Uncoordinated production of Laminin-5 chains in airways epithelium of allergic asthmatics.

BACKGROUND: Laminins are a group of proteins largely responsible for the anchorage of cells to basement membranes. We hypothesized that altered Laminin chain production in the bronchial mucosa might explain the phenomenon of epithelial cell shedding in asthma. The aim was to characterize the presence of Laminin chains in the SEBM and epithelium in allergic and non-allergic asthmatics. PATIENTS AND METHODS: Biopsies were taken from the bronchi of 11 patients with allergic and 9 patients with non-allergic asthma and from 7 controls and stained with antibodies against the Laminin (ln) chains alpha1-alpha5, beta1-beta2 and gamma1-gamma2. RESULTS: Lns-2,-5 and -10 were the main Laminins of SEBM. The layer of ln-10 was thicker in the two asthmatic groups while an increased thickness of lns-2 and -5 was only seen in allergic asthmatics. The ln gamma2-chain, which is only found in ln 5, was exclusively expressed in epithelial cells in association with epithelial injury and in the columnar epithelium of allergic asthmatics. CONCLUSION: The uncoordinated production of chains of ln-5 in allergic asthma could have a bearing on the poor epithelial cell anchorage in these patients.

Method for localization of sialic acid on cell surface and cell interior in peripheral blood: a pilot study.

This article presents a method for identification and localization of cell surface and intracellular sialoglycoconjugates of peripheral blood cells. To reveal cell surface conjugates, a sample of peripheral blood was incubated with lectin after centrifugation and rinsing. For intracellular localization in leukocytes, RBCs were lysed and the membranes were permeabilized prior to cytochemical reaction. Fluorescein isothiocyanate conjugated lectins were used for visualization in fluorescence microscope. All lectins bound specifically to the surface of erythrocytes. Confocal microscopy showed surface and intracellular labeling of permeabilized leukocytes. A part of the signal in eosinophils originated from binding of anionic fluorophore to cationic granular proteins.

A new technique for multiparameter imaging microscopy: use of long decay time photoluminescent labels enables multiple color immunocytochemistry with low channel-to-channel crosstalk.

In this report, we describe luminescence imaging microscopy using five different photoluminescent dyes in a single specimen. We combined the long decay time luminophores, europium(III) chelate, terbium(III) chelate, palladium(II) coproporphyrin, and platinum(II) coproporphyrin, with a green nuclear stain, Syto 25 trade mark, that emits conventional fast decaying fluorescence. The luminescence emissions from the five different luminophores were separated from each other by the differences in spectra and decay times using time-resolved detection. Applicability of this dye-combination for multiparameter analysis of a biological object was verified in a mixed population of peripheral blood leukocytes. Leukocyte cytocentrifugates were incubated in one step with a cocktail of luminophore-conjugated antibodies recognizing neutrophil- and lymphocyte-specific markers, followed by rapid staining with a mixture of nuclear stain and Pt-porphyrin as an eosinophil stain. The results show that multiple luminescent dyes with long decay time can be used together, and in combination with a conventional fluorophore. The separation of the signals of the long decay time labels was distinctive and enabled reliable identification of different leukocyte types, as well as an automated cell count. The long decay time luminophores together with time-resolved luminescence imaging microscopy (TR-LIM) provide a unique tool for studies of simultaneous expression of multiple antigens at the level of a single cell. In comparison with other multiparameter imaging techniques, the described technique offers increased accuracy of results, simplification of preparation procedure, and dramatic shortening of the total processing time. To our knowledge, this is the first time that simultaneous fivefold labeling/staining and analysis in a single specimen has been performed in the field of immunocytochemistry.

Phosphorescent metalloporphyrins as labels in time-resolved luminescence microscopy: effect of mounting on emission intensity.

In this study, we present an investigation of the effects of mounting media on the phosphorescence of metalloporphyrin stained microscopy samples. The samples were: (1) Platinum(II) coproporphyrin (=PtCP) stained porous Sephadex beads; (2) compact polystyrene microspheres coated with IgG-PtCP conjugate; and (3) immunocytochemically labeled human peripheral blood neutrophils. The human neutrophils in a mixed leukocyte population were fixed, permeabilized, and then immunolabeled with PtCP conjugate of monoclonal mouse IgG directed to the intracellular antigen myeloperoxidase. The samples were mounted in twelve different mounting media and studied with quantitative time-resolved luminescence imaging microscopy with respect to the intensity and stability of the phosphorescence signal. The results indicate that microscopy samples stained with PtCP exhibit the brightest phosphorescence emission in non-mounted form or when mounted in non-aqueous permanent mounting media.