize biofilms for environmental remediation applications.Scanning transmission X-ray microscopy (STXM) (1, 2), which uses near-edge X-ray absorption spectroscopy (NEXAFS) as its contrast mechanism, is a powerful new tool that can be applied to fully hydrated biological materials. This is possible due to the ability of soft X rays to penetrate water, the presence of suitable analytical core edges in the soft X-ray region, and reduced radiation damage (compared to that caused by electron beam techniques). Soft X rays also provide spatial resolution of better than 50 nm, which is suitable for imaging bacteria and bacterial biofilms. The spectral resolution is on the order of 100 meV, which in combination with their intrinsic spectral properties is sufficient to provide good differentiation of classes of biomolecules (26, 43; X. Zhang, T. Araki, A. P. Hitchcock, J. R. Lawrence, and G. G. Leppard, unpublished data). Through the application of tunable soft X rays and appropriate analysis of X-ray absorption spectra in the form of NEXAFS image sequences (15), quantitative chemical mapping at a spatial scale below 50 nm may be achieved. With use of the appropriate spectral range, NEXAFS microscopy provides detailed, quantitative speciation and elemental analysis with parts-per-thousand local and parts-per-million global sensitivities with transmission detection. Soft X-ray microscopy provides a combination of suitable spatial resolution and chemical information at a microscale. In addition, soft X rays interact with nearly all elements and also allow mapping of chemical species based on bonding structure (2). Further, the method uses the intrinsic X-ray absorption properties of the sample, thus eliminating the need for addition of reflective, absorptive, or fluorescent probes and markers that may introduce artifacts or complicate interpretation. It is...
A scanning transmission X-ray microscope illuminated with synchrotron light was used to investigate the speciation and spatial distributions of metals in a microbial biofilm cultivated from river water. Metal 2p absorption edge signals were used to provide metal speciation (through shapes of the absorption spectra) and quantitative spatial distributions of the metal species. This paper presents sample data and describes methods for extracting quantitative maps of metal species from image sequences recorded in the region of the metal 2p edges. Comparisons were made with biochemical characterization of the same region using images recorded at the C 1s and O 1s edges. The method is applied to detailed quantitative analysis of ferrous and ferric iron in a river biofilm, in concert with mapping Ni-(II) and Mn(II) species in the same region. The distributions of the metal species are discussed in the context of the biofilm structure. These results demonstrate that soft X-ray STXM measurements at the metal 2p absorption edges can be used to speciate metals and to provide quantitative spatial distribution maps for metal species in environmental samples with 50 nm spatial resolution.
Scientific imaging represents an important and accepted research tool for the analysis and understanding of complex natural systems. Apart from traditional microscopic techniques such as light and electron microscopy, new advanced techniques have been established including laser scanning microscopy (LSM), magnetic resonance imaging (MRI) and scanning transmission X-ray microscopy (STXM). These new techniques allow in situ analysis of the structure, composition, processes and dynamics of microbial communities. The three techniques open up quantitative analytical imaging possibilities that were, until a few years ago, impossible. The microscopic techniques represent powerful tools for examination of mixed environmental microbial communities usually encountered in the form of aggregates and films. As a consequence, LSM, MRI and STXM are being used in order to study complex microbial biofilm systems. This mini review provides a short outline of the more recent applications with the intention to stimulate new research and imaging approaches in microbiology.
The Athabasca oil sands deposit is the largest reservoir of crude bitumen in the world. Recently, the soaring demand for oil and the availability of modern bitumen extraction technology have heightened exploitation of this reservoir and the potential unintended consequences of pollution in the Athabasca River. The main objective of the present study was to evaluate the potential impacts of oil sands mining on neighboring aquatic microbial community structure. Microbial communities were sampled from sediments in the Athabasca River and its tributaries as well as in oil sands tailings ponds. Bacterial and archaeal 16S rRNA genes were amplified and sequenced using next-generation sequencing technology (454 and Ion Torrent). Sediments were also analyzed for a variety of chemical and physical characteristics. Microbial communities in the fine tailings of the tailings ponds were strikingly distinct from those in the Athabasca River and tributary sediments. Microbial communities in sediments taken close to tailings ponds were more similar to those in the fine tailings of the tailings ponds than to the ones from sediments further away. Additionally, bacterial diversity was significantly lower in tailings pond sediments. Several taxonomic groups of Bacteria and Archaea showed significant correlations with the concentrations of different contaminants, highlighting their potential as bioindicators. We also extensively validated Ion Torrent sequencing in the context of environmental studies by comparing Ion Torrent and 454 data sets and by analyzing control samples.
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