The putative DNA translocase SpoIIIE is required for sporulation of the symmetrically dividing coccal species Sporosarcina ureae

The spoIIIE gene of Sporosarcina ureae encodes a 780-residue protein, showing 58% identity to the SpoIIIE protein of Bacillus subtilis, which is thought to be a DNA translocase. Expression of the S. ureae spoIIIE gene is able to restore sporulation in a B. subtilis spoIIIE mutant. Inactivation of the S. ureae spoIIIE gene blocks sporulation of S. ureae at stage III. Within the limits of detection, the sporulation division in S. ureae shows the same symmetry, or near symmetry, as the vegetative division (in contrast to the highly asymmetric location of the sporulation division for B. subtilis), and so it is inferred that SpoIIIE facilitates chromosome partitioning during sporulation, even when the division is not grossly asymmetric. It is suggested that chromosome partitioning lags behind division during sporulation but not during vegetative growth.     

Phylogenetic analysis of the genera Planococcus, Marinococcus and Sporosarcina and their relationships to members of the genus Bacillus

A phylogenetic analysis based on 16S rRNA was performed on the genera Planococcus, Marinococcus, Sporosarcina and endospore-forming rods. In agreement with earlier 16S rRNA cataloguing data, Planococcus citreus and Sporosarcina ureae clustered with Bacillus pasteurii and other bacilli containing lysine in their cell walls. Sporosarcina halophila was shown to be genetically distinct from S. ureae and formed a loose association with the main Bacillus subtilis grouping. Marinococcus halophilus (formerly Planococcus halophilus) exhibited low levels of relatedness to all reference species examined and formed a distinct line of descent.     

The division during bacterial sporulation is symmetrically located in Sporosarcina ureae

Immunofluorescence microscopy was used to visualize the FtsZ band that marks the site of septation in Sporosarcina ureae . Image analysis indicated that the vegetative division was symmetrically located with respect to the ends of the cells. Fusions of lacZ to the sporulation loci, spoIIA and cotE , of Bacillus subtilis were introduced into S . ureae by mobilization of plasmids containing the fusions from Escherichia coli . The fusions showed similar patterns of sporulation-associated expression in S . ureae to those observed in B . subtilis . Formation of β-galactosidase encoded by the spoIIA–lacZ fusion made it possible to identify early sporulating cells by immunofluorescence microscopy. Analysis of the position of FtsZ bands in cells expressing spoIIA–lacZ indicated that the location of sporulation division was symmetrical with respect to the ends of the cells, in sharp contrast to the asymmetrical location of septation in sporulating Bacilli . It is inferred that asymmetry of location of the sporulation division is not essential for the compartmentalization of gene expression that follows the division.     

Surface arrays on the wall of Sporosarcina ureae.

Thin sections of the cell wall of Sporosarcina ureae revealed two structurally distinct layers: a continuous amorphous zone, approximately 15 nm thick, which was adjacent to the plasma membrane, and an overlying periodic zone, approximately 16 nm thick. Sequential Triton X-100 and lysozyme treatment of isolated walls produced small fragments of the outer regular structure which allowed high-resolution, negatively stained images suitable for optical diffractometric analysis. These data suggested a tetragonal array of complex polygonal units of C-C spacing = 12 nm, with each unit joined to another by two delicate linkers. The array was entirely proteinaceous, consisting of a 150,000-dalton polypeptide which had a high affinity for Mg2+. It proved to be sensitive to chelating agents, 5 mM concentrations of Ca2+, Sr2+, or Ba2+, proteases, heat greater than or equal to 45 degrees C, sodium dodecyl sulfate, and pH greater than or equal to 5.8, but magnesium offered protection against the chelating agents and the deleterious salts.     

Comparative allostery of 3-deoxy-D-arabino-heptulosonate-7-phosphate synthetase as a molecular basis for classification

The allosteric pattern of control for 3-deoxy-d-arabino-heptulosonate 7-phosphate (DAHP) synthetase has previously been shown to be strongly conserved among the member species of a given genus in bacteria. The implications of this finding as a procedural tool of bacterial phylogeny were pursued by a study of two organisms, Sporosarcina ureae and Aeromonas formicans, the taxonomic positions of which have been historically controversial. S. ureae has characteristics of both Bacillaceae and Micrococcaceae, and A. formicans has characteristics of both Enterobacteriaceae and pseudomonads. Since the patterns of control for DAHP synthetase in all four of these microbial groups are different from one another but internally homogeneous within each group, the results obtained from the two test organisms were unambiguous. It was concluded that S. ureae is properly classified within Bacillaceae, probably deserving generic rank, and that A. formicans belongs with the family Enterobacteriaceae.     

16S ribosomal RNA analysis of Filibacter limicola indicates a close relationship to the genus Bacillus

The phylogenetic relationship of the Gram-negative, filamentous gliding bacterium Filibacter limicola was analysed by 16S rRNA oligonucleotide cataloguing. In contrast to the proposed membership of this asporogenous species in the Flexibacteriaceae, Filibacter limicola clusters phylogenetically with the Gram-positive eubacteria Bacillus pasteurii, Sporosarcina ureae and the asporogenous species Planococcus citreus. The genetic relationship is supported by several common phenotypic properties.     

Novel phenylalanine dehydrogenases from Sporosarcina ureae and Bacillus sphaericus. Purification and characterization

NAD+-dependent phenylalanine dehydrogenases were purified 1,500- and 1,600-fold, and crystallized from Sporosarcina ureae SCRC-R04 and Bacillus sphaericus SCRC-R79a, respectively. The purified enzymes were homogeneous as judged by disc gel electrophoresis. The enzyme from S. ureae has a molecular weight of 305,000, while that of B. sphaericus has a molecular weight of 340,000. Each is probably composed of eight subunits identical in molecular weight. The S. ureae enzyme showed a high substrate specificity in the oxidative deamination reaction acting on L-phenylalanine, while that of B. sphaericus acted on L-phenylalanine and L-tyrosine. The enzymes had lower substrate specificities in the reductive amination reaction acting on alpha-keto acids. The Sporosarcina enzyme acted on phenylpyruvate, alpha-ketocaproate, alpha-keto-gamma-methylthiobutyrate and rho-hydroxyphenylpyruvate. The Bacillus enzyme acted on rho-hydroxyphenylpyruvate, phenylpyruvate, and alpha-keto-gamma-methylthiobutyrate. The enzyme from B. sphaericus catalyzes The enzyme from B. sphaericus catalyzes the transfer of pro-S (B) hydrogen from NADH.     

Small, acid-soluble, spore proteins and their genes from two species of Sporosarcina

Small, acid-soluble proteins (SASP) of both the alpha/beta- and gamma-type were present in spores of Sporosarcina ureae and S. halophila, and three genes encoding alpha/beta-type SASP in these species have been cloned and sequenced. The amino acid sequences of the Sporosarcina alpha/beta-type SASP are extremely homologous to those of Bacillus SASP, further indicative of the close evolutionary relationship between these genera.     

Localization of α-galactomannan and of wheat germ agglutinin receptors inSchizosaccharomyces pombe

The location of galactomannan on the surface ofSchizosaccharomyces pombe cells was reexamined by scanning electron microscopy by an indirect but specific method using gold markers. The polysaccharide was found on the cell surface and at the end beginning to grow but not on the wall established by division. Galactomannan was also localized onS. pombe thin sections by transmission electron microscopy using the same method. The polysaccharide was found deposited in two layers in the cell wall, i.e. at the periphery of the wall and near the plasmalemma. The septum was also marked but mainly near the plasmalemma. These results indicated that the polysaccharide is elaborated onto the outside of the wall during extension but not during septum formation. When thin sections ofS. pombe were marked with gold granules labeled with wheat germ agglutinin, marking was found in vacuoles but not in the cell wall. This confirmed thatS. pombe cell wall is devoid of chitin.Non-Standard Abbreviations Au gold colloid - RCA_I Ricinus communis lectin - SEM scanning electron microscopy - TEM transmission electron microscopy - WGA wheat germ agglutinin     

Ultrastructural organization of Alicyclobacillus tolerans strain K1T cells

Electron microscopy examinations of thin sections and freeze-fracture replicas revealed the specific ultrastructural features of Alicyclobacillus tolerans strain K1(T). In particular, the cell wall displayed an ultrastructure typical of gram-positive bacteria and consisted of a thin murein layer (50-60 A in thickness); cells exhibited a surface S-layer constituted by large hexagonally packed (p6-symmetry) rod-shaped subunits of 150-160 A in diameter and 200 A in height. In the cytoplasmic membrane, there were intramembrane vesicular structures that sometimes appeared as large leaflets in the central part. The cytoplasm contained numerous vesicular inclusions covered with a monolayered wall, dissimilar to bilamellar lipid membranes. Endospore coats displayed an intricate structure and consisted of three thick layers; the outer layer had an unusual fine structure; the exosporium was also found.     

Ca(2+)-dependent association of S100A6 (Calcyclin) with the plasma membrane and the nuclear envelope.

Expression of S100A6 (Calcyclin), a member of the S100 family and of Zn(2+)-binding proteins is elevated in a number of malignant tumors. In vitro the protein associates with several actin-binding proteins and annexins in a Ca(2+)-dependent manner. We have now studied the subcellular localization of S100A6 using a new, specific monoclonal antibody. Immunofluorescence microscopy of unfixed, ultrathin, frozen sections demonstrated a dual localization of S100A6 at the nuclear envelope and the plasma membrane of porcine smooth muscle only in the presence of Ca(2+). The same localization was found by immunofluorescence and immunogold electron microscopy as well as by confocal laser scanning microscopy with cultured, fixed, human CaKi-2 and porcine ST interphase cells. Upon cell division, however, S100A6 was found exclusively in the cytoplasm. Cell fractionation studies showed that S100A6 was present in the microsomal fraction in the presence of Ca(2+) and was released from this fraction by the addition of EGTA/EDTA but not by Triton X-100. The data demonstrate that S100A6 is localized both at the plasma membrane and the nuclear envelope in vivo and suggest a Ca(2+)-dependent interaction with annexins or other components of the nuclear envelope.     

ELECTRON MICROSCOPY OF CELLULAR DIVISION IN ESCHERICHIA COLI.

Conti, S. F. (Brookhaven National Laboratory, Upton, N. Y.) and M. E. Gettner. Electron microscopy of cellular division in Escherichia coli. J. Bacteriol. 83:544-550. 1962.-Exponentially growing cells of Escherichia coli were fixed in formalin, exposed to uranyl nitrate, dehydrated at low temperatures with ethanol, and embedded in methacrylate. Polymerization was carried out at -70 C, by exposure of specimens to radiation from a cobalt(60) source. Electron micrographs revealed that cellular division occurs by the centripetal growth of the cell wall. The fine structure of the cytoplasm, nuclear apparatus, cell wall, and cytoplasmic membrane was also studied.     

Localization to the nucleolus is a common feature of coronavirus nucleoproteins, and the protein may disrupt host cell division

The subcellular localization of transmissible gastroenteritis virus (TGEV) and mouse hepatitis virus (MHV) (group I and group II coronaviruses, respectively) nucleoproteins (N proteins) were examined by confocal microscopy. The proteins were shown to localize either to the cytoplasm alone or to the cytoplasm and a structure in the nucleus. This feature was confirmed to be the nucleolus by using specific antibodies to nucleolin, a major component of the nucleolus, and by confocal microscopy to image sections through a cell expressing N protein. These findings are consistent with our previous report for infectious bronchitis virus (group III coronavirus) (J. A. Hiscox et al., J. Virol. 75:506-512, 2001), indicating that nucleolar localization of the N protein is a common feature of the coronavirus family and is possibly of functional significance. Nucleolar localization signals were identified in the domain III region of the N protein from all three coronavirus groups, and this suggested that transport of N protein to the nucleus might be an active process. In addition, our results suggest that the N protein might function to disrupt cell division. Thus, we observed that approximately 30% of cells transfected with the N protein appeared to be undergoing cell division. The most likely explanation for this is that the N protein induced a cell cycle delay or arrest, most likely in the G(2)/M phase. In a fraction of transfected cells expressing coronavirus N proteins, we observed multinucleate cells and dividing cells with nucleoli (which are only present during interphase). These findings are consistent with the possible inhibition of cytokinesis in these cells.     

Unusual ultrastructural features in three strains of Cyanothece (cyanobacteria)

Three unicellular cyanobacterial strains (PCC 7425, PCC 8303, PCC 9308) assigned to the genus Cyanothece Komárek 1976, which showed an unusually high content of light refractile inclusions when viewed by phase-contrast microscopy, were characterized by confocal laser scanning microscopy and transmission electron microscopy. All strains had concentric cortical thylakoids and a compact central nucleoid. Frequently, the two innermost thylakoid membranes protruded to form circular enclosures containing cytoplasm or electron-transparent granules, or both. The largest granules were partially immersed in the nucleoid region, but they remained attached to the inner cortical thylakoids by a single narrow connection. The pattern of binary cell division in strain PCC 7425 was different than that in strains PCC 8303 and PCC 9308. In the former, all cell wall layers invaginated simultaneously, whereas in the latter the invagination of the outer membrane was delayed compared to that of the cytoplasmic membrane and the peptidoglycan layer. Thus, prior to completion of cell division, the new daughter cells of strains PCC 8303 and PCC 9308 were transiently connected by a thick septum, which was not observed in strain PCC 7425. Nucleoid partitioning coincided with initiation of cell division in all three strains and was unlike that reported in other bacteria and in archaea, in which separation of the nucleoids precedes cell division. Based on the common morphological and ultrastructural features, the three strains of Cyanothece examined constitute a distinct cluster, which might deserve independent generic status.     

Localization of dibenzodioxocin substructures in lignifying Norway spruce xylem by transmission electron microscopy–immunogold labeling

The lignification process in mature Norway spruce [Picea abies (L.) H. Karsten] xylem cell walls was studied using transmission electron microscopy (TEM)–immunogold detection with a polyclonal antibody raised against a specific lignin substructure, dibenzodioxocin. The study reveals for the first time the exact location of this abundant eight-ring structure in the cell wall layers of wood. Spruce wood samples were collected in Southern Finland at the time of active growth and lignification of the xylem cell walls. In very young tracheids where secondary cell wall layers were not yet formed, the presence of the dibenzodioxocin structure could not be shown at all. During secondary cell wall thickening, the dibenzodioxocin structure was more abundant in the secondary cell wall layers than in the middle lamella. The highest number of gold particles revealing dibenzodioxocin was in the S2+S3 layer. Statistically significant differences were found in the frequency of gold particles present in various cell wall layers. For comparison, wood sections were also cut with a cryomicrotome for light and fluorescence microscopy.     

Giardia intestinalis: transmission electron microscopy study of in vitro excystation]

The in vitro excystation process in Giardia intestinalis was studied by transmission electron microscopy (TEM). Untreated cysts served as controls. The excystation process was monitored by examination of organisms after the in vitro induction and at several times during the incubation phase. The control cyts had a thick wall, made of microfibrils, that appeared not to contain any weak areas. The peritrophic space extended between the cyst wall and the organism peripherally, the space was delimited by a thin cytoplasmic layer, "the outer cytoplasmic envelope" that subtended the cyst wall. During the in vitro incubation, the trophozoite cytoplasm retracted from the wall; thus, the peritrophic space became progressively larger. The outer cytoplasmic envelope detached from the cyst wall, then broke up forming numerous small vesicles lodged between the wall and the organism. The tight arrangement of the wall microfibirils was lost. Electron-dense vacuoles appeared in the peripheral cytoplasm of the trophozoite. The organism emerged through the posterior end of the cyst, leaving behind the empty husk. Emergence was followed by cell division. The possible interrelationships of biochemical and mechanical factors affecting the process of excystation are discussed in light of the present TEM findings.     

Ultrastructure of the Cell Wall and Cell Division of Unicellular Blue-green Algae

The fine structure of the cell wall and the process of cell division were examined in thin sections of two unicellular blue-green algae grown under defined conditions. Unilateral invagination of the photosynthetic lamellae is the first sign of cell division in the rod-shaped organism, Anacystis nidulans. Symmetrical invagination of the cytoplasmic membrane and inner wall layers follows. One wall layer, which appears to be the mucopolymer layer, is then differentially synthesized to form the septum; the outer wall layers are not involved in septum formation. Centripetal splitting of the inner layer separates the two daughter cells. A second division, in a plane parallel to the first, usually occurs before the first daughter cells are separated. In the coccoid organism, Gleocapsa alpicola, the features of cell division are broadly similar; however, unilateral invagination of the lamellae is not observed and the second division takes place in a plane perpendicular to the plane of the previous division.     

Detection of growth sites in and protomer pools for the sheath of Methanospirillum hungatei GP1 by use of constituent organosulfur and immunogold labeling.

Methanospirillum hungatei GP1 integrated approximately 9% of cellular [35S]cysteine into its sheath. Autoradiography of sodium dodecyl sulfate-polyacrylamide gels revealed that [35S]cysteine was confined to the proteins released by the sodium dodecyl sulfate-beta-mercaptoethanol-EDTA solubilization method (G. Southam and T. J. Beveridge, J. Bacteriol. 173:6213-6222, 1991) and was not present in the proteins released by treatment with phenol (G. Southam and T. J. Beveridge, J. Bacteriol. 174:935-946, 1992). Limited labeling of exposed sulfhydryl groups on hoops produced from sheath material suggested that most organosulfur groups occur within hoops and therefore help contribute to resilience. Electron microscopic autoradiography demonstrated that sheath growth, which is most active at the sites of cell division (spacer region), occurs through the de novo development of hoops. For growth to occur in the spacer region, sheath precursors must transverse several periodic envelope layers, including the cell wall (a single layer) and the various lamellae of the spacer plug (T. J. Beveridge, G. D. Sprott, and P. Whippey, J. Bacteriol. 173:130-140, 1991).     

Fine structure ofMicrococcus denitrificans andM. halodenitrificans in relation to their taxonomy

A study of ultrathin sections ofMicrococcus denitrificans andM.halodenitrificans has shown similar cell structures. The cell wall consists of several layers corresponding to those of the cell wall of gram-negative bacteria. The thickness of the cell wall is 250 – 350 Å; that of the cytoplasmic membrane 70 Å. The cytoplasm in both species contains ribosomes and inclusions of polymetaphosphate. Comparison with ultrathin sections ofThiobacillus novellus shows too much difference to consider the former two species to be identical with the latter one. The taxonomic position ofM.denitrificans andM.halodenitrificans is discussed.Deceased 3 July 1967.