Expression of the surface properties of the fibrillar Streptococcus salivarius HB and its adhesion deficient mutants grown in continuous culture under glucose limitation

Streptococcus salivarius HB and four adhesion deficient mutants, HB-7, HB-V5, HB-V51 and HB-B, were grown in continuous culture in a defined medium under glucose limitation over a range of growth rates from 0.1 to 1.1 h-1. The ability to coaggregate with Veillonella parvula V1 cells and the ability to adhere to buccal epithelial cells did not alter with increasing growth rate. Cell surface hydrophobicity decreased markedly with increasing growth rate for the non-fibrillar non-adhesive mutant HB-B but not for the other four strains which all carry different combinations of fibril classes. The thickness of the ruthenium red staining layer (RRL) also varied with growth rate for strain HB-B, ranging from 19.5 +/- 3.8 nm at high growth rate to a minimum of 12.3 +/- 4.8 nm at low growth rate. Low cell surface hydrophobicity correlated with a thicker RRL for strain HB-B. Strains HB-V5 and HB-7 also showed a significant increase in RRL thickness at high growth rates although to a lesser degree than HB-B. SDS-PAGE revealed a large number of protein bands common to all strains at all growth rates, with the major common protein occurring at 15.6 kDa. Protein bands at 70, 56, 40.5 and 39 kDa appeared stronger at high growth rates than at low. A protein band at 82 kDa showed strongly only at low growth rates. Therefore, adhesion and coaggregation are not phenotypically variable with increasing growth rate but RRL thickness, hydrophobicity and cell surface proteins may be phenotypically variable depending on the strain.     

Depth profiling of the elemental surface composition of the oral microorganism S. salivarius HB and fibrillar mutants by X-ray photoelectron spectroscopy.

X-ray photoelectron spectroscopy (XPS) on microbial cell surfaces requires freeze-drying of cells, and as a result, the cell surface appendages flatten out on the cell surface and form a collapsed fibrillar mass. At present, it is unclear how the density, length and composition of these fibrils influence the elemental surface composition as probed by XPS. The sampling depth of XPS can be varied by changing the electron take-off angle. In this article, we made a depth profiling of the collapsed fibrillar mass of Streptococcus salivarius HB and fibril-deficient mutants by angle-dependent XPS. Methylamine tungstate negative staining and ruthenium red staining followed by sectioning revealed distinct classes of fibrils with various lengths on each of the strains. Interpretation of the angle dependence of the oxygen/carbon (O/C) and phosphorus/carbon (P/C) surface concentration ratios of these strains was difficult. However, the angle dependence of the nitrogen/carbon (N/C) surface concentration ratio could be fully interpreted: N/C did not vary with sampling depth on a bald strain, S. salivarius HBC12 and on S. salivarius HB7, a strain with a dense array of fibrils of uniform length. N/C decreased with sampling depth in case of a sparsely fibrillated strain, S. salivarius HBV51 and eventually reached the value observed for the bald strain, HBC12. A high N/C at small sampling depth was observed for S. salivarius HB with protruding, protein rich fibrils. We conclude that elemental depth profiling of microbial cell surfaces by XPS can be interpreted to coincide with structural and biochemical information on the cell surface as obtained by electron microscopy and can therefore be considered as a useful technique to study structural features of cell surfaces in combination with electron microscopy.     

The surface ultrastructure and adhesive properties of a fimbriate streptococcus sanguis strain and six non‐fimbriate mutants

Streptococcus sanguis FW213 carries peritrichous fimbriae (216±28 nm long) and 6 mutants derived from it lack fimbriae but carry peritrichous fibrils with a mean length of 77–4 + 3–9 nm. Both wild type strain and mutants have a ruthenium red staining layer (≤ 14.5±2.9 nm thick) external to the cell wall at the base of the fibrils and fimbriae. The thickness of this layer is strain dependent. Ruthenium red also stains extracellular masses of material, probably extracellular polysaccharide, but not the fimbriae. S. sanguis strain FW 213 adheres to saliva‐coated hydroxyapatite and buccal epithelial cells and is not aggregated by saliva. The 6 non‐fimbriate mutants of FW213 adhered poorly to hydroxyapatite coated in heated whole saliva (S‐SHA) but 3/6 mutants adhered to the same extent or higher than the wild type to S‐SHA coated in unheated saliva, indicating that strain FW213 may carry a non‐fimbriate adhesin and that whole saliva contains a heat sensitive adhesin. All the mutants had a significantly thinner ruthenium red staining layer (RRL) external to the cell wall than the wild type strain FW213, while the cell surface hydrophobicity showed that the mutants were all less hydrophobic than the wild type FW213.     

Streptococcus salivarius strains carry either fibrils or fimbriae on the cell surface

Strains of Streptococcus salivarius were screened by negative staining for the presence of surface structures. Two structural subgroups were found, carrying either fibrils or fimbriae, projecting from the cell surface. Eight strains carried a very dense peritrichous array of fibrils of two distinct lengths. Long fibrils had an average length of 175 nm, and short fibrils had an average length of 95 nm. Two strains carried only long fibrils, one strain carried only short fibrils, and another strain carried a lateral tuft of very prominent fibrils of two lengths, with a fibrillar fuzz covering the remainder of the cell surface. In all the strains in which they were present, the long fibrils were unaffected by protease or trypsin treatment. In contrast, the short fibrils were completely digested by protease and partially removed by trypsin. Neither long nor short fibrils were affected structurally by mild pepsin digestion or by lipase. The Lancefield extraction procedure removed both long and short fibrils. These twelve fibrillar strains were therefore divisible into four structural subgroups. Extracts of all the fibrillar strains reacted with group K antiserum. The second main structural subgroup consisted of nine strains of S. salivarius, all of which carried morphologically identical, flexible fimbriae arranged peritrichously over the cell surface. The fimbriae were structurally distinct from fibrils and measured 0.5 to 1.0 micron long and 3 to 4 nm wide, with an irregular outline and no obvious substructure. There was no obvious reduction in the number of fimbriae after protease or trypsin treatment. Extracts of the fimbriated strains did not react with the group K antiserum. The two serological and structural subgroups could also be distinguished by colony morphology.     

Negative staining and immunoelectron microscopy of adhesion-deficient mutants of Streptococcus salivarius reveal that the adhesive protein antigens are separate classes of cell surface fibril

The subcellular distribution of the cell wall-associated protein antigens of Streptococcus salivarius HB, which are involved in specific adhesive properties of the cells, was studied. Mutants which had lost the adhesive properties and lacked the antigens at the cell surface were compared with the parent strain. Immunoelectron microscopy of cryosections of cells labeled with affinity-purified, specific antisera and colloidal gold-protein A complexes was used to locate the antigens. Antigen C (AgC), a glycoprotein involved in attachment to host surfaces, was mainly located in the fibrillar layer outside the cell wall. A smaller amount of label was also found throughout the cytoplasmic area in the form of small clusters of gold particles, which suggests a macromolecular association. Mutant HB-7, which lacks the wall-associated AgC, accumulated AgC reactivity intracellularly. Intracellular AgC was often found associated with isolated areas of increased electron density, but sometimes seemed to fill the entire interior of the cell. Antigen B (AgB), a protein responsible for interbacterial coaggregation, was also located in the fibrillar layer, although its distribution differed from that of the wall-associated AgC since AgB was found predominantly in the peripheral areas. A very small amount of label was also found in the cytoplasmic area as discrete gold particles. Mutant HB-V5, which lacks wall-associated AgB, was not labeled in the fibrillar coat, but showed the same weak intracellular label as the parent strain. Immunolabeling with serum against AgD, another wall-associated protein but of unknown function, demonstrated its presence in the fibrillar layer of strain HB. Negatively stained preparations of whole cells of wild-type S. salivarius and mutants that had lost wall-associated AgB or AgC revealed that two classes of short fibrils are carried on the cell surface at the same time. AgB and AgC are probably located on separate classes of short, protease-sensitive fibrils 91 and 72 nm in length, respectively. A third class of only very sparsely distributed short fibrils (63 nm) was observed on mutant HB-V51, which lacks both wall-associated AgB and AgC antigens. The identity of these fibrils and whether they are present on the wild type are not clear. The function of long, protease-resistant fibrils of 178 nm, which are also present on the wild-type strain, remains unknown.     

Ultrastructure, serogrouping and localization of surface antigens of Bacteroides intermedius

The surface ultrastructure of 21 strains of Bacteroides intermedius was investigated by electron microscopy. Rat monoclonal antibodies (mAbs) were used to define serogroups and to detect the location of surface antigens. All 21 isolates had capsules as demonstrated by the use of wet and dry Indian ink stains. Negative staining of whole cells with 1% (w/v) methylamine tungstate showed that all 21 isolates carried clumped peritrichous fibrils with strain dependent morphology, density and length (less than or equal to 0.75 micron). Fibrils on 11 of 13 fresh clinical isolates were more conspicuously clumped and easily visible, whereas those on 6 of 8 laboratory strains were indistinct and were at the limits of the resolution of the negative staining technique. Staining with ruthenium red (RR), followed by thin sectioning, revealed a dense, amorphous RR staining layer (RRL), up to 24.8 +/- 3.0 nm thick, adjacent to the outer membrane on all of 15 strains examined. All isolates had a less dense RR staining matrix (RRM) extending away from the RRL. The structure of the RRM varied between strains. Four rat mAbs (37BI6.1, 38BI1, 39BI1.1 and 40BI3.2) were used to serogroup the 21 strains of B. intermedius. Immunonegative staining revealed that the mAbs were not directed against fibrilis. Antigens recognized by mAb 37BI6.1 and mAb 39BI1.1 were located on the surfaces of cells, beneath fibrils, and on extracellular vesicles. mAb 38BI1 recognized an antigen which was most accessible on lysed cells, and non-specific binding of mAb 40BI3.2 to grids prevented its localization on the cell surface.     

Depth profiling of the elemental surface composition of the oral microorganismS. salivarius HB and fibrillar mutants by X-ray photoelectron spectroscopy

X-ray photoelectron spectroscopy (XPS) on microbial cell surfaces requires freeze-drying of cells, and as a result, the cell surface appendages flatten out on the cell surface and form a collapsed fibrillar mass. At present, it is unclear how the density, length and composition of these fibrils influence the elemental surface composition as probed by XPS. The sampling depth of XPS can be varied by changing the electron take-off angle. In this article, we made a depth profiling of the collapsed fibrillar mass ofStreptococcus salivarius HB and fibril-deficient mutants by angle-dependent XPS. Methylamine tungstate negative staining and ruthenium red staining followed by sectioning revealed distinct classes of fibrils with various lengths on each of the strains. Interpretation of the angle dependence of the oxygen/carbon (O/C) and phosphorus/carbon (P/C) surface concentration ratios of these strains was difficult. However, the angle dependence of the nitrogen/carbon (N/C) surface concentration ratio could be fully interpreted: N/C did not vary with sampling depth on a bald strain,S. salivarius HBC12 and onS. salivarius HB7, a strain with a dense array of fibrils of uniform length. N/C decreased with sampling depth in case of a sparsely fibrillated strain,S. salivarius HBV51 and eventually reached the value observed for the bald strain, HBC12. A high N/C at small sampling depth was observed forS. salivarius HB with protruding, protein rich fibrils. We conclude that elemental depth profiling of microbial cell surfaces by XPS can be interpreted to coincide with structural and biochemical information on the cell surface as obtained by electron microscopy and can therefore be considered as a useful technique to study structural features of cell surfaces in combination with electron microscopy.     

Transmission-scanning electron microscopic observations of selected Eikenella corrodens strains.

The morphology of Eikenella corrodens 333/54-55 (ATCC 23834) and two human periodontal lesion isolates, strains 470 and 373, was examined by transmission and scanning electron microscopy. All strains exhibited a cell envelope characteristic of gram-negative bacteria. Staining with ruthenium red and alcian blue revealed a loosely organized fibrous slime layer associated with the outer surface of the outer membrane. Slime "stabilization" was achieved by incubation of cells with antisera prepared against whole cells of the Eikenella strains. The stabilized slime appeared as a thick, electron-opaque layer juxtaposed to the outer membrane. Negative staining and heavy metal shadow-casting revealed an interwoven network of fibrils approximately 4 nm in diameter. These fibrils appeared to represent subunits of a larger fibril. Scanning electron microscopy after antibody slime stabilization confirmed the presence and location of the slime layer.     

Use of colloidal gold and ruthenium red in stereo high-voltage electron microscopic study of Con A-binding sites in mouse macrophages

Concanavalin A (Con A)-binding sites were labeled with colloidal gold (CG), stained with ruthenium red, and observed under a high-voltage electron microscope. Mouse peritoneal macrophages were labeled by the indirect Con A/CG labeling method at 0 degree C. After washing, some of the cells were incubated in phosphate-buffered saline (PBS) at 37 degrees C. The specimens were then stained with ruthenium red, to enhance the contrast of the cell surface, and embedded in Epon. Sections (0.3 approximately 3 micron thick) were cut and examined by high-voltage electron microscopy at accelerating voltages of 200 approximately 1,000 kV. Staining with ruthenium red provided a strong contrast of the cell surface and the invaginating tubules beneath it against the cytoplasm; in thick sections, both of them were clearly seen by stereomicroscopy. CG particles which represented Con A-binding sites were also sufficiently electron dense to be recognized by high-voltage electron microscopy of thick sections. The two- and three-dimensional distribution of CG particles on the ruthenium-red-positive cell surface was clearly visualized. At 0 degree C, Con A-binding sites were randomly distributed on the cell surface. The redistribution and endocytosis of Con A-binding sites were seen at 37 degrees C. The three-dimensional organization of membrane invagination, which represented the process of endocytosis, was clearly seen by stereomicroscopy. The combination of CG labeling and ruthenium red staining is a useful method for high-voltage electron microscopic analysis of the two- and three-dimensional distribution of CG-labeled ligands on the cell surface in thick sections.     

Surface structures, haemagglutination and cell surface hydrophobicity of Bacteroides fragilis strains.

Nineteen strains of Bacteroides fragilis were examined by negative staining for surface structures. One strain (ATCC 23745) possessed peritrichous fibrils, 16 strains carried peritrichous fimbriae and two strains carried no surface structures. The fimbriae had a diameter of 2.1 +/- 0.25 nm and appeared to be 'curly'. Only a small proportion (4 to 41%, depending on the strain) of cells in a population carried fimbriae or fibrils. Strain A312 Showed phase variation of fimbriae as expression of fimbriae was repressed at 20 degrees C and in early exponential phase at 37 degrees C. The fibrils on strain ATCC 23745 did not exhibit phase variation in response to changes in incubation temperature, growth phase or growth in two different media. Capsules were demonstrated by the Indian ink method on 18 of the 19 strains, varying in size from strain to strain and within the same population. Cultures often contained both capsulate and noncapsulate cells. All strains possessed an electron dense ruthenium red staining layer between 7.9 and 23.9 nm in width attached to the outer membrane. Cell surface hydrophobicity quantified by the hexadecane partition assay gave low values ranging from 6.6 to 52.1%. Only a few strains were able to haemagglutinate and these were only weakly active. There was no correlation between cell surface hydrophobicity, haemagglutinating activity and surface structures.     

Use of colloidal gold and ruthenium red in stereo high-voltage electron microscopic study of Con A-binding sites in mouse macrophages

Summary Concanavalin A (Con A)-binding sites were labeled with colloidal gold (CG), stained with ruthenium red, and observed under a high-voltage electron microscope. Mouse peritoneal macrophages were labeled by the indirect Con A/CG labeling method at 0° C. After washing, some of the cells were incubated in phosphate-buffered saline (PBS) at 37° C. The specimens were then stained with ruthenium red, to enhance the contrast of the cell surface, and embedded in Epon. Sections (0.33 m thick) were cut and examined by high-voltage electron microscopy at accelerating voltages of 2001,000 kV. Staining with ruthenium red provided a strong contrast of the cell surface and the invaginating tubules beneath it against the cytoplasm; in thick sections, both of them were clearly seen by stereomicroscopy. CG particles which represented Con A-binding sites were also sufficiently electron dense to be recognized by high-voltage electron microscopy of thick sections. The two- and three-dimensional distribution of CG particles on the ruthenium-red-positive cell surface was clearly visualized. At 0° C, Con A-binding sites were randomly distributed on the cell surface. The redistribution and endocytosis of Con A-binding sites were seen at 37° C. The three-dimensional organization of membrane invagination, which represented the process of endocytosis, was clearly seen by stercomicroscopy. The combination of CG labeling and ruthenium red staining is a useful method for high-voltage electron microscopic analysis of the two- and three-dimensional distribution of CG-labeled ligands on the cell surface in thick sections.     

Physico-chemical surface characteristics and adhesive properties of Streptococcus salivarius strains with defined cell surface structures

Physico-chemical surface characteristics and adhesive properties of a series of mutants of Streptococcus salivarius HB with defined cell surface structures were determined. Zeta potentials showed no relation either with the presence or absence of specific antigens on the bacterial cell surface, or with the adhesive properties of the cells. Hydrophobicity was assessed by surface free energy determination from measured contact angles, by adsorption to hexadecane and by hydrophobic interaction chromatography. Generally, the progressive removal of fibril subclasses from the cell surface resulted in a reduced hydrophobicity. However, specific fibrillar subclasses appeared to contribute to surface hydrophobicity to widely different extents. Bacterial adhesion to polymethylmethacrylate increased with increasing hydrophobicity of the mutants. However, adhesion to a more complex biological substratum, such as saliva-coated hydroxyapatite, correlated only partly with hydrophobicity. The organism, deprived of most of its fibrillar surface structures, clearly showed the least adhesion to hydrophobic ligands, to both polymethylmethacrylate and saliva-coated hydroxyapatite, and had a significantly higher surface free energy than the other mutants and the parent strain.     

Ultrastructural characteristics of the external surfaces of Pasteurella pneumotropica from mice and Pasteurella multocida from rabbits

The surface structures of the cells of Pasteurella pneumotropica from mice and Pasteurella multocida from rabbits were examined by transmission electron microscopy after ruthenium red staining and polycationic ferritin labelling. P. pneumotropica strains ATCC 35149 and K 79114 had slight extracellular fibrous materials associated with cell walls with ruthenium red staining. Ferritin labelling method revealed thick strands or sparsely ferritin-labelled materials on the cell surface of the strains. P. multocida strains Pm-78 and P-2440 had ferritin-labelled capsules surrounded with the cell wall. Strain Pm-78, which was serotyped as A:12, had a thick capsule, whereas serotype -:3 strain P-2440 had a thin and irregular capsule.     

Morphology and enzymatic degradation of oriented thin film of ultrahigh molecular weight poly[(R)-3-hydroxybutyrate

Thin films of ultrahigh molecular weight poly[(R)-3-hydroxybutyrate] (P(3HB)) were sheared and isothermally crystallized at 100 degrees C. Transmission electron microscopy and atomic force microscopy (AFM) observations revealed that thick fibrous textures, on which lamellae are overgrown normal to the long axis of the fibril, run parallel to the shearing direction. A selected area electron diffraction pattern taken from the fibrils exhibits a fiber pattern of P(3HB) alpha-modification, and the crystallographic c-axis (chain axis) of P(3HB) is set parallel to the long axis of the fibril. In situ AFM observations of enzymatic degradation for the thin film were performed with an extracellular P(3HB) depolymerase from Ralstonia pickettii T1 in a buffer solution. The film surface and thickness became rougher and thinner, respectively, with time after adding the enzyme. During the degradation, fine shish-kebab structures appeared gradually. This fact supports that the amorphous region in the film is preferentially degraded rather than the crystalline one by the depolymerase. The in situ AFM observations also revealed that one thick fibril in the original film is composed of three different states, namely, finer fibril (shish), stacked lamellae (kebab) in edge-on state, and the surrounding amorphous phase.     

Ultrastructure of irregular collagen fibrils of shark mandible

Sawada T. and Inoue S. 2011. Ultrastructure of irregular collagen fibrils of shark mandible. —Acta Zoologica (Stockholm) 92 : 62–66. Collagen fibrillogenesis was investigated in developing fibrous connective tissue (tooth band) in shark mandible by transmission electron microscopy. Fibrils varied considerably in shape and size. Both thin and thick fibrils 40–200 and 400–500 nm in width, respectively, were observed, with the latter showing irregular contours. Examination of both transverse and longitudinal sections of fibril suggested that the irregular, thick fibrils were formed by fusion of the thin fibrils. This was in agreement with a previously proposed mechanism of collagen fibrillogenesis in a variety of tissues, in which formation of thin fibrils is followed by their coalescence into thicker fibrils. Detailed high resolution ultrastructural examination revealed decorin‐like, 4.5‐ to 5.5‐nm‐wide polygonal frames and 3‐nm‐wide ribbon‐like structures previously identified as chondroitin sulfate proteoglycan ‘double tracks’ localized within the interfibrillar spaces. These structures may be closely involved in collagen fibrillogenesis.     

A comparison of the adhesion, coaggregation and cell-surface hydrophobicity properties of fibrillar and fimbriate strains of Streptococcus salivarius

Fibrillar and fimbriate strains of Streptococcus salivarius were compared for their ability to adhere to buccal epithelial cells and saliva-coated hydroxyapatite beads, and for their ability to coaggregate with Veillonella strains. The fibrillar Lancefield group K strains adhered statistically significantly better to both buccal epithelial cells and saliva-coated hydroxyapatite beads than the fimbriate strains, which lacked the Lancefield group K antigen. After 1 h the fibrillar strains coaggregated statistically significantly better than the fimbriate strains with V. parvula strain V1, but after 24 h, coaggregation both of fibrillar and of fimbriate strains reached approximately 90%. Freshly isolated Veillonella strains all coaggregated with the S. salivarius strains, but the percentage coaggregation varied considerably after 1 h depending on the Veillonella strain. Coaggregation was independent of the presence of Ca2+. S. salivarius strain HB-V5, a mutant of strain HB that had lost the Veillonella-binding protein, coaggregated weakly with V. parvula strain V1, but coaggregated very well with other wild-type veillonellae, suggesting the presence of an alternative mechanism for Veillonella-binding for strain HB. Fibrillar strains were, therefore, more adhesive to oral surfaces and coaggregated with veillonellae after 1 h better than the fimbriate S. salivarius strains. Both fibrillar and fimbriate strains were highly hydrophobic in the hexadecane-buffer partition assay.     

Electron microscopic observations of the surface of L-cells in culture

Summary Techniques are described for the preparation of preshadowed replicas of both the upper and lower surfaces of L-cells in culture, and of cross sections of L-cells growing on a cellophane substrate. These revealed long slender microvilli, 800 to 1,100 A in diameter, projecting from both upper and lower surfaces of the cells. These microvilli were frequently observed to contact other cells and substrate, and to leave material behind on the substrate. The plasma membrane of the lower surface was separated from the substrate by an electron-lucent gap 200 to 300 A wide. The surface coat of the L-cell was visualized by staining with colloidal iron and ruthenium. Staining with colloidal iron was most intense on the surface of the microvilli. The gap between cell and substrate was intensely stained with ruthenium red. Enzymatic digestion of living cells revealed that both trypsin and neuraminidase reduced the staining of the cell coat by colloidal iron, whereas only trypsin altered its staining with ruthenium red. After trypsin treatment, fragments of an amorphous material with the staining characteristics of the cell coat were observed between the denuded cells. Treatment with ribonuclease, chymotrypsin or hyaluronidase did not affect the staining of the cell coat.     

Labeling of binding sites for beta 2-microglobulin (beta 2m) on nonfibrillar surface structures of mutans streptococci by immunogold and beta 2m-gold electron microscopy.

As little detail is known about the surface structure of streptococci in the mutans group and the relationship of surface structure to host ligand-binding functions, the twofold purpose of this investigation was to examine in detail, by a range of electron microscopic techniques, the surface structures of streptococci in the different species of the mutans group and to investigate the distribution of beta 2-microglobulin (beta 2m)-binding sites on such structures. Strains representing Streptococcus mutans, S. cricetus, S. rattus, S. sobrinus, and four fresh isolates were studied by shadowcasting and histochemical staining of whole-mounted cells as well as by ultrathin and thick sectioning of embedded specimens. beta 2m-binding site distribution was visualized by indirect immunogold electron microscopy and by direct bacterial binding of beta 2m-conjugated gold probes. Shadowcast preparations revealed binding of gold probes to the cell surface of known beta 2m-binding strains but not to their polar fibrillar appendages. These long fibrils, common to all strains, were trypsin and sonication sensitive and stained with lead citrate but not with uranyl acetate or ruthenium red. More gold particles were bound by the indirect technique. For grid-mounted bacteria, the gold was mostly bound in clusters at the periphery of the cells. When gold probes were reacted in suspension with bacteria before mounting onto grids, a more even distribution of the gold was seen, but the bacteria were aggregated. Heating the bacteria eliminated beta 2m-gold binding but had no effect on the morphology of the fibrils. Thick sections of embedded bacteria prereacted with beta 2m-conjugated gold probes were analyzed by stereo imaging. A wispy, uranyl acetate-stained fuzzy layer, distinct from the fibrils seen by shadowcasting and extending up to one cell diameter from the cell wall, contained the gold probes. These findings introduce a concept that binding sites for some salivary ligands on mutans streptococci may be clustered on very delicate, nonfibrillar structures extending much further from the cell wall than previously appreciated. As for beta 2m, which composes part of the human histocompatibility antigens, part of the bacterial surface would be coated at a distance from its body with a protein not necessarily recognized as foreign by the host.     

Ruthenium red as a stain for electron microscopy. Some new aspects of its application and mode of action.

Commercial ruthenium red has been tested for its purity by spectrophotometry. Impurities detected by this method could be abolished by nitric acid-precipitation of ruthenium brown. This substance has no effect on cell surface staining and converts almost completely to ruthenium red under the conditions used in electron microscopy. It was found, by photometric analysis, that in the ruthenium red-osmium tetroxide-cacodylate combination, generally used for cell surface staining, chemical reactions between ruthenium red and osmium tetroxide occur. As aerial oxidation of hexammineruthenium2+ leads to a product with some surface staining capability, it is suggested that an oxidized product of ruthenium red is responsible for binding to cellular components, and that a reduced product of osmium tetroxide gives an additional contrast enhancement. In ruthenium red-osmium dioxide combinations ruthenium red seems to bind to cell surfaces without any molecular alteration, and contrast is gained by the model proposed by Blanquet (1976b). The latter method could open a way for investigating the binding of ruthenium red to certain natural compounds involved in calcium transport, as postulated by a number of authors. Both ruthenium-osmium combinations differ in their cell surface staining ability. The ruthenium red-osmium dioxide combination tends to form distinct subunits, whereas the osmium tetroxide variety stains homogeneously. In combination with osmium dioxide, the surface staining is affected by EDTA, and, in contrast to osmium tetroxide, a successive application of ruthenium red and osmium dioxide as possible.     

The Attachment of Bacteria to the Gastric Epithelium of the Pig and its Importance in the Microecology of the Intestine

Some characteristics of the association between lactic acid bacteria and pig squamous epithelial cells were studied. Strains from several sources were tested for adhesion in vitro but only those from pigs and chickens attached. The adhesion rate of pig isolates was very variable and, of the isolates tested, strains of Lactobacillus fermentum and Streptococcus salivarius attached in largest numbers. These strains were selected for further study. They did not attach to columnar epithelial cells from the small and large intestine. Adhesion was reduced by sodium periodate or protease. Both strains had a microcapsule with fibrils which stained with ruthenium red. The adhesive bond between lactobacilli and squamous tissue was strong enough to resist washing 50 times but there was a persistent release of bacteria during the washing process. When the strains of both species or of L. fermentum alone were fed to artificially reared pigs there was a statistically significant reduction in the numbers of Escherichia coli in the stomach.