Central control of upper airway resistance regulating respiratory airflow in mammals

This article reviews recent studies on the importance of glycine receptors for both the spontaneous and the reflex respiratory modulation of the laryngeal abductors and adductors. Our findings show that strychnine blockade of glycine receptors within the brainstem changes the eupneic three-phase respiratory pattern into two phases. This has major implications for glottal control: (i) the inspiratory glottic abduction and early expiratory adduction were both compromised--a finding mimicked by 5% hypoxia; (ii) closure of the glottis during defensive upper airway reflexes became intermittent and the reflex apnoea reversed to sustained inspiratory discharge. Based on these data, we predict that periods of prolonged hypoxia, such as those that occur during sleep apnoeas, will constrain inspiratory glottic abduction thereby impeding inhalation.     

Dynamic confocal imaging in acute brain slices and organotypic slice cultures using a spectral confocal microscope with single photon excitation

Confocal imaging in living brain slices allows the resolution of submicrometre structures of nerve cells, glia and brain vessels. Imaging living brain slices is in many respects different from conventional fixed histological preparations for which confocal microscopes were designed originally. Several problems (i.e. mechanical and thermal drift, and autofluorescence) resulting from the optical and structural properties of brain slices are discussed. Fluorescent indicators may be used to monitor numerous intracellular parameters such as pH and Ca(2+) concentration, but not all of them are equally suitable for this type of work. Genetically engineered fluorescent proteins can be used to visualise the fine dendritic structure of neurones or track particular intracellular structures and proteins. They have also been used to generate indicators for Ca(2+), cAMP and other molecules. While conventional chemical indicators can be either loaded into neurones via patch pipettes or as membrane-permeable esters, protein indicators can be expressed in various types of cells using adenoviral vectors. Adenoviral transgenesis can be performed in vitro in both acute slices and organotypic slice cultures. Organotypic slice cultures give excellent optical access to neurones loaded with either conventional fluorescent indicators or transfected with adenovirus to express fluorescent proteins. They are most suitable for experiments where both conventional and genetically engineered indicators are combined. Single photon imaging in brain slices is limited to the superficial layers (approximately相似文献   

Differential PsaA-, PspA-, PspC-, and PdB-specific immune responses in a mouse model of pneumococcal carriage

Larger numbers of pneumococci were detected in the nasal tract compared to the lung, cervical lymph nodes, and spleen 1, 2, 4, 7, 14, and 21 days after nasal challenge with Streptococcus pneumoniae strain EF3030. In this mouse model of pneumococcal carriage, peripheral S. pneumoniae pneumococcal surface adhesin A (PsaA)-specific humoral responses (immunoglobulin G2a [IgG2a] > IgG1 = IgG2b > IgG3) were significantly higher than pneumococcal surface protein A (PspA)-specific, genetic toxoid derivative of pneumolysin (PdB)-specific, or pneumococcal surface protein C (PspC)-specific serum antibody levels. However, PspA-specific mucosal IgA antibody levels were significantly higher than those against PsaA, PdB, and PspC. In general, both PsaA- and PspA-specific lung-, cervical lymph node-, nasal tract-, and spleen-derived CD4(+) T-cell cytokine (interleukin-4, interleukin-6, granulocyte-macrophage colony-stimulating factor, gamma interferon, and tumor necrosis factor alpha) and proliferative responses were higher than those for either PspC or PdB. Taken together, these findings suggest that PsaA- and PspA-specific mucosal responses as well as systemic humoral and T helper cell cytokine responses are predominantly yet differentially induced during pneumococcal carriage.     

Noninfectious Virus-Like Particle Antigen for Detection of Swine Vesicular Disease Virus Antibodies in Pigs by Enzyme-Linked Immunosorbent Assay

An inactivated SVDV antigen is used in current enzyme-linked immunosorbent assays (ELISAs) for the detection of antibodies to swine vesicular disease virus (SVDV). To develop a noninfectious recombinant alternative, we produced SVDV-like particles (VLPs) morphologically and antigenically resembling authentic SVDV particles by using a dual baculovirus recombinant, which expresses simultaneously the P1 and 3CD protein genes of SVDV under different promoters. Antigenic differences between recombinant VLPs and SVDV particles were not statistically significant in results obtained with a 5B7-ELISA kit, indicating that the VLPs could be used in the place of SVDV antigen in ELISA kits. We developed a blocking ELISA using the VLPs and SVDV-specific neutralizing monoclonal antibody 3H10 (VLP-ELISA) for detection of SVDV serum antibodies in pigs. The VLP-ELISA showed a high specificity of 99.9% when tested with pig sera that are negative for SVDV neutralization (n = 1,041). When tested using sera (n = 186) collected periodically from pigs (n = 19) with experimental infection with each of three different strains of SVDV, the VLP-ELISA detected SVDV serum antibodies as early as 3 days postinfection and continued to detect the antibodies from all infected pigs until termination of the experiments (up to 121 days postinfection). This test performance was similar to that of the gold standard virus neutralization test and indicates that the VLP-ELISA is a highly specific and sensitive method for the detection of SVDV serum antibodies in pigs. This is the first report of the production and diagnostic application of recombinant VLPs of SVDV. Further potential uses of the VLPs are discussed.     

Shiga toxin-producing Escherichia coli isolates from cases of human disease show enhanced adherence to intestinal epithelial (Henle 407) cells.

Shiga toxin-producing Escherichia coli (STEC) strains are a diverse group of organisms which are known to cause diarrhea and hemorrhagic colitis in humans. We have recently described a large food-borne outbreak of STEC disease caused by contaminated semidry fermented sausage (A. W. Paton, R. Ratcliff, R. M. Doyle, J. Seymour-Murray, D. Davos, J. A. Lanser, and J. C. Paton, J. Clin. Microbiol. 34:1622-1627, 1996). STEC strains belonging to several O serotypes were isolated from the contaminated food source, but of these, only a subset were isolated from patients with diarrhea or hemolytic-uremic syndrome (HUS). In the present study, we characterized these STEC isolates with respect to the presence of putative virulence-associated genes and the capacity to adhere to a human intestinal epithelial cell line (Henle 407). The O111:H- STEC strain 95NR1 (isolated from one of the outbreak HUS patients) was shown to adhere to Henle 407 cells in a dose-dependent, mannose-resistant fashion. Microscopic examination revealed a diffuse pattern of adherence for this as well as several other STEC strains. Interestingly, the adherence of STEC strains from HUS cases (both outbreak related and sporadic) was significantly greater than that of STEC strains found in the contaminated food source but not found in any patients. These studies support the hypothesis that an enhanced capacity to adhere to intestinal cells is one of the factors which distinguishes human-virulent STEC strains from those of lesser clinical significance.     

Streptococcus pneumoniae Autolysis Prevents Phagocytosis and Production of Phagocyte-Activating Cytokines

Streptococcus pneumoniae is a major pathogen in humans. The pathogenicity of this organism is related to its many virulence factors, the most important of which is the thick pneumococcal capsule that minimizes phagocytosis. Another virulence-associated trait is the tendency of this bacterium to undergo autolysis in stationary phase through activation of the cell wall-bound amidase LytA, which breaks down peptidoglycan. The exact function of autolysis in pneumococcal pathogenesis is, however, unclear. Here, we show the selective and specific inefficiency of wild-type S. pneumoniae for inducing production of phagocyte-activating cytokines in human peripheral blood mononuclear cells (PBMC). Indeed, clinical pneumococcal strains induced production of 30-fold less tumor necrosis factor (TNF), 15-fold less gamma interferon (IFN-γ), and only negligible amounts of interleukin-12 (IL-12) compared with other closely related Streptococcus species, whereas the levels of induction of IL-6, IL-8, and IL-10 production were similar. If pneumococcal LytA was inactivated by mutation or by culture in a medium containing excess choline, the pneumococci induced production of significantly more TNF, IFN-γ, and IL-12 in PBMC, whereas the production of IL-6, IL-8, and IL-10 was unaffected. Further, adding autolyzed pneumococci to intact bacteria inhibited production of TNF, IFN-γ, and IL-12 in a dose-dependent manner but did not inhibit production of IL-6, IL-8, and IL-10 in response to the intact bacteria. Fragments from autolyzed bacteria inhibited phagocytosis of intact bacteria and reduced the in vitro elimination of pneumococci from human blood. Our results suggest that fragments generated by autolysis of bacteria with reduced viability interfere with phagocyte-mediated elimination of live pneumococci.The pneumococcus Streptococcus pneumoniae is a leading cause of community-acquired pneumonia, meningitis, otitis media, and sinusitis and is a common cause of infection-related mortality in children and elderly people (28, 37).There is a large number of streptococcal species whose taxonomic classification is debated (14, 31). A number of streptococci, including alpha-hemolytic and nonhemolytic variants, constitute the viridans group, which can be further subdivided into the mitis, sanguinis, anginosus, salivarius, and mutans groups based on biochemical tests (14). Phenotypic and genetic tests consistently show that S. pneumoniae is closely related to and may be placed in the mitis subgroup (14, 30). Although the other members of the mitis group can cause sepsis and endocarditis (53), they are considerably less virulent than S. pneumoniae.Pneumococci are considered strictly extracellular pathogens, whose elimination depends on ingestion and killing by phagocytes (i.e., alveolar and tissue-resident macrophages and neutrophils recruited during the inflammatory process). Accordingly, an important determinant of pneumococcal pathogenicity is the thick, hydrophilic polysaccharide capsule, which impedes elimination by phagocytes in the absence of capsule-specific antibodies.The ability of phagocytes to kill microbes is augmented by the phagocyte-activating cytokines gamma interferon (IFN-γ) and tumor necrosis factor (TNF), which boost the bactericidal machinery and enhance killing and digestion of bacteria present within the phagosome (4, 39, 47). TNF is produced by monocytes/macrophages and activated T cells, while IFN-γ is produced by NK cells and T cells in response to interleukin-12 (IL-12) from macrophages. Thus, production of TNF, IFN-γ, and IL-12 is necessary for host defense against intracellular bacteria (8, 11, 21, 34, 48). More recently, these phagocyte-activating cytokines have also been shown to be essential for controlling extracellular gram-positive bacteria, including S. pneumoniae (36, 42, 50, 52, 54). Thus, a patient with an IL-12 deficiency was shown to suffer from recurrent episodes of pneumococcal infection (20). Phagocyte activation by TNF and/or IFN-γ might be required for decomposition of the thick, sturdy peptidoglycan (PG) layer of gram-positive bacteria after phagocytosis, while gram-negative bacteria may be more easily digested. Thus, human leukocytes produce more TNF, IFN-γ, and IL-12 when they are stimulated with gram-positive bacteria than when they are stimulated with gram-negative bacteria (23, 24).A peculiar property of S. pneumoniae is its tendency to undergo autolysis when it reaches the stationary phase of growth. This process is mediated by enzymes called autolysins (ALs), which, when activated, degrade cell wall PG. The major AL is an N-acetyl-muramyl-l-alanine amidase called LytA (27). Other pneumococcal ALs include LytB and LytC, which are believed to be involved mainly in modification of the cell wall during growth and division (16, 17). ALs are anchored to the cell wall via interactions with choline moieties on teichoic acid and lipoteichoic acid (LTA). Choline is necessary for pneumococcal growth, but culture in the presence of high concentrations of choline renders the bacteria incapable of undergoing autolysis (6, 19).Studies with mice have shown that S. pneumoniae with mutated LytA is less virulent than wild-type pneumococci (2, 7, 25). The reason for this is not clear, but two main hypotheses have been put forward. First, autolysis promotes the release of the intracellular toxin pneumolysin (Ply) (5, 33). Ply is an important determinant of virulence (3, 41) and interferes with several defense systems, including inhibition of ciliary beating (15), complement activation (38), and induction of intracellular oxygen radical production (33). Second, cell wall degradation products, such as soluble PG fragments and LTA released upon autolysis, have been suggested to augment the inflammatory response (9, 10, 44, 49).Here we examine a third possibility, that autolysis interferes with the generation of phagocyte-activating cytokines. We have previously shown that intact gram-positive bacteria provide a very efficient stimulus for IL-12 production by human monocytes, regardless of whether they are dead or alive (1, 23, 24), but that decomposed bacteria are inactive in this process and soluble components of the gram-positive cell wall, such as PG and LTA, even downregulate the production of IL-12 in response to intact bacteria in a dose-dependent manner (1). These observations led us to speculate that autolysis may promote virulence by generating bacterial cell wall fragments that block IL-12 production and thereby reduce IFN-γ production and phagocyte activation. Indeed, our data demonstrate that AL-mediated disintegration of pneumococci inhibits production of IFN-γ and also TNF in response to intact bacteria. Further, the presence of autolyzed bacteria reduced elimination of live pneumococci by blood cells in vitro.