Mechanism of gram variability in select bacteria.

Gram stains were performed on strains of Actinomyces bovis, Actinomyces viscosus, Arthrobacter globiformis, Bacillus brevis, Butyrivibrio fibrisolvens, Clostridium tetani, Clostridium thermosaccharolyticum, Corynebacterium parvum, Mycobacterium phlei, and Propionibacterium acnes, using a modified Gram regimen that allowed the staining process to be observed by electron microscopy (J. A. Davies, G. K. Anderson, T. J. Beveridge, and H. C. Clark, J. Bacteriol. 156:837-845, 1983). Furthermore, since a platinum salt replaced the iodine mordant of the Gram stain, energy-dispersive X-ray spectroscopy could evaluate the stain intensity and location by monitoring the platinum signal. These gram-variable bacteria could be split into two groups on the basis of their staining responses. In the Actinomyces-Arthrobacter-Corynebacterium-Mycobacterium-Propionibacterium group, few cells became gram negative until the exponential growth phase; by mid-exponential phase, 10 to 30% of the cells were gram negative. The cells that became gram negative were a select population of the culture, had initiated septum formation, and were more fragile to the stress of the Gram stain at the division site. As cultures aged to stationary phase, there was a relatively slight increase toward gram negativity (now 15 to 40%) due to the increased lysis of nondividing cells by means of lesions in the side walls; these cells maintained their rod shape but stained gram negative. Those in the Bacillus-Butyrivibrio-Clostridium group also became gram negative as cultures aged but by a separate set of events. These bacteria possessed more complex walls, since they were covered by an S layer. They stained gram positive during lag and the initial exponential growth phases, but as doubling times increased, the wall fabric underlying the S layer became noticeably thinner and diffuse, and the cells became more fragile to the Gram stain. By stationary phase, these cultures were virtually gram negative.     

Gram Characteristics and Wall Ultrastructure of Arthrobacter crystallopoietes During Coccus-Rod Morphogenesis

Arthrobacter crystallopoietes growing exponentially as cocci were changed to rods by adding succinate to the medium. Cells were sampled before, during, and after this transition for Gram-staining and ultrastructural studies. Cells were Gram stained by the standardized method of Bartholomew, and all samples were fixed and prepared for thin sectioning in an identical manner. Cocci were gram positive, and thin sections demonstrated a gram-positive type of cell wall having an average thickness of 31 nm. Cells sampled during morphogenesis appeared as cocci with most having a single rodlike projection. The coccus portion of these transition cells was gram positive and bound by a gram-positive type of wall having an average thickness of 29 nm. The rodlike projection of the transition cells appeared to be gram negative; it was also surrounded by a gram-positive type of wall, but its average thickness was only 22 nm. Gram-negative rods of the type species, Arthrobacter globiformis, were also examined and found to produce a gram-positive type of wall with a 19-nm average thickness. Evidence for the trilaminar region, characteristic of most gram-negative bacterial cell walls, was totally lacking in both species. These results suggest that variations in cell wall thickness may be an important contributing factor to the variable Gram-staining characteristics of this genus.     

A Fluorescent Gram Stain for Flow Cytometry and Epifluorescence Microscopy

The fluorescent nucleic acid binding dyes hexidium iodide (HI) and SYTO 13 were used in combination as a Gram stain for unfixed organisms in suspension. HI penetrated gram-positive but not gram-negative organisms, whereas SYTO 13 penetrated both. When the dyes were used together, gram-negative organisms were rendered green fluorescent by SYTO 13; conversely, gram-positive organisms were rendered red-orange fluorescent by HI, which simultaneously quenched SYTO 13 green fluorescence. The technique correctly predicted the Gram status of 45 strains of clinically relevant organisms, including several known to be gram variable. In addition, representative strains of gram-positive anaerobic organisms, normally decolorized during the traditional Gram stain procedure, were classified correctly by this method.Gram’s staining method is considered fundamental in bacterial taxonomy. The outcome of the Gram reaction reflects major differences in the chemical composition and ultrastructure of bacterial cell walls. The Gram stain involves staining a heat-fixed smear of cells with a rosaniline dye such as crystal or methyl violet in the presence of iodine, with subsequent exposure to alcohol or acetone. Organisms that are decolorized by the alcohol or acetone are designated gram negative.Alternative Gram staining techniques have recently been proposed. Sizemore et al. (19) reported on the use of fluorescently labeled wheat germ agglutinin. This lectin binds specifically to N-acetylglucosamine in the peptidoglycan layer of gram-positive bacteria, whereas gram-negative organisms contain an outer membrane that prevents lectin binding. Although simpler and faster than the traditional Gram stain, this method requires heat fixation of organisms.Other Gram stain techniques suitable for live bacteria in suspension have been described. Allman et al. (1) demonstrated that rhodamine 123 (a lipophilic cationic dye) rendered gram-positive bacteria fluorescent, but its uptake by gram-negative organisms was poor. This reduced uptake by gram-negative bacteria was attributed to their outer membranes. The outer membrane can be made more permeable to lipophilic cations by exposure to the chelator EDTA (4). Shapiro (18) took advantage of this fact to form the basis of another Gram stain, one which involved comparing the uptake of a carbocyanine dye before and after permeabilizing organisms with EDTA. All of these methods, however, rely on one-color fluorescence, making analysis of mixed bacterial populations difficult.An alternative to the use of stains is the potassium hydroxide (KOH) test. The method categorizes organisms on the basis of differences in KOH solubility. After exposure to KOH, gram-negative bacteria are more easily disrupted than gram-positive organisms. This technique has been used to classify both aerobic and facultatively anaerobic bacteria, including gram-variable organisms (8). In a study by Halebian et al. (9), however, this technique incorrectly classified several anaerobic strains, giving rise to the recommendation that the method should only be used in conjunction with the traditional Gram stain.In this study we demonstrate a Gram staining technique for unfixed organisms in suspension, by using clinically relevant bacterial strains and organisms notorious for their gram variability. The method uses two fluorescent nucleic acid binding dyes, hexidium iodide (HI) and SYTO 13. Sales literature (11) published by the manufacturers of HI (Molecular Probes, Inc., Eugene, Oreg.), which displays a red fluorescence, suggests that the dye selectively stains gram-positive bacteria. SYTO 13 is one of a group of cell-permeating nucleic acid stains and fluoresces green (11). These dyes have been found to stain DNA and RNA in live or dead eukaryotic cells (16). Both dyes are excited at 490 nm, permitting their use in fluorescence instruments equipped with the most commonly available light sources. We reasoned that a combination of these two dyes applied to mixed bacterial populations would result in all bacteria being labeled, with differential labeling of gram-positive bacteria (HI and SYTO 13) and gram-negative bacteria (SYTO 13 only). The different fluorescence emission wavelengths of the two dyes would ensure differentiation of gram-positive from gram-negative bacteria by either epifluorescence microscopy or flow cytometry when equipped with the appropriate excitation and emission filters. While a commercial Gram stain kit produced by Molecular Probes includes HI and an alternative SYTO dye, SYTO 9, we are unaware of any peer-reviewed publications regarding either its use or its effectiveness with traditionally gram-variable organisms.     

The characterization and ultrastructure of two new strains of Butyrivibrio

Strains B-385-1 and 2-33 are numerically important components rumen bacterial populations , but they have remained (taxonomically) undefined. In spite of some resemblance to Selenomonas ruminantium in their cell size and in their formation of tufts of flagella, they more closely resemble Butyrivibrio fibrisolvens in the subpolar location of their flagella, in their guanine + cytosine content, and in most biochemical characteristics, including butyrate formation. Cells of these strains stain Gram negative, as do both Selenomonas and Butyrivibrio, but their cell walls closely resemble those of Butyrivibrio in their Gram-positive type of molecular architecture and in their cleavage pattern in freeze-etching. Cells of these strains and of B. fibrisolvens have a very thin (ca. 12 nm) peptidoglycan cell wall; thus, they fail to retain the crystal violet complex of the Gram stain and stain Gram negative. This important structural characteristic of their cell walls places strains B-385-1 and 2-33 within the genus Butyrivibrio and certain morphological and biochemical characteristics distinguish them from B. fibrisolvens.     

Photometric Application of the Gram Stain Method To Characterize Natural Bacterial Populations in Aquatic Environments

The Gram stain method was applied to the photometric characterization of aquatic bacterial populations with a charge-coupled device camera and an image analyzer. Escherichia coli and Bacillus subtilis were used as standards of typical gram-negative and gram-positive bacteria, respectively. A mounting agent to obtain clear images of Gram-stained bacteria on Nuclepore membrane filters was developed. The bacterial stainability by the Gram stain was indicated by the Gram stain index (GSI), which was applicable not only to the dichotomous classification of bacteria but also to the characterization of cell wall structure. The GSI spectra of natural bacterial populations in water with various levels of eutrophication showed a distinct profile, suggesting possible staining specificity that indicates the presence of a particular bacterial population in the aquatic environment.Gram’s method is the most important and fundamental orthodox method for bacterial identification. It classifies bacteria into two groups, gram-negative and gram-positive. The mechanism of Gram staining is based on the fundamental structural and chemical attributes of bacterial cell walls. The cell walls of gram-positive bacteria have a high percentage of peptidoglycan, while those of gram-negative bacteria have only a thin peptidoglycan layer (1–3, 6). In Gram’s method, an insoluble dye-iodine complex is formed inside bacterial cells and is extracted by alcohol from gram-negative but not gram-positive bacteria (6, 12, 16). There are taxonomically gram-variable species, but some cells of gram-negative or gram-positive species may show gram-variable characteristics due to environmental stress, such as unsuitable nutrients, temperature, pH, or electrolytes (3).Functional differences between gram-positive and gram-negative cell walls have been studied with special emphasis on nutrient uptake from the ambient environment. Gram-negative bacteria have a periplasmic space between the lipopolysaccharide layer and the plasma membrane. In this space, binding proteins initially attach to nutrients and take them to a membrane carrier. Gram-positive bacteria lack the periplasmic space and are believed to have no binding proteins (9). Therefore, nutrient uptake from the environment is easier for gram-negative bacteria than for gram-positive bacteria. Because of this difference, the population density of gram-negative bacteria in more oligotrophic environments could be higher than that of gram-positive bacteria (20).Gram staining is commonly used only to reflect cell wall structure. If Gram staining characterizes not only simple taxonomical dichotomy but also multiple biological functions, it may also be used to correlate bacterial cell wall structure with related physiological responses to the environment. In particular, Gram staining could supply ecological information on natural bacterial populations that are difficult to culture by the present technology.Membrane filter methods are widely used for microscopy in aquatic microbiology because of the low population densities of bacteria in many aquatic environments (4, 11, 16). However, these methods sometimes have problems associated with microscopic observations, causing unclear images of bacterial cells on Nuclepore filters when used with the conventional mounting medium (immersion oil; refractive index [nd] = 1.514). Hence, a suitable mounting agent must be applied to obtain precise image analyses of Gram-stained bacteria on Nuclepore filters.In this study, we have established a distinct method to characterize photometric Gram stain images; it involves the Gram stain index (GSI) for specifying natural bacterial populations in various aquatic environments. For this purpose, we have standardized the GSI of typical gram-negative and gram-positive bacteria by using Escherichia coli and Bacillus subtilis, respectively, and compared these GSI values to those of natural bacterial populations of several freshwater environments. The natural waters we investigated were Hyoutaro-ike pond, Matsumi-ike bog, and Lake Kasumigaura, which are oligotrophic, mesotrophic, and eutrophic water bodies, respectively, as previously determined (8, 10, 13, 18, 22, 23).     

Simultaneous fluorescent gram staining and activity assessment of activated sludge bacteria

Wastewater treatment is one of the most important commercial biotechnological processes, and yet the component bacterial populations and their associated metabolic activities are poorly understood. The novel fluorescent dye hexidium iodide allows assessment of Gram status by differential absorption through bacterial cell walls. Differentiation between gram-positive and gram-negative wastewater bacteria was achieved after flow cytometric analysis. This study shows that the relative proportions of gram-positive and gram-negative bacterial cells identified by traditional microscopy and hexidium iodide staining were not significantly different. Dual staining of cells for Gram status and activity proved effective in analyzing mixtures of cultured bacteria and wastewater populations. Levels of highly active organisms at two wastewater treatment plants, both gram positive and gram negative, ranged from 1.5% in activated sludge flocs to 16% in the activated sludge fluid. Gram-positive organisms comprised <5% of the total bacterial numbers but accounted for 19 and 55% of the highly active organisms within flocs at the two plants. Assessment of Gram status and activity within activated sludge samples over a 4-day period showed significant differences over time. This method provides a rapid, quantitative measure of Gram status linked with in situ activity within wastewater systems.     

Simultaneous Fluorescent Gram Staining and Activity Assessment of Activated Sludge Bacteria

Wastewater treatment is one of the most important commercial biotechnological processes, and yet the component bacterial populations and their associated metabolic activities are poorly understood. The novel fluorescent dye hexidium iodide allows assessment of Gram status by differential absorption through bacterial cell walls. Differentiation between gram-positive and gram-negative wastewater bacteria was achieved after flow cytometric analysis. This study shows that the relative proportions of gram-positive and gram-negative bacterial cells identified by traditional microscopy and hexidium iodide staining were not significantly different. Dual staining of cells for Gram status and activity proved effective in analyzing mixtures of cultured bacteria and wastewater populations. Levels of highly active organisms at two wastewater treatment plants, both gram positive and gram negative, ranged from 1.5% in activated sludge flocs to 16% in the activated sludge fluid. Gram-positive organisms comprised <5% of the total bacterial numbers but accounted for 19 and 55% of the highly active organisms within flocs at the two plants. Assessment of Gram status and activity within activated sludge samples over a 4-day period showed significant differences over time. This method provides a rapid, quantitative measure of Gram status linked with in situ activity within wastewater systems.     

An improved method for clearing and staining free-hand sections and whole-mount samples

BACKGROUND AND AIMS: Free-hand sectioning of living plant tissues allows fast microscopic observation of internal structures. The aim of this study was to improve the quality of preparations from roots with suberized cell walls. A whole-mount procedure that enables visualization of exo- and endodermal cells along the root axis was also established. METHODS: Free-hand sections were cleared with lactic acid saturated with chloral hydrate, and observed with or without post-staining in toluidine blue O or aniline blue. Both white light and UV light were used for observation. Lactic acid was also used as a solvent for berberine, and fluorol yellow for clearing and staining the samples used for suberin observation. This procedure was also applied to whole-mount roots with suberized celllayers. KEY RESULTS: Clearing of sections results in good image quality to observe the tissue structure and cell walls compared with non-cleared sections. The use of lactic acid as a solvent for fluorol yellow proved superior to previously used solvents such as polyethylene glycol-glycerol. Clearing and fluorescence staining of thin roots such as those of Arabidopsis thaliana were successful for suberin visualization in endodermal cells within whole-mount roots. For thicker roots, such as those of maize, sorghum or tea, this procedure could be used for visualizing the exodermis in a longitudinal view. Clearing and staining of peeled maize root segments enabled observation of endodermal cell walls. CONCLUSIONS: The clearing procedure using lactic acid improves the quality of images from free-hand sections and clearings. This method enhances the study of plant root anatomy, in particular the histological development and changes of cell walls, when used in combination with fluorescence microscopy.     

On the stainability of plant cell walls with alcian blue

This work is a continuation of a communication on the stainability of broad bean (Vicia faba L.) root tip cells with alcian blue, published some time ago. Following the standard method of staining with alcian blue, the cell walls are very strongly stained, the nuclei (except nucleolus) lightly, the nucleolus and cytoplasm are practically colourless. The weak dyeing of the nucleus is not equal throughout the whole section so that the comparison of stainability of cell walls and nuclei by itself cannot explain the staining with alcian blue. The results of this work on the staining of cell walls (if not including model experiments and experiments in vitro, which are not considered as decisive here) can be summarized as follows: the pH dependence of staining, the loss of stainability as a result of pectinase digestion, blocking of staining by methylation and regeneration of stainability by demethylation and, finally, the impossibility of staining in the presence of NaCl lead to the conclusion that the staining of the material studied in this work is primarily caused by the salt linkage of alcian blue with the free carboxyls of pectic substances. From the comparison of staining with alcian blue and with other basic dyes it follows that in the case of alcian blue some other factors may also take part and are the reason for the selectivity and firmness (fastness) of the staining of cell walls with this dye. Otherwise, the staining of plant cell walls with alcian blue corresponds quite well to the staining of carboxyls containing polysaccharides of animal tissues with this dye. By staining with alcian blue it was found impossible to distinguish between younger and older cell walls within the meristem. However, this staining is suitable for routine use when studying the meristematic tissue. It is often possible to use solutions of a higher pH than generally used.     

Obtaining and characterization of DNA-containing micromummies of yeasts and gram-positive bacteria with enhanced cell wall permeability: application in PCR

The procedure of obtaining DNA-containing cell envelopes ("micromummies") of bacteria, yeasts, and fungi using chaotropic salts has been developed previously and the possibility of their direct application in PCR has been demonstrated. The fine structure of micromummies has been studied by electron microscopic methods. This work has demonstrated that additional treatment of micromummies of yeasts and gram-positive bacteria with proteinase K results in hydrolytic degradation of cell proteins and drastic enhancement of cell wall permeability for macromolecules (DNA). Thus, the efficiency of PCR ex situ using resultant micromummies after washing off the products of protein hydrolysis and proteinase K can be increased. The results of electron microscopic study of ultrathin sections of yeasts (Pichia pastoris, Saccharomyces cerevisiae) and gram-positive bacteria (Micrococcus luteus, Arthrobacter globiformis, Bacillus subtilis) support the biochemical data that treatment with chaotropic salts and proteinase K results in the loosening of microbial cell walls and in a decrease in the intracellular protein content. At the same time, cell walls generally maintain their integrity (continuity) and initial spherical or rodlike shape. The optimal modes of treatment of the cells of different microbial species with chaotropic salts and proteinase K have been selected to obtain permeabilized cell envelopes containing denatured or native DNA.     

Evaluation of techniques for immunofluorescent staining of microtubules in cultured plant cells

Various modifications to the immunofluorescent labeling procedures for microtubules in plant cells have been compared using cell cultures of Vicia hajastana Grossh. Using serial section electron microscopic reconstructions as a reference, we have chosen as our standard procedure a method that maximizes both the preservation of the cytoskeleton and the proportion of cells staining, while minimizing the degree of nonspecific staining. The critical steps of the procedure include stabilization of the cytoskeleton, cell wall permeabilization, and cell extraction. To maintain structural integrity during the procedure, it is necessary to stabilize the cytoskeleton with paraformaldehyde. To facilitate antibody penetration into the cell, it was necessary that the walls be made permeable via partial enzymatic digestion. Detergent extraction of cells increased the proportion of cells staining and decreased the level of nonspecific binding of the antibodies. The procedures detailed in this article provide a good starting point for the application of immunofluorescent labeling techniques to other plant systems.     

Fluorescein-labeled β-Glucosidase as a Bacterial Stain

Fluorescein isothiocyanate-labeled β-glucosidase was used as a simple staining reagent with selected gram-positive and gram-negative organisms. Staining in situ appeared to be dependent on the presence of accessible glycosidic-type linkages in the bacterial cell wall. Extensive wall damage or lysis did not occur when stained cells were suspended in washing and mounting solutions. The apparent specificity of labeled enzyme for wall substance was tested by blocking reactions, staining of isolated cell walls, and failure to stain substances lacking appropriate glycosidic linkages. Severe cell wall lesions were produced after prolonged contact with labeled enzyme, and this phenomenon may also be related to staining specificity. Gram-negative organisms and spores were poorly stained unless protected glycopeptide substrate was previously exposed by treatment of cells with thioglycolic acid or dilute alkaline sodium hypochlorite solution. A potential for staining tissues and cell lines may also exist. Some possible applications of labeled enzymes are briefly discussed.     

Structural cell-wall proteins in protoxylem development: evidence for a repair process mediated by a glycine-rich protein

Polyclonal antibodies were used to localize structural cell-wall proteins in differentiating protoxylem elements in etiolated bean and soybean hypocotyls at the light- and electron-microscopic level. A proline-rich protein was localized in the lignified secondary walls, but not in the primary walls of protoxylem elements, which remain unlignified, as shown with lignin-specific antibodies. Secretion of the proline-rich protein was observed during lignification in different cell types. A glycine-rich protein (GRP1.8) was specifically localized in the modified primary walls of mature protoxylem elements and in cell corners between xylem elements and xylem parenchyma cells. The protein was secreted by Golgi bodies both in protoxylem cells after the lignification of their secondary walls and in the surrounding xylem parenchyma cells. The modified primary walls of protoxylem elements were visualized under the light microscope as filaments or sheets staining distinctly with the protein stain Coomassie blue. Electron micrographs of these walls show that they are composed of an amorphous material of moderate electron-density and of polysaccharide microfibrils. These materials form a three-dimensional network, interconnecting the ring- or spiral-shaped secondary wall thickenings of protoxylem elements and xylem parenchyma cells. The results demonstrate that the modified primary walls of protoxylem cells are not simply breakdown products due to partial hydrolysis and passive elongation, as believed until now. Extensive repair processes produce cell walls with unique staining properties. It is concluded that these walls are unusually rich in protein and therefore have special chemical and physical properties.     

Evaluation of a fluorescent lectin-based staining technique for some acidophilic mining bacteria

A fluorescence-labeled wheat germ agglutinin staining technique (R. K. Sizemore et al., Appl. Environ. Microbiol. 56:2245-2247, 1990) was modified and found to be effective for staining gram-positive, acidophilic mining bacteria. Bacteria identified by others as being gram positive through 16S rRNA sequence analyses, yet clustering near the divergence of that group, stained weakly. Gram-negative bacteria did not stain. Background staining of environmental samples was negligible, and pyrite and soil particles in the samples did not interfere with the staining procedure.     

Obtaining and characterization of DNA-containing micromummies of yeasts and gram-positive bacteria with enhanced cell wall permeability: Application in PCR

The procedure of obtaining DNA-containing cell envelopes (“micromummies”) of bacteria, yeasts, and fungi using chaotropic salts has been developed previously and the possibility of their direct application in PCR has been demonstrated. The fine structure of micromummies has been studied by electron microscopic methods. This work has demonstrated that additional treatment of micromummies of yeasts and gram-positive bacteria with proteinase K results in hydrolytic degradation of cell proteins and drastic enhancement of cell wall permeability for macromolecules (DNA). Thus, the efficiency of PCR ex situ using resultant micromummies after washing off the products of protein hydrolysis and proteinase K can be increased. The results of electron microscopic study of ultrathin sections of yeasts (Pichia pastoris, Saccharomyces cerevisiae) and gram-positive bacteria (Micrococcus luteus, Arthrobacter globiformis, Bacillus subtilis) support the biochemical data that treatment with chaotropic salts and proteinase K results in the loosening of microbial cell walls and in a decrease in the intracellular protein content. At the same time, cell walls generally maintain their integrity (continuity) and initial spherical or rodlike shape. The optimal modes of treatment of the cells of different microbial species with chaotropic salts and proteinase K have been selected to obtain permeabilized cell envelopes containing denatured or native DNA.     

The application of flow cytophotometry in measurements of cell adhesion

A common approach to the study of cell substrate interactions is the measurement of the attachment of cells to different substrates or to cultured cell layers. The evaluation of attachment is made either by scintillation counting of previously labelled adhering cells, or by light microscopy using the criterion of cell shape, sometimes refined by automatic image analysis. These methods have many drawbacks. This paper suggests the use of fluorescence-activated flow cytophotometry, (FC) which yields direct counts of the non-adhering cells. These "free" cells are removed after completion of the adhesion experiment from the microtitre plate wells. An internal standard, in the form of fluorescent polystyrene beads is added, allowing evaluation of the percentage of cells adhering to the well walls. Flow cytophotometry then produces data based on the analysis of large populations of cells. Unequivocal discrimination is obtained between the counted cells and counted fluorescent beads eliminating counting errors. The results can be processed on line by computer. A suspension of mouse splenocytes was used for the evaluation of the overall error of the method arising from inaccuracies in pipetting, interference of glutaraldehyde with ethidium bromide (EB) staining and instrumental error. Each adhesion experiment was terminated by staining and post-fixation and it was established that this introduces no change in cell counting, in comparison with the original unfixed cells. Prefixation, however, quenches the EB staining and would interfere with the counting procedure. The overall standard error of the technique was found to be 5%-10%.(ABSTRACT TRUNCATED AT 250 WORDS)     

Morphological changes associated with novobiocin resistance in Bacillus licheniformis.

Spontaneously occurring novobiocin-resistant (Nov) mutants of Bacillus licheniformis ATCC 9945, resistant to low levels of novobiocin (15 mug/ml), were isolated with a frequency of 3 in 106 organisms. Such isolates grew well, but nearly all exhibited consistent plleiotropic alterations in colonial and cell morphologies. One mutant, nov-12, grew as chains of unseparated but clearly distinct daughter cells in the absence of novobiocin in liquid culture. When novobiocin was present, nov-12 grew as very long "filaments" which were, however, septate. Septa formed in the presence of the antibiotic were normal, except that no annular clevage of the septal wall was observed. Septa were also irregularly positioned along the filament. These observations were compared with previous findings on the effects of novobiocin and novobiocin resistance described for other organisms. It was concluded that the primary action of novobiocin might differ in gram-positive and gram-negative organisms. However, when the low-level novobiocin sensitivity, normally associated with gram-positive organisms, was genetically abolished in Nov strains of B. licheniformis they became susceptible to an action of novobiocin more analogous to that found for gram-negative organisms. The morphological alterations associated with the Nov phenotype in this organism, together with observations in other organisms, indicate that novobiocin resistance might be generally useful in the search for mutants of gram-positive organisms with altered cell walls.     

Evaluation of a Fluorescent Lectin-Based Staining Technique for Some Acidophilic Mining Bacteria

A fluorescence-labeled wheat germ agglutinin staining technique (R. K. Sizemore et al., Appl. Environ. Microbiol. 56:2245–2247, 1990) was modified and found to be effective for staining gram-positive, acidophilic mining bacteria. Bacteria identified by others as being gram positive through 16S rRNA sequence analyses, yet clustering near the divergence of that group, stained weakly. Gram-negative bacteria did not stain. Background staining of environmental samples was negligible, and pyrite and soil particles in the samples did not interfere with the staining procedure.     

Cytochemical localization of calcium in cap cells of primary roots of Zea mays L

The distribution of calcium (Ca) in caps of vertically- and horizontally-oriented roots of Zea mays was monitored to determine its possible role in root graviresponsiveness. A modification of the antimonate precipitation procedure was used to localize Ca in situ. In vertically-oriented roots, the presumed graviperceptive (i.e., columella) cells were characterized by minimal and symmetric staining of the plasmalemma and mitochondria. No precipitate was present in plasmodesmata or cell walls. Within 5 min after horizontal reorientation, staining was associated with the portion of the cell wall adjacent to the distal end of the cell. This asymmetric staining persisted throughout the onset of gravicurvature. No staining of lateral cell walls of columella cells was observed at any stage of gravicurvature, suggesting that a lateral flow of Ca through the columella tissue of horizontally-oriented roots does not occur. The outermost peripheral cells of roots oriented horizontally and vertically secrete Ca through plasmodesmata-like structures in their cell walls. These results are discussed relative to proposed roles of root-cap Ca in root gravicurvature.     

Isolation of Outer Membranes with an Ordered Array of Surface Subunits from Acinetobacter

A method has been developed for the isolation of outer membranes from Acinetobacter sp. strain MJT/F5/199A. Washed cells were broken in a French press and, after deoxyribonuclease and ribonuclease treatment, removal of intact cells, and four washes in 20 mosmol phosphate buffer, pH 7.4, with centrifugation at 25,000 x g for 10 min, preparations of cell wall fragments from which almost all pieces of plasma membrane had been removed resulted. Treatment of the cell walls with lysozyme and further washing, in the presence of 20 mM MgCl(2), yielded preparations of outer membranes. Electron microscopy of freeze-etched preparations shows that a regular pattern of subunits is present on the outer surfaces of intact cells. After negative staining, these subunits are visible on isolated walls and outer membranes; they can be removed by brief treatment with papain. In section, the cell wall structure is that typical of gram-negative bacteria, but the subunits are not detectable on the surface of the outer membrane. The outer membrane retains the appearance of a "unit membrane" in the cell wall, isolated outer membrane, and papain-treated outer membrane fractions. Both cell walls and outer membranes contain a high percentage of protein (76 and 84%, respectively) and not more than 5% carbohydrate, of which glucose and galactose are constitutents. The outer membranes of this Acinetobacter thus differ in structure and composition from those of bacteria in the Enterobacteriaceae.