Morphological variety of intracellular microcolonies of Legionella species in Vero cells.

Intracellular microcolonies of six Legionella species growing in Vero cells showed distinctly varied morphologies. The varieties were observed by light microscopy of Gimenez-stained, Legionella-infected Vero cells and by electron microscopy (EM). Legionella pneumophila Philadelphia-1 formed needle-shaped crystal-like microcolonies. Legionella bozemanii WIGA formed microcolonies like wool balls containing filamentous cells. In EM, these organisms proliferated in endosomes, which were adjacent to swollen rough endoplasmic reticula. Legionella oakridgensis OR-10 showed serpentine chains. Many mitochondria were observed around the microcolonies. Legionella jordanis BL-540 formed spherical moss-like microcolonies which were or were not surrounded by endoplasmic membranes. Legionella feeleii WO-44C spread throughout the cytoplasm without making clusters. Legionella dumoffii Tex-KL made big clusters that spread in the cytoplasm, a portion of which was outside the endosome membranes. These different morphologies imply diversity in modes of intracellular multiplication of Legionella spp.

A comparison of solid and liquid media for resuscitation of starvation- and low-temperature-induced nonculturable cells of Aeromonas hydrophila.

Like many other gram-negative bacteria, starved cells of Aeromonas hydrophila can be induced into a viable but nonculturable (VBNC) state by incubation at low temperature, as shown here by using various bacterial enumeration methods. Starved A. hydrophila strain HR7 cells at 4 degrees C reached the nonculturable stage in about 45 days. The cells were resuscitated by either a solid medium resuscitation method, using solid agar amended with H2O2-degrading agents, catalase or sodium pyruvate, or a liquid medium resuscitation method, by incubating nonculturable cells in liquid media containing these compounds before spreading onto plates. The liquid medium resuscitation method using catalase resulted in nearly complete recovery of nonculturable cells.

Resuscitation of viable but nonculturable cells of Vibrio parahaemolyticus induced at low temperature under starvation.

Vibrio parahaemolyticus is known to exist in a viable but nonculturable state when incubated at low temperature under starvation. It has long been debated whether the culturable cells which appear after temperature upshift are the result of true resuscitation or regrowth of a few residual culturable cells. Starved V. parahaemolyticus cells at 4 degrees C reached the nonculturable stage in about 12 days. The true resuscitation of nonculturable cells of V. parahaemolyticus occurred after spreading them onto an agar medium supplemented with H(2)O(2)-degrading compounds such as catalase or sodium pyruvate. The proposed method may be applicable to detecting the enteropathogen from environmental samples.

Virus entry is a major determinant of cell tropism of Edmonston and wild-type strains of measles virus as revealed by vesicular stomatitis virus pseudotypes bearing their envelope proteins.

The Edmonston strain of measles virus (MV) that utilizes the human CD46 as the cellular receptor produced cytopathic effects (CPE) in all of the primate cell lines examined. In contrast, the wild-type MV strains isolated in a marmoset B-cell line B95a (the KA and Ichinose strains) replicated and produced CPE in some but not all of the primate lymphoid cell lines. To determine the mechanism underlying this difference in cell tropism, we used a recently developed recombinant vesicular stomatitis virus (VSV) containing as a reporter the green fluorescent protein gene in lieu of the VSV G protein gene (VSVDeltaG*). MV glycoproteins were efficiently incorporated into VSVDeltaG*, producing the VSV pseudotypes. VSVDeltaG* complemented with VSV G protein efficiently infected all of the cell lines tested. The VSV pseudotype bearing the Edmonston hemagglutinin (H) and fusion (F) protein (VSVDeltaG*-EdHF) infected all cell lines in which the Edmonston strain caused CPE, including the rodent cell lines to which the human CD46 gene was stably transfected. The pseudotype bearing the wild-type KA H protein and Edmonston F protein (VSVDeltaG*-KAHF) infected all lymphoid cell lines in which the wild-type MV strains caused CPE as efficiently as VSVDeltaG*-EdHF, but it did not infect any of the cell lines resistant to infection with the KA strain. The results indicate that the difference in cell tropism between these MV strains was largely determined by virus entry, in which the H proteins of respective MV strains play a decisive role.

Restoration of culturability of starvation-stressed and low-temperature-stressed Escherichia coli O157 cells by using H2O2-degrading compounds.

Late-exponential-phase cells of Escherichia coli O157:H- strain E32511/HSC became nonculturable in sterilized distilled water microcosms at 4 degrees C. Plate counts declined from 3 x 10(6) to less than 0.1 CFU/ml in about 21 days. However, when samples of microcosms at 21 days were inoculated onto an agar medium amended with catalase or nonenzyme peroxide-degrading compounds such as sodium pyruvate or alpha-ketoglutaric acid, plate counts increased to 10(4)-10(5) CFU/ml within 48 h. The proposed mode of action of the catalase or pyruvate is via the degradation of the metabolic by-product H2O2, rather than through supplementation of a required nutrient in the recovery of nonculturable cells. Our studies were based on the assumption that E32511/HSC strain responds to starvation and a low temperature by entering a nonculturable state and that the correction of oxidative stress upon the inoculation of bacteria on agar plates promotes recovery of nonculturable cells.

Isolation and characterization of rugose form of Vibrio cholerae O139 strain MO10.

An extracellular exopolysaccharide (slime) is produced by Vibrio cholerae O139 MO10 in response to nutrient starvation. The presence of this slime layer on the cell surface and its subsequent release have been shown to be associated with biofilm formation and the change from a normal smooth colony morphology to a rugose one. An immunoelectron microscopic examination demonstrated that there is an epitope common to the exopolysaccharide antigen of V. cholerae O1 and that of O139 MO10.

Vibrio cholerae O1 strain TSI-4 produces the exopolysaccharide materials that determine colony morphology, stress resistance, and biofilm formation.

Vibrio cholerae O1 strain TSI-4 (El Tor, Ogawa) can shift to a rugose colony morphology from its normal translucent colony morphology in response to nutrient starvation. We have investigated differences between the rugose and translucent forms of V. cholerae O1 strain TSI-4. Electron microscopic examination of the rugose form of TSI-4 (TSI-4/R) revealed thick, electron-dense exopolysaccharide materials surrounding polycationic ferritin-stained cells, while the ferritin-stained material was absent around the translucent form of TSI-4 (TSI-4/T). The exopolysaccharide produced by V. cholerae TSI-4/R was found to have a composition of N-acetyl-D-glucosamine, D-mannose, 6-deoxy-D-galactose, and D-galactose (7.4:10.2:2.4:3.0). The expression of an amorphous exopolysaccharide promotes biofilm development under static culture conditions. Biofilm formation by the rugose strain was determined by scanning electron microscopy, and most of the surface of the film was colonized by actively dividing rod cells. The corresponding rugose and translucent strains were compared for stress resistance. By having exopolysaccharide materials, the rugose strains acquired resistance to osmotic and oxidative stress. Our data indicated that an exopolysaccharide material on the surface of the rugose strain promoted biofilm formation and resistance to the effects of two stressing agents.

Overproduction of Campylobacter ferritin in Escherichia coli and induction of paracrystalline inclusion by ferrous compound.

The ferritin gene (cft) of Campylobacter jejuni was overexpressed in cells of Escherichia coli using a T7 RNA polymerase expression system. Many round particles which were the same size as the ferritin particles purified from C. jejuni were observed in the lysate of the cft-overexpressed E. coli cells. Since most of them were devoid of a central electron dense core consisting of ferric irons, the Campylobacter ferritins over-produced in E. coli seemed to be apoferritin. When large amounts of ferrous iron (supplied as FeSO4) were added to culture medium, the cft-overexpressed cells formed large inclusion bodies of paracrystalline arrays comprised of ferritin particles with central electron dense cores. The addition of ferric irons did not produce paracrystalline inclusion.

Morphological features of a filamentous phage of Vibrio cholerae O139 Bengal.

A filamentous phage was isolated from carrier strain AI-1841 of Vibrio cholerae 0139 Bengal and thus was termed fs phage. The phage was measured to be approximately 1 microm in length and 6 nm in width. One end of the phage was slightly tapered and had a fibrous appendage. The plaques developed on strain AI-4450 of V. cholerae 0139 were small and turbid. The phage grew in strain AI-4450 and reached a size of 10(8) to 10(9) pfu/ml at 5 hr after infection without inducing any lysis of the host bacteria. The group of phages attached on rod-shaped materials like fimbriae of this bacteria, with their fibrous appendages at the pointed end, were often found in the phage-infected culture. The anti-fimbrial serum effectively inhibited the infection of fs phage to the host strain AI-4450. We thus concluded that the phage can be adsorbed on fimbriae with a fibrous appendage on the pointed end of the phage filament.

Electron microscopy of the major outer membrane protein of Campylobacter jejuni.

The surfaces of the disrupted-cell surfaces of the Campylobacter jejuni strains FUM158432 and M1 were examined using the negative-staining technique and electron microscopy. The surfaces of the whole cells and the outer membranes were covered with small dark dots which, in some areas, were arranged in hexagonal patterns. The hexagonal arrangement was more clearly seen in extracted outer membrane. The size of each structure was measured based on a center-to-center distance with the adjacent structure, and was determined to be 9.9 +/- 0.9 nm. A profile of the proteins in the outer membrane by SDS-PAGE, performed in 0.1% SDS and at 100 C, showed 42 kDa proteins to comprise the major outer membrane protein of this bacterium. Digestion of the outer membrane materials with proteinase reduced this protein band in the SDS-PAGE, and the amount of dark dots on the electron micrograph indicated the structure to be the major outer membrane protein (porin) of this bacterium. The power spectrogram of a computer-assisted Fourier transformation of the hexagonally arranged porin proteins suggests that the porin has a trimeric structure rather than a monomeric one.

The hydrophobic surface protein layer of enteroaggregative Escherichia coli strains.

The surface of three strains of enteroaggregative Escherichia coli (EAggEC) and three strains of enteropathogenic E. coli (EPEC) were examined using the freeze-substitution technique of electron microscopy and as a result an electron dense surface layer was found only on EAggEC strains but not on EPEC strains. The analysis of the outer membrane proteins by polyacrylamide gel electrophoresis revealed the existence of a unique 38 kDa protein in EAggEC strains. The protein could be easily extracted from the bacterial surface with 5 M LiCl treatment at room temperature. The antiserum raised in mice with 38 kDa protein extracted from the electrophoresed gel was immunoreacted with the surface of the bacteria of EAggEC by immunoelectron microscopy. The hydrophobic surface character of the EAggEC strains was lost after the extraction of the protein layer by LiCl. We thus conclude that the surface protein layer therefore plays an important role in the expression of the aggregative phenotype in EAggEC strains.

Stabilization of biological specimens by the use of plasma polymerized hydrocarbon film for imaging with an atomic force microscope.

An atomic force microscope makes imaging of biological molecules possible at high resolution. To this end all samples have to be fixed securely to a flat solid support so that they cannot be displaced by the scanning tip. We herein describe a new method to fix the biological samples to glass surfaces by depositing a thin layer of plasma polymerized methane gas in a high vacuum chamber. Such samples can thus be imaged repeatedly by an atomic force microscope without any loss of image quality.

Purification and characterization of ferritin from Campylobacter jejuni.

We purified an iron-containing protein from Campylobacter jejuni using ultracentrifugation and ion-exchange chromatography. Electron microscopy of this protein revealed circular particles with a diameter of 11.5 nm and a central core with a diameter of 5.5 nm. The protein was composed of a single peptide of 21 kDa and did not serologically cross-react with horse spleen ferritin. The UV-visible spectrum of the protein showed no absorption peaks in the visible region, indicating that little or no heme is bound. The ratio of Fe:phosphate of C. jejuni ferritin was 1.5:1. From these morphological and chemical examinations, we concluded that the C. jejuni purified protein is a ferritin of the same class as that of Helicobacter pylori and Bacteroides fragilis and differs from the heme-containing bacterioferritin of Escherichia coli. The 30 N-terminal amino acids were sequenced and were found to resemble the sequences of other ferritins strongly (H. pylori ferritin, 73% identity; B. fragilis ferritin, 50% identity; E. coli gene-165 product, 50% identity), and to a lesser degree, bacterioferritins (E. coli bacterioferritin, 26% identity; Azotobacter vinelandii, 26% identity; horse spleen ferritin 30% identity). Proteins that cross-reacted with antiserum against the ferritin of C. jejuni were found in other Campylobacter species and in H. pylori, but not in Vibrio, E. coli, or Pseudomonas aeruginosa.

The purification of a GroEL-like stress protein from aerobically adapted Campylobacter jejuni.

From plate cultures of Campylobacter jejuni grown in room air a particulate protein of 62 kDa was isolated by ion-exchange chromatography. The protein had a square shape from the side view but when viewed from the top it had a star-shaped structure. The molecular size of the whole particle determined by gel filtration was 850 kDa which suggested the presence of 14 subunits of 62 kDa in each particle. The N-terminal 37 amino residues showed more than 80% homology with the sequence of these heat shock protein (HSP) 60 homologs of Chlamydia trachomatis, Helicobacter pylori, and Escherichia coli (GroEL). This protein is immunologically cross-reactive with the antiserum for the 60-kDa HSP of Yersinia enterocolitica. Production of the 62-kDa protein increased under heat stress and growth in an aerobic atmospheric environment. From these observations we concluded that the 62-kDa protein is a Campylobacter stress protein (Cj62) which belongs to the HSP 60 family.

The release of outer membrane vesicles from the strains of enterotoxigenic Escherichia coli.

The clinically isolated heat labile enterotoxin (LT)-producing strains of Escherichia coli can be separated into two groups, namely spontaneous LT-releasing strain and non-spontaneous LT-releasing strain, based on their phenotypes of spontaneous release of LT into the culture medium. The phenotype of spontaneous LT release was observed to correlate closely with the phenotype of the release of numerous small vesicles into the culture medium. Both morphological and biological examinations of the vesicle showed that the vesicle was released from the outer membrane. It can, therefore, be assumed that LT may be released from the cell at the time the vesicles form.

The structure and characterization of the surface protein layer of a Comamonas-like organism.

The regular surface layer of a strain of a Comamonas-like organism was examined by electron microscopy. The surface layer protein was easily extracted from the cell surface by a 2.5 M solution of lithium chloride. The protein subunit has a molecular size of 32,000 daltons, but usually forms a large aggregate of more than 1,200,000 daltons. In the extract it formed a regular array of p4 symmetry and was observed to be intimately associated with fragments of lipopolysaccharide. The size of a subunit determined by the negative staining method and the image processing method measured 5.2 x 6.4 nm (width and length), was arranged in a cobblestone-like pattern, and was located in a lattice space measuring 13.0 nm square.

Morphology of the viable but nonculturable Vibrio cholerae as determined by the freeze fixation technique.

The morphology of the nonculturable Vibrio cholerae strain TSI-4 was examined by the freeze fixation technique of electron microscopy and subsequently four unique structures were found in the fine structure s of this bacterium. The size of the cell was about 2/3 of the growing cell. Although the cell was observed to have an outer membrane as well as the cell membrane and cytoplasm, the outer membrane was undulated and had a surface layer of fine fibers. The peptidoglycan layer was thick and more electron dense than that of normal cells.

Release of the outer membrane vesicles from Vibrio cholerae and Vibrio parahaemolyticus.

We found numerous small vesicles released from the cell by thin sectioning of the plate culture of Vibrio cholerae and V. parahaemolyticus fixed with the freeze-substitution technique. From the broth media of exponentially growing bacteria we could collect the vesicles by the centrifugation but not enough without fixation. The vesicles are encompassed with a membrane structure similar to the outer membrane of these bacteria. The anti-O (Inaba) serum reacted with the surface of the vesicles and the inside of the vesicle are generally filled with an electron-dense mass.

The structure of Mycoplasma pneumoniae as determined by the freeze-substitution technique.

The ultrastructure of Mycoplasma pneumoniae FH was examined by a mild fixation method, the freeze-substitution technique, for thin-section transmission electron microscopy and the following new findings were obtained. In the cytoplasm, no nuclear region could be clearly identified. The cytoplasm was filled with many ribosome-like particles, fine fibers and electron-dense particles. The electron-dense particles appeared to be similar to the particles found in the nucleoid region of Pseudomonas aeruginosa and might therefore possibly be a kind of DNA binding protein. The cell surface was completely enveloped with a thin opaque layer. The presence of this surface layer prevented any direct contact of the cell surface with that of the two M. pneumoniae cells.

Correlation between molecular size of the surface array protein and morphology and antigenicity of the Campylobacter fetus S layer.

The correlation between the molecular size of the surface layer protein (S protein) and both structure and antigenicity of the Campylobacter fetus surface layer (S layer) was investigated in several clinical strains and their spontaneous variants which produce S proteins of molecular weights (MW) different from those of the parents. Only three molecular sizes of the S proteins were observed (98, 127, and 149 kDa) in the parental and variant strains. Immunologically, the 98-kDa protein and the 149-kDa protein but not the 127-kDa protein were cross-reactive. Freeze-etching analysis showed that the 98-kDa S protein formed a hexagonal arrangement with a 24-nm center-to-center space and that the S proteins with larger MW (127 or 149 kDa) formed tetragonal ones with an 8-nm center-to-center space. Thus, the MW changes of the S proteins seen in the variant strains were associated with both morphological and antigenic changes in S layer. These observations support the hypothesis that the pattern and antigenicity of the C. fetus S layer is determined by the particular type of S protein. Furthermore, the presence of the two different S layer patterns on a single bacterial cell indicates that multiple S proteins can be produced and expressed in a single cell.