Morphological and serological analysis of leptospiral structure

Pathogenic Leptospira: Advances in understanding the molecular pathogenesis and virulence

Leptospirosis is a common zoonotic disease has emerged as a major public health problem, with developing countries bearing disproportionate burdens. Although the diverse range of clinical manifestations of the leptospirosis in humans is widely documented, the mechanisms through which the pathogen causes disease remain undetermined. In addition, leptospirosis is a much-neglected life-threatening disease although it is one of the most important zoonoses occurring in a diverse range of epidemiological distribution. Recent advances in molecular profiling of pathogenic species of the genus Leptospira have improved our understanding of the evolutionary factors that determine virulence and mechanisms that the bacteria employ to survive. However, a major impediment to the formulation of intervention strategies has been the limited understanding of the disease determinants. Consequently, the association of the biological mechanisms to the pathogenesis of Leptospira, as well as the functions of numerous essential virulence factors still remain implicit. This review examines recent advances in genetic screening technologies, the underlying microbiological processes, the virulence factors and associated molecular mechanisms driving pathogenesis of Leptospira species.

Do prokaryotes contain microtubules?

In eukaryotic cells, microtubules are 24-nm-diameter tubular structures composed of a class of conserved proteins called tubulin. They are involved in numerous cell functions including ciliary motility, nerve cell elongation, pigment migration, centrosome formation, and chromosome movement. Although cytoplasmic tubules and fibers have been observed in bacteria, some with diameters similar to those of eukaryotes, no homologies to eukaryotic microtubules have been established. Certain groups of bacteria including azotobacters, cyanobacteria, enteric bacteria, and spirochetes have been frequently observed to possess microtubule-like structures, and others, including archaebacteria, have been shown to be sensitive to drugs that inhibit the polymerization of microtubules. Although little biochemical or molecular biological information is available, the differences observed among these prokaryotic structures suggest that their composition generally differs among themselves as well as from that of eukaryotes. We review the distribution of cytoplasmic tubules in prokaryotes, even though, in all cases, their functions remain unknown. At least some tend to occur in cells that are large, elongate, and motile, suggesting that they may be involved in cytoskeletal functions, intracellular motility, or transport activities comparable to those performed by eukaryotic microtubules. In Escherichia coli, the FtsZ protein is associated with the formation of a ring in the division zone between the newly forming offspring cells. Like tubulin, FtsZ is a GTPase and shares with tubulin a 7-amino-acid motif, making it a promising candidate in which to seek the origin of tubulins.

Immunodominant antigens recognized by the human immune response to infection by organisms of the species Leptospira interrogans serogroup Australis

Serum samples from patients infected by organisms of Leptospira interrogans serogroup Australis were tested by Western blot to determine the nature of major antigens that are involved in the immune response. Although there was some patient-to-patient variability, immunodominant genus-specific antigens were found to be proteins of apparent molecular ratio 68, 46 and 35-kDa, and lipopolysaccharide (LPS) sub-units in the 35-14-kDa region. Serogroup epitopes specific for Australis were exclusively saccharides of about 32 and 24 kDa: a serovar-specific antigen for serovar lora was of 38-40 kDa and behaved like a protein. Antibodies to the LPS serogroup-specific antigens and to the 38-40 kDa protein were long-lasting and consequently suggest that these immunodominant epitopes are important in resistance to re-infection.

Genus-specific antigens in Leptospira revealed by immunoblotting

Immunoblotting of leptospiral sonicates with heterologous rabbit antisera revealed a distinct cross-reactive pattern which differed with respect to the pathogenic and non-pathogenic leptospiral serovars, and that all serovars tested from Leptospira interrogans, L. biflexa and L. illini contained a common 35 kilodalton (Kd) band. A leptospiral genus-specific antigen preparation produced by ethanol fractionation of L. biflexa serovar patoc reacted by enzyme immunoassay (EIA) with all heterologous serovars tested. Further purification using Sephacryl S-300 gel filtration revealed one major cross-reactive peak and several homologous peaks detectable by EIA. Gel electrophoresis of this peak revealed 3 major protein bands of 35, 34 and 29 Kd by Coomassie blue staining. This peak was further fractionated by high pressure liquid chromatography (HPLC), yielding 7 fractions, one of which cross-reacted. Rabbit antisera to this S-300/HPLC fraction reacted with all serovars tested. Immunoblotting revealed 2 distinct groups of cross-reactive antigens, a 33-35 Kd group that was proteinase K sensitive but not reduced by periodate oxidation, and a 14.4-26.5 Kd group whose activity was reduced by periodate but not proteinase K, indicating the presence of both protein and carbohydrate genus antigens. Immunoblotting L. interrogans serovar pomona flagella with S-300/HPLC antiserum suggested that the 35 Kd band found in all serovars tested was a flagellar component.

Detection of antibodies to leptospiral genus-specific antigen in human and animal sera by indirect hemagglutination test with a partially purified genus-specific protein antigen

Antibodies against leptospiral genus-specific antigen were detected in the sera from clinically diagnosed human leptospirosis and suspected animal leptospirosis by indirect hemagglutination (IHA) test with a partially purified genus-specific protein antigen (GP-Ag). The reaction was positive in the infected humans and animals irrespective of the leptospiral serovars. No significant correlation was found between IHA titer against GP-Ag and microscopic agglutination (MA) titer. IHA titer did not always develop in parallel with MA titers. Sera obtained from healthy individuals were negative in both IHA and MA tests.

Chemical compositions of cell walls and polysaccharide fractions of spirochetes

Cellular polysaccharide fractions of various representative members of genera of the family Spirochaetaceae were obtained by the ammonium hydroxide extraction method. The sugar composition of the polysaccharide preparations was complex and many kinds of sugars such as rhamnose, fucose, ribose, xylose, mannose, galactose, and glucose were detected in all of the spirochetes tested. Of particular interest was the presence of 4-O-methylmannose as a constituent polysaccharide in members of the genus Leptospira. This sugar was not detected in the polysaccharides of Spirochaeta, Borrelia, and Treponema. The chemical compositions of cell wall fractions were also examined. 4-O-Methylmannose was detected in the cell wall polysaccharides of the genus Leptospira but not in cell walls prepared from the Spirochaeta, Borrelia, and Treponema. The diaminopimelic acid present in cell wall peptidoglycans of the genus Leptospira was meso-diaminopimelic acid (A2pm). The molar ratios of alanine, glutamic acid, A2pm, glycine, muramic acid, and glucosamine in leptospiral cell walls were found to be approximately 2:1:1:1:1:1. In contrast to the Leptospira, the peptidoglycans of genera Spirochaeta, Borrelia, and Treponema contained ornithine (Orn) but not A2pm. Since 4-O-methylmannose and A2pm were found in the cell wall fractions of genus Leptospira but not in Spirochaeta, Borrelia, or Treponema, it was suggested that the chemical compositions of the cell wall might become an important criterion for the chemotaxonomy of Spirochaetales.

Chemical and biological properties of a peptidoglycan isolated from Treponema pallidum kazan

A peptidoglycan layer of Treponema pallidum kazan was isolated by solubilization of whole cells with 1% warm sodium dodecyl sulfate and subsequent digestion of an insoluble residue with proteases. Electron microscopy revealed that the peptidoglycan was isolated as a single-layered sacculus of less than 5 nm in thickness, freed from axial filaments and an envelope sheath. An isolated peptidoglycan fraction was mainly composed of glucosamine, muramic acid, alanine, glutamic acid, ornithine, and glycine in molar ratios of 0.65:0.68:1.63:1.00:0.75:1.03. Amino (N)- and carboxyl (C)-terminal amino acid analyses suggested the involvement of at least a part of the glycine residue in cross-linking between the amino group of ornithine residue at one strand of the stem peptide subunit and the carboxyl group of alanine of the neighboring strand. The treponemal peptidoglycan lacked the immunoadjuvant activity both to stimulate antibody production and to induce delayed-type hypersensitivity against ovalbumin, as well as the properties necessary to stimulate guinea pig and mouse splenocytes and guinea pigs peritoneal macrophages, unlike the cell walls or peptidoglycans (group A type of Schleifer and Kandler's classification, Bacteriol. Rev. 36:407-477, 1972) isolated from many bacterial species parasitic to the mammal. However, the peptidoglycan activated the human complement system through the alternative pathway, as well as the classical one, and caused a liberation of 5-hydroxytryptamine in rabbit blood platelets in a similar manner to the cell wall peptidoglycans of both group A and B types.

Chemical studies on the cell walls of Leptorspira biflexa strain Urawa and Treponema pallidum strain Reiter

The preparation and chemical properties of the cell walls of Leptospira biflexa Urawa and Treponema pallidum Reiter are described. Both cell walls are composed mainly of polysaccharides and peptidoglycans. The data of chemical analysis indicate that the cell wall of L. biflexa Urawa contains rhamnose, arabinose, xylose, mannose, galactose, glucose and unidentified sugars as neutral sugars, and alanine, glutamic acid, alpha, epsilon-diaminopimelic acid, glucosamine and muramic acid as major amino acids and amino sugars. As major chemical constituents of the cell wall of T. pallidum Reiter, rhamnose, arabinose, xylose, mannose, galactose, glucose, alanine, glutamic acid, ornithine, glycine, glucosamine and muramic acid have been detected. The chemical properties of protein and polysaccharide fractions prepared from the cells of T. pallidum Reiter were also partially examined.

Peptidoglycan of free-living anaerobic spirochetes

Electron microscope examination of negatively stained or thin-sectioned cells of Spirochaeta stenostrepta treated with penicillin or lysozyme showed that the peptidoglycan was present as a thin, electron-dense layer adjacent and external to the cytoplasmic membrane. The peptidoglycan was isolated from cells of S. stenostrepta and Spirochaeta litoralis by a procedure including treatments with sodium lauryl sulfate and Pronase. Hydrolysates of the isolated S. stenostrepta and S. litoralis peptidoglycans contained glucosamine, muramic acid, glutamic acid, l-ornithine, and alanine in molar ratios of 0.90:0.85:1.00:1.00:1.40 and of 0.63:0.63:0.99:1.00:1.41, respectively. Determination of N-terminal residues suggested that nearly 50% of the ornithine in S. stenostrepta and S. litoralis peptidoglycans was involved in peptide cross-linkage. The peptidoglycan layer of S. stenostrepta was sensitive to lysozyme and myxobacter AL-1 protease.

Estrutura antigênica e constituição química das leptospiras

Os autores fazem um estudo comparativo entre os métodos de sedimentação, MIF-C e Kato em relação à eficiência para diagnosticar ovos de helmintos, em especial os de Schistosoma mansoni. Discutem as possibilidades e limitações dos métodos assinalados e concluem pela maior eficiência do método de sedimentação.

Isolation of the outer sheath of Leptospira and its immunogenic properties in hamsters

Spherical forms of Leptospira interrogans serotype canicola Hond Utrecht IV were induced with 1 m NaCl. Electron micrographs of these salt-altered cells (SAC) revealed that the outer envelope or sheath had pulled away from the protoplasmic cylinder. Treatment of SAC with 0.02% sodium lauryl sulfate solubilized the sheath and released the protoplasmic cylinder. Further processing of the solubilized sheath yielded a pellet which displayed a membrane structure in electron micrographs. The released protoplasmic cylinder showed loss of intracellular organization and the outer envelope present in normal cells. Immunization of hamsters with whole formalized cells, SAC, or sheath in doses as low as 10 mug/animal protected them from death upon challenge with virulent canicola 27.

Isolation and characterization of a leptospiral type-specific antigen

The type-specific main (TM) antigen was extracted from the leptospiral cells of strain Kyoto of the Hebdomadis group by 90% phenol and was purified mainly by ethanol precipitation. The TM antigen was specific, forming one precipitin band by immunodiffusion and reacting by complement fixation test with anti-strain Kyoto serum; so far as has been tested, it does not appear to react with antisera of other serotypes. The sedimentation velocity of the TM antigen was 216S. Morphologically the TM antigen was filamentous in shape with a uniform width of 25 to 30 nm and various lengths from 50 nm to 1 mum. The infrared absorption pattern of the TM antigen generally resembled that of gram-negative bacterial endotoxin, and this fact suggests that the antigen is composed mainly of lipopolysaccharides. Galactose, rhamnose, xylose, arabinose, glucosamine, 13 kinds of acidic and neutral amino acids, lipids, and phosphorus were found in the TM antigen.

Purification, ultrastructure, and composition of axial filaments from Leptospira

The ultrastructure of three strains of water Leptospira was studied by negative staining, thin sectioning, and freeze-etching. The cells possessed a triple-layered sheath which covered two independent axial filaments, one inserted subterminally in each end of the cell. The protoplasmic cylinder was surrounded by a triple-layered cell wall and possessed ribosomes, lamellar structures, and a typical procaryotic nuclear region. The axial filament was comprised of several component structures. An axial fibril, with a diameter of 20 to 25 nm, consisted of a solid inner core (13 to 16 nm in diameter) surrounded by a coat. A terminal knob (40 to 70 nm in length) was connected to a series of disc insertion structures at the terminal end of the axial fibril. The axial fibril was surrounded by a helical outer coat (35 to 60 nm in diameter) which was composed of a continuously coiled fiber, 3 to 4 nm in diameter, embedded in an electron-dense material. A procedure for the purification of the axial fibrils was presented and their ultrastructural, physical, and chemical properties were determined. Similarities in ultrastructural, physical, and chemical properties were noted between the axial fibrils and bacterial flagella. A schematic model of the leptospiral axial filament is presented, and a mechanism is proposed for its function as a locomotor organelle.

Microfibers present in surface structure of Leptospira

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Electron microscopy of immune disruption of leptospires: action of complement and lysozyme

Sequential disruption of the sheath of avirulent leptospires of the serotype canicola with antibody and complement was monitored by electron microscopy. Loosening and separation of the sheath from the protoplasmic cylinder was observed as early as 2 min after exposure to complement. Virulent leptospires of this serotype were morphologically intact after 1 hr of exposure to antibody and complement. Similarly, treatment of leptospires of the serotype patoc with normal serum and complement severely damaged the sheath structure. Removal of the sheath of both serotypes permitted lysozyme to act on the wall of the protoplasmic cylinder. Thus, morphological evidence for the location of the mucopeptide-containing structure of these leptospires was obtained. Viable leptospires with intact sheaths were resistant to lysozyme alone. Sections and negatively stained preparations of sheaths of serotypes canicola and patoc revealed three dense layers with two intermediate light zones and an overall thickness of about 110 A. A periodicity of 40 A was observed in sheath fragments produced by complement. The 70 A wallmembrane complex of leptospires of both serotypes consisted of two dense layers with an intermediate light zone. Structures apparent after removal of the outer sheath included membranous bodies or mesosomes, axial filaments attached to terminal knobs at opposite ends of the cell, and electron-dense intracellular bodies.