Detection of antileukoprotease in connective tissue of the lung

Summary An indirect immunofluorescence technique was applied to frozen sections of central and peripheral human lung tissue to search for extracellular localizations of antileukoprotease (ALP). Two monoclonal anti-ALP antibodies recognizing different epitopes and polyclonal anti-ALP antibodies were used. ALP was found to be localized along elastic fibers in alveolar septa, and also along elastic fibers in the walls of bronchi, bronchioles and blood vessels. Serous cells of bronchial submucosal glands showed labelling as well. In frozen sections of liver and spleen no label was found. Cells and elastic fibers were not labelled when lung tissue sections were processed with polyclonal or monoclonal anti-ALP antibodies, that were blocked with purified ALP before the immunostaining. The association of ALP with elastic fibers of human pulmonary connective tissue is of importance in understanding the role of the inhibitor in the defense of the lung parenchyma against the action of proteolytic enzymes, which is thought to result in emphysema.     

Detection of antileukoprotease in connective tissue of the lung

An indirect immunofluorescence technique was applied to frozen sections of central and peripheral human lung tissue to search for extracellular localizations of antileukoprotease (ALP). Two monoclonal anti-ALP antibodies recognizing different epitopes and polyclonal anti-ALP antibodies were used. ALP was found to be localized along elastic fibers in alveolar septa, and also along elastic fibers in the walls of bronchi, bronchioles and blood vessels. Serous cells of bronchial submucosal glands showed labelling as well. In frozen sections of liver and spleen no label was found. Cells and elastic fibers were not labelled when lung tissue sections were processed with polyclonal or monoclonal anti-ALP antibodies, that were blocked with purified ALP before the immunostaining. The association of ALP with elastic fibers of human pulmonary connective tissue is of importance in understanding the role of the inhibitor in the defense of the lung parenchyma against the action of proteolytic enzymes, which is thought to result in emphysema.     

Loose connective tissue of rat rete testis

Summary Fine structure, postnatal development and reaction to efferent duct ligation of the loose connective tissue of the rat rete testis were studied by light and electron microscopy.The loose connective tissue of adult rats consists of elongate fibroblasts in a homogenous ground substance, together with some Leydig cells, lymphocytes, macrophages and mast cells. During postnatal development this tissue increases in amount, while the interstitial areolar tissue decreases. The looseness of the tissue becomes more evident between days 22 and 27, and may reflect an increase in hydration.Efferent duct ligation for 15 min to five days has no effect on the histological appearance of the tissue.     

Effect of colchicine on the immunohistochemical localization of somatostatin in the rat brain: light and electron microscopic studies.

Somatostatin (SRIF), the hypothalmic hormone which inhibits the secretion of growth hormone by the pituitary, has been localized immunohistochemically in the rat hypothalamus after intracerebral injection of colchicine. The number of cell bodies staining for SRIF was increased in the periventricular nucleus while the number of nerve fibers was decreased in the median eminence after treatment. The number of secretory granules containing SRIF in the nerve cell bodies was increased in the treated animals, suggesting a correlation between the number of specific secretory granules and intensity of the immunohistochemical reaction. These observations are in agreement with the hypothesis that SRIF cell bodies in the periventricular nucleus send their axons into the median eminence.     

Ultrastructural and cytochemical studies on the connective tissue of chaetognaths

The hydroskeleton plays a central role in the architecture of the trunk of the Chaetognath. Its fibrous part is composed by a ‘basement membrane’ which separates the epithelial and nervous level from the locomotory muscle and other tissues which surround the general cavity. This structure corresponds to a dense connective tissue sheath; together with the aqueous phase of the general cavity it constitutes the main part of the hydroskeleton. The axes of the lateral and caudal fins are extensions of this connective tissue; they are rich in ground substance and contain several kinds of fibrils and granules.The ‘basement membrane’ is made of a network of densely packed parallel layers of collagen fibrils which form helices which wrap around the trunk. The collagen fibrils of this connective stratum are sandwiched between two basal lamina; they are embedded in a reduced extracellular matrix whose components are closely related to the architecture of the collagen fibrils. In the core of the fin, the ground substance is very abundant and classical cross-striated collagen fibrils are not to be found. A compact fibrillar transition zone is to be noted between the dense connective stratum surrounding the body and the hyaline axis of the fins. In this zone, no crossbanded collagen fibrils are to be seen.The hydroskeleton and the fins show variations within the phylum. They could be related to speciation, and the ancestral pathway of the phylum. Furthermore these variations are related to the general problem of the evolution of the extracellular matrices and collagen molecule itself.     

Characteristics of mast cells in Chediak-Higashi mice: light and electron microscopic studies of connective tissue and mucosal mast cells

The beige mouse, a homologue of the Chediak-Higashi syndrome in man, possesses abnormally large granules in many tissue cells. The granules in the mucosal mast cells (MMC) of the small intestine of beige and littermate C57BL/6J mice were examined after infecting the mice with the intestinal parasite, Nippostrongylus brasiliensis. MMC in both beige and littermate mice had irregular granules which contained paracrystalline substructures embedded in an amorphous matrix. Granules were not observed in fusion with the cell membrane. Instead, in late-stage mast cells, the granule membrane broke down, the granule contents were spread throughout the cytoplasm, and the cell organelles disintegrated. Unlike connective tissue mast cells, MMC were poorly demonstrated with formalin fixation and toluidine blue staining.     

Eccrine sweat glands of rat fingertips. Scanning electron microscope observations after enzymatic digestion of dermal connective tissue

By removing epidermis with EDTA and a subsequent enzymatic digestion of dermis, eccrine sweat glands of rat fingertips were exposed and examined by scanning electron microscopy (SEM). Different protocols were tested to remove as much connective tissue as possible, while minimizing damage to other structures, and to expose the epithelial surface of secretory tubules in order to display vascular and nervous networks. SEM observations gave detailed information on the relationship between epithelial secretory cells and myoepithelial cells, as well as on the vascular and nervous networks which surround the glomeruli of glands.     

The microfibrils of connective tissue: I. Ultrastructure

The ultrastructure of connective tissue microfibrils was examined in two sites: the ciliary zonule of the eye and the foot pad, in 20-day-old mice perfused with glutaraldehyde. The microfibrils were classified into two categories, referred to as typical and atypical. Typical microfibrils predominate in both sites; they are unbranched, straight or gently curving, tubular structures of indefinite length with an overall diameter of 12.8 +/- 1.7 nm in the zonule and 13.8 +/- 2.8 nm in the foot pad. They are composed of two parts: tubule proper and surface band. The tubule is 7- to 10-nm wide and characterized in cross section by an approximately pentagonal wall and an electron-lucent lumen containing a 1- to 2-nm bead referred to as a spherule. When longitudinal sections of microfibrils are examined at high magnification, the wall of the tubule does not appear as a continuous line but as a series of successive dots. The interpretation of these findings is that the tubule is composed of successive annular segments with an approximately pentagonal outline. The surface band is a 3-nm-wide, ribbon-like structure wrapped around the tubule. The band has dense borders called tracks. Along the tracks, densely stained, 4.6-nm-long "spikes" are attached at 4.0-nm intervals. The wrapping of the bands is somewhat irregular. They may be in a transverse position across single or several microfibrils, in which case each band might constitute a distinct belt; more frequently, the bands are oblique and appear to form a continuous helix. It is proposed that surface bands play a role in holding together the juxtaposed segments making up a tubule. A model has been constructed to represent the association of tubule and band into a typical microfibril. Atypical microfibrils, which are more common in foot pad than in ciliary zonule, appear wavy, lack a definite tubule, and are characterized by distorted, irregular surface bands. They are attributed to proteolysis of typical microfibrils.