Spirochete periplasmic flagella and motility

Spirochetes have a unique structure, and as a result their motility is different from that of other bacteria. They also have a special attribute: spirochetes can swim in a highly viscous, gel-like medium, such as that found in connective tissue, that inhibits the motility of most other bacteria. In spirochetes, the organelles for motility, the periplasmic flagella, reside inside the cell within the periplasmic space. A given periplasmic flagellum is attached only at one end of the cell, and depending on the species, may or may not overlap in the center of the cell with those attached at the other end. The number of periplasmic flagella varies from species to species. These structures have been shown to be directly involved in spirochete motility, and they function by rotating within the periplasmic space. The mechanics of motility also vary among the spirochetes. In Leptospira, a motility model developed several years ago has been extensively tested, and the evidence supporting this model is convincing. Borrelia burgdorferi swims differently, and a model of its motility has been recently put forward. This model is based on analyzing the motion of swimming cells, high voltage electron microscopy of fixed cells, and mutant analysis. To better understand spirochete motility on a more molecular level, the proteins and genes involved in motility are being analyzed. Spirochete periplasmic flagellar filaments are among the most complex of bacterial flagella. They are composed of the FlaA sheath proteins, and in many species, multiple FlaB core proteins. Allelic exchange mutagenesis of the genes which encode these proteins is beginning to yield important information with respect to periplasmic flagellar structure and function. Although we are at an early stage with respect to analyzing the function, organization, and regulation of many of the genes involved in spirochete motility, unique aspects have already become evident. Future studies on spirochete motility should be exciting, as only recently have complete genome sequences and tools for allelic exchange mutagenesis become available.     

Antigenic variation of Campylobacter flagella.

Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of flagella dissociated from strains of Campylobacter coli and Campylobacter jejuni belonging to the heat-labile serogroup LIO 8 showed that some strains were capable of producing flagellin subunits of two different molecular weights (MrS), 59,500 and 61,500. Immunoelectron microscopy of cultures of the type strain of this serogroup, C. coli VC167, showed the presence of two flagellum filaments of different antigenic specificity. Epitopes on the surface of one of these flagella bound antibodies in LIO 8 typing antiserum, and Western blotting (immunoblotting) and immunoprecipitation showed that the flagellum was composed of flagellin of Mr 61,500. The other flagellum antigenic type did not bind LIO 8 antibodies but did possess serospecific epitopes which bound a second polyclonal antiserum, LAH2. This second antigenic flagellum type was composed of the Mr 59,500 flagellin. Cells producing either of the flagellum antigenic types serotyped as LIO 8, indicating that flagella composed of the Mr 61,500 flagellin do not carry the serological determinants for this serogroup. The ability of C. coli VC167 to produce these flagella of different subunit MrS was shown to represent a bidirectional antigenic variation. When measured in culture medium, the phase 1-to-phase 2 transition occurred at a rate of approximately 2.0 x 10(-5) per cell per generation, and the phase 2-to-phase 1 transition occurred at a rate of 1.2 x 10(-6) per cell per generation.     

Molecular architecture of the sperm flagella: molecules for motility and signaling

Sperm motility is generated by a highly organized, microtubule-based structure, called the axoneme, which is constructed from approximately 250 proteins. Recent studies have revealed the molecular structures and functions of a number of axonemal components, including the motor molecules, the dyneins, and regulatory substructures, such as radial spoke, central pair, and other accessory structures. The force for flagellar movement is exerted by the sliding of outer-doublet microtubules driven by the molecular motors, the dyneins. Dynein activity is regulated by the radial spoke/central pair apparatus through protein phosphorylation, resulting in flagellar bend propagation. Prior to fertilization, sperm exhibit dramatic motility changes, such as initiation and activation of motility and chemotaxis toward the egg. These changes are triggered by changes in the extracellular ionic environment and substances released from the female reproductive tract or egg. After reception of these extracellular signals by specific ion channels or receptors in the sperm cells, intracellular signals are switched on through tyrosine protein phosphorylation, Ca2+, and cyclic nucleotide-dependent pathways. All these signaling molecules are closely arranged in each sperm flagellum, leading to efficient activation of motility.     

Expression of flagella and motility by Shigella

Since the discovery of Shigella as the aetiologic agent of acute dysentery almost 100 years ago, this organism has been described as a non-motile and non-flagellated organism that invades the human colonic mucosa. In this study, the production of flagella by prototypic strains of all four Shigella species and, moreover, by fresh clinical isolates was demonstrated by electron microscopy. The fla gellum of Sh igella (flash) is ∼10 µm long and 12–14 nm in diameter and is typically seen emanating from one pole of the bacterium. Flash is composed of a putative structural polypeptide subunit of 33–38 kDa that shares immunological similarities with Escherichia coli , Salmonella spp., and Proteus mirabilis flagellins, and with the recently described recombinant Shigella flagellins (FliC_SS and FliC_SF) expressed in E. coli K-12. A fliC_SS -specific oligo probe hybridized with all four Shigella species, while a fliC_SF probe hybridized with all Shigella flexneri and Shigella dysenteriae strains, but not with all Shigella sonnei or Shigella boydii strains, indicating genetic divergence among their flagellin genes. Shigella exhibits motility in low-concentration motility agar under physiological growth conditions. The expression of flash and motility appears to be strictly regulated by unidentified genetic and environmental factors. These heretofore undescribed features may allow the bacteria to circumvent the natural intestinal mucosal defences leading to bacterial colonization and disease. The motility of shigellae may represent an evolutionary adaptation important for bacterial survival.     

More than propellers: how flagella shape bacterial motility behaviors

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NGF: not just for neurons.

Nerve growth factor (NFF) is the prototypic member of a family of related neurotrophins (Nts). Although originally defined by its actions in the peripheral and central nervous systems, recent data indicate the presence of extensive interactions between NGF and the endocrine and immune systems steroid hormones are able to modulate the neurosomal expression of NGF, while functional NGF receptors have been detected on cells of the immune system, and increased levels of NGF protein are found during the acute phase of diseases with a significant inflammatory component. These wider functions are likely to be of concern in any attempted therapeutic use of NGF.     

Senescence: not just for tumor suppression

Cellular senescence provides an intrinsic barrier to tumor development by preventing the proliferation of cells that are at risk for malignant transformation. In this issue, Krizhanovsky et al. (2008) report that senescence is an important player not only in tumor suppression but also in the response of liver tissue to injury.     

Ubiquitin: not just for proteasomes anymore

Ubiquitin is a small protein that can be covalently linked to itself or other proteins, either as single ubiquitin molecules or as chains of polyubiquitin. Addition of ubiquitin to a target protein requires a series of enzymatic activities (by ubiquitin-activating, -conjugating and -ligating enzymes). The first function attributed to ubiquitin was the covalent modification of misfolded cytoplasmic proteins, thereby directing proteasome-dependent proteolysis. More recently, additional functions have been ascribed to ubiquitin and ubiquitin-related proteins. Ubiquitin directs specific proteins through the endocytic pathway by modifying cargo proteins, and possibly also components of the cytoplasmic protein trafficking machinery.     

Reversible expression of flagella in Campylobacter spp.

The in vitro phase variation of flagella and the transition rates between flagellate and aflagellate phenotypes in Campylobacter species including C. jejuni, C. coli, C. lari (thermophilic campylobacters), C. fetus subsp. fetus, C. fetus subsp. venerealis and C. hyointestinalis were investigated. The change from the flagellate to aflagellate phenotype was detected in all of the 12 Campylobacter strains studied. When measured in a motility medium, flagellate to aflagellate transition in thermophilic campylobacters, C. fetus and C. hyointestinalis strains occurred at a rate of 1.8 x 10(-3) to 7.5 x 10(-3), 3.0 x 10(-4) to 7.8 x 10(-4) and 1.8 x 10(-5) to 7.7 x 10(-6) per cell per generation, respectively. Transition from aflagellate to flagellate phenotype occurred at a rate of 5.8 x 10(-6) to 9.3 x 10(-6) per cell per generation in thermophilic campylobacters and 1.0 x 10(-6) to 1.5 x 10(-6) in C. fetus strains. No reversion from aflagellate to flagellate phenotype could be detected in C. hyointestinalis strains. It was concluded that the ability to reversibly express flagella was inherent in the wild-type strains and the transition rates for both directions were consistent for each strain.     

Location of epitopes on Campylobacter jejuni flagella.

Flagella were isolated from strains of Campylobacter jejuni belonging to different heat-labile serogroups and from a strain of Campylobacter fetus, and sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that the flagellin molecular weights (Mr) were approximately 62,000. The flagellins were cleaved by hydrolysis with cyanogen bromide, and sodium dodecyl sulfate-urea peptide gel electrophoresis showed that the C. jejuni flagellins were structurally similar, and differed from C. fetus flagellin. Immunochemical analysis by Western blotting, enzyme-linked immunosorbent assay, immune electron microscopy, and immunoprecipitation with polyclonal and monoclonal antibodies revealed the presence of both internal and surface-exposed epitopes. The internal epitopes were antigenically cross-reactive and linear, and in the case of C. jejuni flagellin were located on cyanogen bromide peptides of apparent Mr 22,400 and 11,000. Antigenically cross-reactive epitopes were also present on an Mr 43,000 cyanogen bromide peptide of C. fetus flagellin. The Mr 22,400 peptide of C. jejuni VC74 flagellin also carried closely positioned internal linear epitopes for two monoclonal antibodies. One epitope was strain specific, while the other was shared by some but not all Campylobacter flagellins. The flagella of C. jejuni VC74 also displayed both surface-exposed antigenically cross-reactive and surface-exposed serospecific epitopes. Both linear and conformational epitopes contributed to the serospecificity of C. jejuni VC74 flagella, and a linear serospecific epitope was located on a cyanogen bromide peptide of apparent Mr 4,000.     

Pneumocystis: not just pneumonia

Once known exclusively as the agents of severe pneumonia in immunocompromised individuals, Pneumocystis spp. are now being associated with asymptomatic carriage in hosts that do not have profound immune debilitation. In the absence of a cultivation system, polymerase chain reaction and histological studies have identified Pneumocystis in neonatal populations, in pregnant women and in other patients that have chronic underlying disease processes. These findings in humans and in experimental animal models indicate the presence of potential reservoirs of infection, and provide insights into the transmission of this fungus. Also, the role of Pneumocystis has been investigated as a possible co-morbidity factor.     

Bacterial and archaeal flagella as prokaryotic motility organelles

The properties and molecular organization of flagella—the bacterial and archaeal motility organelles—are reviewed. The organization of these functional motility elements of prokaryotic organisms belonging to different kingdoms is compared. A mechanism for both in vivo and in vitro assembly of bacterial flagellum filaments (BFFs) is discussed, and similarity is supposed between flagellin and actin with regard to their polymeric forms (BFF and F-actin). Our own data on intracellular fixation of the Halobacterium salinarium flagellum are presented. Comparative characteristics of intracellular fixation of bacterial and archaeal flagella are also described.Translated from Biokhimiya, Vol. 69, No. 11, 2004, pp. 1477–1488.Original Russian Text Copyright © 2004 by Metlina.     

Purification and antigenic analysis of flagella of Campylobacter jejuni

The flagella of Campylobacter jejuni strain FUM158432 were purified and a flagellin preparation consisting of only a single peptide of 63,000 daltons was obtained. The peptide of 92,000 daltons usually associated with a flagellar preparation was shown to be a peptide derived from the hook region. Antiserum was prepared by immunizing a rabbit with the flagellin preparation. The reaction of the antiserum was found to be highly specific for the flagellar filament by immunoelectron microscopy and for flagellin peptide by the immunoblotting method. Seventeen of 23 clinically isolated strains of C. jejuni reacted with this antiserum but the other six strains did not, indicating the existence of antigenic variation of the flagella of C. jejuni. The flagella of a few strains of C. coli also reacted with this antiserum.     

Memory for food caches: not just for retrieval

Many animals use hoarding as a long-term strategy to ensurea food supply at times of shortage. Hoarders employ strategiesthat enhance their ability to relocate caches such as rememberingwhere caches are located. Long-term scatterhoarders, whose cacheshave potentially high pilferage rates, should also hoard ina way to reduce potential cache pilferers' ability to find caches.Previous studies have demonstrated that this could be achievedby hyperdispersing caches to reduce the foraging efficiencyof pilferers. This study investigates whether coal tits (Parusater) indeed place their caches away from existing ones. Inour experiment, birds hoarded food in 3 conditions: when cachesfrom a previous storage session were still present, when cachesfrom a previous storage session were not present anymore becausethe bird had retrieved them, and when caches from a previousstorage session had been removed by the experimenter. We showthat coal tits hoard away from existing caches and that theydo not use cues from extant caches to do this. This evidenceis consistent with the use of memory for the locations of previouscaches when deciding where to place new caches. This findinghas important implications for our understanding of the selectivepressures that have shaped spatial memory in food-hoarding birds.     

hemingway is required for sperm flagella assembly and ciliary motility in Drosophila

Cilia play major functions in physiology and development, and ciliary dysfunctions are responsible for several diseases in humans called ciliopathies. Cilia motility is required for cell and fluid propulsion in organisms. In humans, cilia motility deficiencies lead to primary ciliary dyskinesia, with upper-airways recurrent infections, left–right asymmetry perturbations, and fertility defects. In Drosophila, we identified hemingway (hmw) as a novel component required for motile cilia function. hmw encodes a 604–amino acid protein characterized by a highly conserved coiled-coil domain also found in the human orthologue, KIAA1430. We show that HMW is conserved in species with motile cilia and that, in Drosophila, hmw is expressed in ciliated sensory neurons and spermatozoa. We created hmw-knockout flies and found that they are hearing impaired and male sterile. hmw is implicated in the motility of ciliated auditory sensory neurons and, in the testis, is required for elongation and maintenance of sperm flagella. Because HMW is absent from mature flagella, we propose that HMW is not a structural component of the motile axoneme but is required for proper acquisition of motile properties. This identifies HMW as a novel, evolutionarily conserved component necessary for motile cilium function and flagella assembly.