3‐D analysis of bacterial cell‐(iron)mineral aggregates formed during Fe(II) oxidation by the nitrate‐reducing Acidovorax sp. strain BoFeN1 using complementary microscopy tomography approaches

The formation of cell‐(iron)mineral aggregates as a consequence of bacterial iron oxidation is an environmentally widespread process with a number of implications for processes such as sorption and coprecipitation of contaminants and nutrients. Whereas the overall appearance of such aggregates is easily accessible using 2‐D microscopy techniques, the 3‐D and internal structure remain obscure. In this study, we examined the 3‐D structure of cell‐(iron)mineral aggregates formed during Fe(II) oxidation by the nitrate‐reducing Acidovorax sp. strain BoFeN1 using a combination of advanced 3‐D microscopy techniques. We obtained 3‐D structural and chemical information on different cellular encrustation patterns at high spatial resolution (4–200 nm, depending on the method): more specifically, (1) cells free of iron minerals, (2) periplasm filled with iron minerals, (3) spike‐ or platelet‐shaped iron mineral structures, (4) bulky structures on the cell surface, (5) extracellular iron mineral shell structures, (6) cells with iron mineral filled cytoplasm, and (7) agglomerations of extracellular globular structures. In addition to structural information, chemical nanotomography suggests a dominant role of extracellular polymeric substances (EPS) in controlling the formation of cell‐(iron)mineral aggregates. Furthermore, samples in their hydrated state showed cell‐(iron)mineral aggregates in pristine conditions free of preparation (i.e., drying/dehydration) artifacts. All these results were obtained using 3‐D microscopy techniques such as focused ion beam (FIB)/scanning electron microscopy (SEM) tomography, transmission electron microscopy (TEM) tomography, scanning transmission (soft) X‐ray microscopy (STXM) tomography, and confocal laser scanning microscopy (CLSM). It turned out that, due to the various different contrast mechanisms of the individual approaches, and due to the required sample preparation steps, only the combination of these techniques was able to provide a comprehensive understanding of structure and composition of the various Fe‐precipitates and their association with bacterial cells and EPS.     

Combination of fluorescent in situ hybridization and microautoradiography-a new tool for structure-function analyses in microbial ecology

A new microscopic method for simultaneously determining in situ the identities, activities, and specific substrate uptake profiles of individual bacterial cells within complex microbial communities was developed by combining fluorescent in situ hybridization (FISH) performed with rRNA-targeted oligonucleotide probes and microautoradiography. This method was evaluated by using defined artificial mixtures of Escherichia coli and Herpetosiphon aurantiacus under aerobic incubation conditions with added [3H]glucose. Subsequently, we were able to demonstrate the potential of this method by visualizing the uptake of organic and inorganic radiolabeled substrates ([14C]acetate, [14C]butyrate, [14C]bicarbonate, and 33Pi) in probe-defined populations from complex activated sludge microbial communities by using aerobic incubation conditions and anaerobic incubation conditions (with and without nitrate). For both defined cell mixtures and activated sludge, the method proved to be useful for simultaneous identification and analysis of the uptake of labeled substrates under the different experimental conditions used. Optimal results were obtained when fluorescently labeled oligonucleotides were applied prior to the microautoradiographic developing procedure. For single-cell resolution of FISH and microautoradiographic signals within activated sludge flocs, cryosectioned sample material was examined with a confocal laser scanning microscope. The combination of in situ rRNA hybridization techniques, cryosectioning, microautoradiography, and confocal laser scanning microscopy provides a unique opportunity for obtaining cultivation-independent insights into the structure and function of bacterial communities.     

Dynamics in bacterial surface properties of a natural bacterial community in the coastal North Sea during a spring phytoplankton bloom

The hydrophilic and hydrophobic properties of single cells of natural bacterioplankton communities were determined using a recently developed staining method combined with confocal laser scanning microscopy and advanced image analysis. On an average, about 50% of the bacterial cell area was covered by hydrophobic and only 16% by hydrophilic properties, while about 72% was covered by the genome. However, the size of these properties was independent of the bacterial cell size. Bacterial hydrophobicity was positively correlated with ambient NH(4)(+) concentrations and negatively correlated with overall bacterial abundance. The expression of hydrophilicity was more dynamic. Over the spring phytoplankton bloom, the bacterioplankton ratio(phil/phob) repeatedly reached highest values shortly before peaks in bacterioplankton abundance were observed, indicating a direct and fast response of bacterial surface properties, especially hydrophilicity, to changing environmental conditions. Compared to bacterial strains, recently studied with the same method, cells of marine bacterioplankton communities are much smaller and less frequently covered by hydrophobic or hydrophilic properties. While the percentage area covered by the genome is essentially the same, the percentage area covered by hydrophobic or hydrophilic properties is much smaller.     

Residual Structure of Streptococcus mutans Biofilm following Complete Disinfection Favors Secondary Bacterial Adhesion and Biofilm Re-Development

Chemical disinfection of oral biofilms often leaves biofilm structures intact. This study aimed to examine whether the residual structure promotes secondary bacterial adhesion. Streptococcus mutans biofilms generated on resin-composite disks in a rotating disc reactor were disinfected completely with 70% isopropyl alcohol, and were again cultured in the same reactor after resupplying with the same bacterial solution. Specimens were subjected to fluorescence confocal laser scanning microscopy, viable cell counts and PCR-Invader assay in order to observe and quantify secondarily adhered cells. Fluorescence microscopic analysis, particularly after longitudinal cryosectioning, demonstrated stratified patterns of viable cells on the disinfected biofilm structure. Viable cell counts of test specimens were significantly higher than those of controls, and increased according to the amount of residual structure and culture period. Linear regression analysis exhibited a high correlation between viable and total cell counts. It was concluded that disinfected biofilm structures favored secondary bacterial adhesion.     

Method for enumeration of 5-cyano-2,3-ditoyl tetrazolium chloride (CTC)-active cells and cell-specific CTC activity of benthic bacteria in riverine, estuarine and coastal sediments

Bacteria are the most abundant and active organisms in marine sediments and are critical for nutrient cycling and as a food source to many benthic and pelagic organisms. Bacteria are found both as free-living cells and as particle-associated cells, which can make investigations of these communities difficult. We found that common procedures for extracting bacteria from sediments leave the bacteria clay particle-associated and the clay particles clump, which reduce the reproducibility of direct counts. We optimized a sonication/surfactant method that produces a homogeneous suspension of bacterial cells against a uniform background of clay particles, which results in reproducible samples for epifluorescence microscopy. We developed a method to estimate CTC-positive cells and cell-specific CTC content in intact cores of surficial sediment communities from riverine, estuarine and coastal sites. Benthic bacterial abundances averaged 4.9x10(8) cells/g dry wt sediments in Apalachicola River, Florida sediments, 4.9-13.8x10(9) cells/g dry wt sediments in a variety of Apalachicola Bay sediments and 3.6x10(8) cells/g dry weight in shallow, anoxic Gulf of Mexico sediments. Percent CTC-positive cells ranged from low values of 9-10% CTC-positive cells in Apalachicola River and Apalachicola Bay sediments to high values of 25% CTC-positive cells in anoxic Gulf of Mexico sediments. After correction for abiotic CTC reduction and chlorophyll interference, estimates of cell-specific CTC reduction ranged from 0.15 to 0.55 fmol CTC(red)/active cell in the Apalachicola Bay sediments to 1.6 to 3.8 fmol CTC(red)/active cell in anoxic Gulf of Mexico sediments.     

Confocal imaging of in situ natural microbial communities and their extracellular polymeric secretions using Nanoplast resin

A novel method using excision and fixation in Nanoplast, a hydrophilic embedding resin, allows confocal imaging of natural microbial communities and their extracellular polymeric secretions (EPS) while in situ. Prestaining with fluorescent probes permits the observation of specific cellular and extracellular components. Marine stromatolite sediments were examined using this method. Optical sectioning using confocal laser scanning microscopy (CLSM) permitted high-resolution imaging through sediments. Delicate arrangements of the EPS that are associated with sedimentary microbial biofilms were imaged using a fluorescein isothiocyanate (FITC)-labeled lectin (concanavalin-A) probe. Close microspatial associations of heterotrophic bacteria cells and autotrophic cyanobacteria cells were also observed. The nanoplast resin produces no detectable autofluorescence. Further coupling of multi-photon scanning laser microscopy (2P-LSM) with a conventional single photon CLSM allowed concurrent imaging of DAPI-labeled microbial cells, FITC-labeled EPS and autofluorescent carbonate sand grains. The multi-photon infrared laser permits deep (approximately 1 mm) penetration of samples and the excitation of DAPI, which normally requires UV-excitation with minimal disturbance to samples. The unique combination of Nanoplast with fluorescent probes, CLSM and 2P-LSM allows for the preservation and imaging of natural microbial communities in their in situ state, a method easily adapted for examinations of other microbial systems.     

Correction to: Intracellular bacteria are common and taxonomically diverse in cultured and in hospite algal endosymbionts of coral reefs

Corals house a variety of microorganisms which they depend on for their survival, including endosymbiotic dinoflagellates (Symbiodiniaceae) and bacteria. While cnidarian–microorganism interactions are widely studied, Symbiodiniaceae–bacteria interactions are only just beginning to receive attention. Here, we describe the localization and composition of the bacterial communities associated with cultures of 11 Symbiodiniaceae strains from nine species and six genera. Three-dimensional confocal laser scanning and electron microscopy revealed bacteria are present inside the Symbiodiniaceae cells as well as closely associated with their external cell surface. Bacterial pure cultures and 16S rRNA gene metabarcoding from Symbiodiniaceae cultures highlighted distinct and highly diverse bacterial communities occur intracellularly, closely associated with the Symbiodiniaceae outer cell surface and loosely associated (i.e., in the surrounding culture media). The intracellular bacteria are highly conserved across Symbiodiniaceae species, suggesting they may be involved in Symbiodiniaceae physiology. Our findings provide unique new insights into the biology of Symbiodiniaceae.Subject terms: Symbiosis, Microbiome, Marine microbiology     

Impact of Nutrient Composition on a Degradative Biofilm Community

A microbial community was cultivated in flow cells with 2,4,6-trichlorobenzoic acid (2,4,6-TCB) as sole carbon and energy source and was examined with scanning confocal laser microscopy and fluorescent molecular probes. The biofilm community which developed under these conditions exhibited a characteristic architecture, including a basal cell layer and conspicuous mounds of bacterial cells and polymer (approximately 20 to 30 (mu)m high and 25 to 40 (mu)m in diameter) occurring at 20- to 200-(mu)m intervals. When biofilms grown on 2,4,6-TCB were shifted to a labile, nonchlorinated carbon source (Trypticase soy broth), the biofilms underwent an architectural change which included the loss of mound structures and the formation of a more homogeneous biofilm. Neutrally charged fluorescent dextrans, which upon hydration become cationic, were observed to bind to mounds, as well as to the basal cell layer, in 14-day biofilms. In contrast, polyanionic dextrans bound only to the basal cell layer, indicating that this material incorporated sites with both positive and negative charge. The results from this study indicate that nutrient composition has a significant impact on both the architecture and the physicochemistry of degradative biofilm communities.     

Location of haemagglutinin in bacterial cells of Fusobacterium necrophorum subsp. necrophorum.

The location of haemagglutinin (HA) of Fusobacterium necrophorum subsp. necrophorum VPI 2891 strain was investigated by immunofluorescence, confocal laser scan microscopy and immunoelectron microscopy. The immunofluorescence study demonstrated the fluorescence specific for the HA on the bacterial cells and confocal laser scan microscopy indicated similar fluorescence around the cross section of the bacterial cell. The immunoelectron microscopic study also revealed that the protein A-gold conjugates were located around the bacterial surfaces. These findings suggest that HA is one of the components of the cell surfaces of F. necrophorum subsp, necrophorum.     

New data on structures formed by the FtsZ protein during the cell division process in <Emphasis Type="Italic">Escherichia coli</Emphasis> obtained using the localization microscopy method

The FtsZ protein, a bacterial tubulin homolog, is one of the key proteins in bacterial cell division, forming a contractile Z-ring in the middle of the dividing cell. In the present study, immunofluorescence staining, in combination with the localization microscopy method, was used for visualization of the structures formed by unlabelled FtsZ in Escherrichia coli cells. The techniques employed allowed reconstruction of the multistep mechanism of formation of FtsZ structures during the cytokinesis process. New data were obtained confirming the hypothesis that FtsZ is a helixlike structure that constricts during the division, producing constriction between the daughter cells.     

3D-SIM结构照明超分辨率显微镜实现蛋白质在植物亚细胞器内的定位

基因表达产物蛋白质的亚细胞定位是解析基因生物学功能的重要证据之一。近年来出现的超分辨率光学成像技术已成功应用于人类和动物细胞中,预示着显微成像技术继激光共聚焦技术后的又一重要进步。由于植物细胞的特殊性和成像技术的研发取向,超分辨率光学成像技术在植物细胞蛋白质亚细胞定位的应用尚未见报道。该研究利用Delta Vision OMX显微镜技术,克服了叶绿体基粒中叶绿素自发荧光与融合蛋白荧光不易区分的缺陷,解决了受分辨率局限无法将植物细胞中蛋白质在亚细胞器内可视化精确定位的技术难题,成功地将植物蔗糖合成酶Zm SUS-SH1定位在烟草表皮细胞叶绿体基粒周围。该研究同时建立了一套基于撕片制片法的简便OMX显微镜制片方法,并针对OMX显微成像技术在植物细胞中蛋白质亚细胞定位的应用进行了讨论。     

Three-dimensional organization of actin cytoskeleton and podosomal contact structures in neoplastic cells in vitro

In spontaneously metastasizing rat RPS sarcoma cells, a 3D structure of oblique F-actin cables was observed which was associated with active cell migration in vitro. This led us to further comparative investigations of several other neoplastic and normal cell populations in vitro for F-actin structures using confocal laser scanning microscopy (CLSM). Various forms of F-actin cytoskeleton were observed and the incidence of podosome-related contact structures appeared to be associated with malignancy, interpreted as metastatic capacity.     

Inner Structure of Intact Chloroplasts Observed by a Low Temperature Laser Scanning Microscope

Inner structure of isolated intact chloroplasts was observed for the first time by a method of laser scanning microscopy at the temperature of liquid nitrogen at 77 K. The microscope, based on gradient index optics, has a maximum resolution of 440 nm at the wavelength of 650 nm. Chloroplasts were excited into the Q-band of chlorophyll b by a krypton laser line at 647.6 nm and fluorescence was detected using two different interference filters. The 680 nm interference filter detects the regions where photosystem (PS) 2 mainly occurs, the 730 nm interference filter detects domains with predominant location of PS1. Since PS1 occurs mainly in stroma lamellae, whereas PS2 occurs mainly in grana regions we were able to view the structure of thylakoid membrane in isolated intact chloroplast that is the closest to in vivo state.     

A comparison of methods for morphological studies of cultured cells

Summary A number of fixation methods for different types of cells in culture were compared, and the best preservation of nuclear and cytoplasmic details was obtained by fixation with Bouin's solution for 15 min, prior to staining with hematoxylin and eosin. All of the fixatives, including Bouin's solution, damaged various structures, notably the peripheral glas-attached cytoplasm and the intercellular connections. Micrographs obtained by bright field, phase contrast, and interference contrast (Nomarski) microscopy are presented. Much more realistic pictures, bringing out details not observed after fixation and staining, were obtained by Nomarski microscopy of living, unfixed cultures. Most conspicuous were numerous thin, cytoplasmic, cilia-like extensions, concentrated on the glass-attached peripheral margins, which were also visible on other cell surfaces and as intercellular connections. These structures were most characteristic of SV40-transformed human amnion cells. Although fixation and staining emphasize certain cell components (for example, inclusion bodies), many aspects of cellular morphology are better demonstrated by observing living cells by interference microscopy or by Nomarski interference contrast microscopy. Surface features of unfixed cells, seen by Nomarski interference contrast microscopy, were similar to the surface features of glutaraldehyde-osmium tetroxide-fixed cells studied as metallic replicas in the electron microscope. Supported in part by National Cancer Institute Research Grant CA-08748 and contributions from the Albert Soiland Cancer Foundation.     

Direct observations on generative cells isolated from pollen grains of Haemanthus katherinae baker

Generative cells from mature pollen grains of Haemanthus katherinae Baker (African blood lily) were isolated by means of a simple squash method and observed by differential interference contrast (DIC), fluorescence and polarizing microscopy. The isolated cells appeared structurally similar to those observed in vivo and gave no evidence of a typical cell wall. Their viability was confirmed using the fluorescein diacetate test. The cell shape changed rapidly as the sucrose concentration of the medium was varied. The squash method of isolating generative cells holds promise for the direct and experimental study of these cells, especially in the living state.Abbreviations FDA Fluorescein diacetate - PAS Periodic-acid-Schiff - DIC differential interference contrast - NA numerical aperture     

Single-Molecule Imaging on Living Bacterial Cell Surface by High-Speed AFM

Advances in microscopy have contributed to many biologic discoveries. Electron microscopic techniques such as cryo-electron tomography are remarkable tools for imaging the interiors of bacterial cells in the near-native state, whereas optical microscopic techniques such as fluorescence imaging are useful for following the dynamics of specific single molecules in living cells. Neither technique, however, can be used to visualize the structural dynamics of a single molecule at high resolution in living cells. In the present study, we used high-speed atomic force microscopy (HS-AFM) to image the molecular dynamics of living bacterial cell surfaces. HS-AFM visualizes the dynamic molecular processes of isolated proteins at sub-molecular resolution without the need for complicated sample preparation. In the present study, magnetotactic bacterial cells were anchored in liquid medium on substrate modified by poly-l-lysine and glutaraldehyde. High-resolution HS-AFM images of live cell surfaces showed that the bacterial outer membrane was covered with a net-like structure comprising holes and the hole rims framing them. Furthermore, HS-AFM captured the dynamic movement of the surface ultrastructure, showing that the holes in the net-like structure slowly diffused in the cell surface. Nano-dissection revealed that porin trimers constitute the net-like structure. Here, we report for the first time the direct observation of dynamic molecular architectures on a live cell surface using HS-AFM.     

Microbial consortia of bacteria and fungi with focus on the lichen symbiosis

The investigation of fungal–bacterial interactions is an emerging field of research applying tools of modern microbial ecology. Studies have previously focused on the mycorrhizosphere, but in past decade, the role of bacteria in other fungal niches has been increasingly evaluated. This review presents recent progress in the understanding of fungal–bacterial interactions and contains a special focus on lichen symbioses. Lichens are traditionally considered as mutualisms between fungi and photoautotrophic species, but recent molecular approaches have revealed that lichens also harbour diverse microbial communities. Using modern DNA/RNA-based and microscopic techniques (e.g. FISH and confocal laser scanning microscopy) we are now able to analyse the abundance, composition, and structure of microbial communities in the lichen holobiont. Lichen-associated microbial communities consist of diverse taxonomic groups; the majority of bacteria belong to Alphaproteobacteria. Microbial communities can form biofilm-like structures on specific parts of the lichen thallus. Until now, the function and interaction within the microbial consortia is not fully understood. The functions displayed mainly by culturable strains suggest that bacteria have lytic activities, complement the nitrogen budget and produce bioactive substances, including hormones and antibiotics. Bacterial contribution to the lichen symbiosis is perhaps not restricted to one particular function in the lichen system, but supports a complex functional network which remains to be studied in greater detail.     

Phylogenetic Composition, Spatial Structure, and Dynamics of Lotic Bacterial Biofilms Investigated by Fluorescent in Situ Hybridization and Confocal Laser Scanning Microscopy

Abstract The phylogenetic composition, three-dimensional structure and dynamics of bacterial communities in river biofilms generated in a rotating annular reactor system were studied by fluorescent in situ hybridization (FISH) and confocal laser scanning microscopy (CLSM). Biofilms grew on independently removable polycarbonate slides exposed in the reactor system with natural river water as inoculum and sole nutrient and carbon source. The microbial biofilm community developed from attached single cells and distinct microcolonies via a more confluent structure characterized by various filamentous bacteria to a mature biofilm rich in polymeric material with fewer cells on a per-area basis after 56 days. During the different stages of biofilm development, characteristic microcolonies and cell morphotypes could be identified as typical features of the investigated lotic biofilms. In situ analysis using a comprehensive suite of rRNA-targeted probes visualized individual cells within the alpha-, beta-, and gamma-Proteobacteria as well as the Cytophaga–Flavobacterium group as major parts of the attached community. The relative abundance of these major groups was determined by using digital image analysis to measure specific cell numbers as well as specific cell area after in situ probing. Within the lotic biofilm community, 87% of the whole bacterial cell area and 79% of the total cell counts hybridized with a Bacteria specific probe. During initial biofilm development, beta-Proteobacteria dominated the bacterial population. This was followed by a rapid increase of alpha-Proteobacteria and bacteria affiliated to the Cytophaga–Flavobacterium group. In mature biofilms, alpha-Proteobacteria and Cytophaga–Flavobacteria continued to be the prevalent bacterial groups. Beta-Proteobacteria constituted the morphologically most diverse group within the biofilm communities, and more narrow phylogenetic staining revealed the importance of distinct phylotypes within the beta1-Proteobacteria for the composition of the microbial community. The presence of sulfate-reducing bacteria affiliated to the Desulfovibrionaceae and Desulfobacteriaceae confirmed the range of metabolic potential within the lotic biofilms. Received: 24 September 1998; Accepted: 17 February 1999     

A soil-based microbial biofilm exposed to 2,4-D: bacterial community development and establishment of conjugative plasmid pJP4

A soil suspension was used as a source to initiate the development of microbial communities in flow cells irrigated with 2,4-dichlorophenoxyacetic acid (2,4-D) (25 microg ml(-1)). Culturable bacterial members of the community were identified by 16S rRNA gene sequencing and found to be members of the genera Pseudomonas, Burkholderia, Collimonas and Rhodococcus. A 2,4-D degrading donor strain, Pseudomonas putida SM1443 (pJP4::gfp), was inoculated into flow cell chambers containing 2-day old biofilm communities. Transfer of pJP4::gfp from the donor to the bacterial community was detectable as GFP fluorescing cells and images were captured using confocal scanning laser microscopy (GFP fluorescence was repressed in the donor due to the presence of a chromosomally located lacI(q) repressor gene). Approximately 5-10 transconjugant microcolonies, 20-40 microm in diameter, could be seen to develop in each chamber. A 2,4-D degrading transconjugant strain was isolated from the flow cell system belonging to the genus Burkholderia.     

In situ PCR for visualization of microscale distribution of specific genes and gene products in prokaryotic communities.

Obtaining information on the genetic capabilities and phylogenetic affinities of individual prokaryotic cells within natural communities is a high priority in the fields of microbial ecology, microbial biogeochemistry, and applied microbiology, among others. A method for prokaryotic in situ PCR (PI-PCR), a technique which will allow single cells within complex mixtures to be identified and characterized genetically, is presented here. The method involves amplification of specific nuclei acid sequences inside intact prokaryotic cells followed by color or fluorescence detection of the localized PCR product via bright-field or epifluorescence microscopy. Prokaryotic DNA and mRNA were both used successfully as targets for PI-PCR. We demonstrate the use of PI-PCR to identify nahA-positive cells in mixtures of bacterial isolates and in model marine bacterial communities.