The distribution of amyloid P component in normal human cervix

The distribution of amyloid P component in normal human adult cervix was studied using fluorescent immunohistochemical techniques on frozen sections. Amyloid P component is associated with elastic fibres which are particularly concentrated in a sub-epithelial plexus in the ectocervix. This plexus does not extend into the endocervix but terminates at, or just caudal to, the squamocolumnar junction. Amyloid P component was not demonstrated in any of the epithelial basement membranes.     

Amyloid P component in human thyroid

The distribution of amyloid P component in the adult human thyroid was studied by direct immunofluorescence on frozen sections of surgically removed tissue. Amyloid P component shows a striking fibrillary and broken linear distribution in the interfollicular areas. This pattern corresponds to that of reticulin fibres. Amyloid P is also localised to the small amount of elastic tissue in blood vessels but is not demonstrable within cells or in acinar basement membranes.     

Energy stored and dissipated in skeletal muscle basement membranes during sinusoidal oscillations.

We subjected single skeletal muscle cells from frog semitendinosus to sinusoidal oscillations that simulated the strain experienced as the cells near the end of passive extension and begin active contraction in slow swimming. Other cells from which the basement membrane was removed by enzymatic and mechanical procedures were tested identically. Effectiveness of the basement membrane removal technique was evaluated by electron microscopy, by an electrophoretic and lectin-binding assay for depletion of cell surface glycoproteins, and by confirmation by means of electrophoretic and immunologic analyses that major intracellular, cytoskeletal proteins were not disrupted. Measurements of maximum stress, maximum strain, and phase lag between these maxima enabled the complex modulus (dynamic stiffness) and loss tangent (relative viscous losses to elastic energy storage) to be calculated for each mechanically tested preparation. We also calculated the amounts of energy stored and dissipated in each preparation. These calculations indicate that cells with intact basement membranes have complex moduli significantly greater than those of cells without basement membranes, and that cells with basement membrane store significantly more elastic energy than basement membrane depleted cells. However, when subjected to identical sinusoidal strains, energy dissipation in cells with intact basement membranes is over three times greater than dissipation in cells without basement membrane. The relative magnitudes of energy losses to energy storage, called the specific loss, is nearly three times greater for intact cells than for basement membrane depleted cells. Basement membranes may thereby serve as a brake for slowing passive extension of muscle before contraction begins.     

Histochemical characteristics of the basement membranes of the parietal podocytes in the rabbit kidney. A light- and electron-microscopic study

The patterns of silver affinity and following treatment with guanidine were studied in the basement membrane produced by pareital podocytes induced by corticoids in newborn rabbits. The goal of this study was to analyze the role of the different cell types of the renal corpuscle in the determination of the histochemical characteristics of the glomerular basement membrane (GBM). Jones' method shows that while the GBM exhibited silver affinity only after periodic-acid oxidation, the basement membrane of parietal podocytes exhibits the same histochemical characteristics as the normal parietal basement membrane, appearing deep black both after periodic-acid or permanganate oxidation, and after elastase or lysozyme digestions. Since the treatment with guanidine shows that the basement membrane of the parietal podocytes lacks the endothelial component typical of the GBM, it may be suggested that the special resistance to silver impregnation exhibited by the basement membrane after permanganate oxidation or after different enzymatic digestions is due to its endothelial component.     

Phospholipid of the rat glomerular basement membrane in experimental nephrosis

Phospholipids were found to be a constant component of rat glomerular basement-membrane preparations. The concentration fell during preparation of basement membrane by sonication of whole glomeruli, but then remained constant despite continued sonication. The proportions of the individual phospholipids were different from those of whole renal tissue or of isolated glomeruli. The basement-membrane preparations had no (Na(+)+K(+))-activated adenosine triphosphatase activity, an enzyme that is bound to plasma membranes. The concentration of lipid P was decreased on exposure in vivo or in vitro to antiserum against basement membrane; 7 days after injection of antiserum there was a change in the phospholipid composition, with a relative increase in phosphatidylcholine and a decrease in sphingomyelin content. The metabolic turnover rate of the lipid P remaining in the membrane was normal, as determined by (32)P incorporation. The loss of phospholipid was associated with decreases in the relative concentrations of hydroxyproline, hydroxylysine and glycine, and relative increases in proline, lysine, serine, threonine and valine. Administration of aminonucleoside and daunomycin produced proteinuria but did not cause a decrease in lipid P. Anticollagen and anti-lymphocyte sera that attached to the basement membrane but failed to produce proteinuria, also failed to affect the phospholipid content.     

Particular structure of the anterior third of the human true vocal cord.

The histological aspects of the true vocal cord mucosa change in the anterior third compared with the posterior two thirds. The anterior third is characterized by an epithelium where the ridges, marked in the posterior two thirds, are very slight or even absent. The underlying basement membrane, which is thin in the posterior two thirds, here appears particularly thick. At the ultrastructural level in this area, beneath a normally thickened basal lamina, a thick layer of finely granulated electron-dense material, interspersed with thin and randomly scattered collagen fibrils and proteoglycan filaments, is detectable. Beneath this thickened basement membrane, a layer of small undulated collagen fibril bundles with very numerous interspersed oxytalan fibres is found. The collagen fibrils, small in diameter (30-40 nm), seem to continue with the collagen fibrils of the basement membrane. In this layer numerous blood vessels with a very thick, delaminated basement membrane are also observed. The underlying area is characterized by the vocal cord ligament, composed by large compact collagen fibril bundles with interspersed elastic fibres. The particular features of the thick basement membrane, the thick-walled and delaminated vessels and the modular distribution of the elastic system together may well form the basic structure enabling the functional integration of the vocal ligament into the overlying mucosa and the underlying vocal muscle.     

Isolation and characterization of pepsin fragments of laminin from human placental and renal basement membranes.

The presence of laminin in authentic basement membranes was examined at the level of a large pepsin-resistant fragment P1. This strongly antigenic fragment has been recently isolated from a mouse tumour basement membrane. By using antibodies to mouse laminin P1 for identification it was possible to isolate a homologous fragment P1 (Mr about 250 000) and a related component Pa (Mr about 70 000--90 000) from pepsin digests of human placenta and kidney. The fragments were in half-cystine (90--130 residues/1000) and carbohydrate and showed strong binding to concanavalin A. Reduction of disulphide bonds produced several smaller peptide chains, indicating a complex pepsin cleavage. Immunological assays demonstrated partial antigenic identity between laminin fragments obtained from mouse and human tissue, and suggested that fragment Pa may originate from a protein not completely identical with laminin. The results showed that laminin is an abundant component of tissue rich in basement membranes, which has been previously suggested by immunohistological studies.     

The basement-membrane-like matrix of the mouse EHS tumor: III. Immunodetection of the amyloid P component in basotubules

Immunohistochemical methods were applied to the ultrastructural localization of the amyloid P component in the EHS tumor matrix. First, the preembedding approach was used by exposing frozen sections of tumor to antiserum against the mouse amyloid P component followed by the peroxidase-antiperoxidase sequence. Second, using the postembedding approach, Lowicryl K4M sections of the tumor were exposed to antiserum against the amyloid P component and subjected to the protein A-gold procedure. In both cases, the immunostaining was restricted to structures which appeared in longitudinal section as fairly straight rods and in cross section as 7- to 10-nm pentagonal or roughly circular profiles outlining a lumen with a central dot. Since these features are characteristic of basotubules, it is concluded that the basotubules of the tumor matrix possess the antigenicity of the amyloid P component and presumably contain this substance itself. Similar experiments carried out on the thick basement membrane known as Reichert's membrane demonstrated that its basotubules also possessed amyloid P-component antigenicity. It is likely, therefore, that the amyloid P component is a constituent of basotubules.     

Low abundance of sweat duct Cl- channel CFTR in both healthy and cystic fibrosis athletes with exceptionally salty sweat during exercise

To understand potential mechanisms explaining interindividual variability observed in human sweat sodium concentration ([Na(+)]), we investigated the relationship among [Na(+)] of thermoregulatory sweat, plasma membrane expression of Na(+) and Cl(-) transport proteins in biopsied human eccrine sweat ducts, and basal levels of vasopressin (AVP) and aldosterone. Lower ductal luminal membrane expression of the Cl(-) channel cystic fibrosis transmembrane conductance regulator (CFTR) was observed in immunofluorescent staining of sweat glands from healthy young adults identified as exceptionally "salty sweaters" (SS) (n = 6, P < 0.05) and from patients with cystic fibrosis (CF) (n = 6, P < 0.005) compared with ducts from healthy young adults with "typical" sweat [Na(+)] (control, n = 6). Genetic testing of healthy subjects did not reveal any heterozygotes ("carriers") for any of the 39 most common disease-causing CFTR mutations in the United States. SS had higher baseline plasma [AVP] compared with control (P = 0.029). Immunostaining to investigate a potential relationship between higher plasma [AVP] (and sweat [Na(+)]) and ductal membrane aquaporin-5 revealed for all groups a relatively sparse and location-dependent ductal expression of the water channel with localization primarily to the secretory coil. Availability of CFTR for NaCl transport across the ductal membrane appears related to the significant physiological variability observed in sweat salt concentration in apparently healthy humans. At present, a heritable link between healthy salty sweaters and the most prevalent disease-causing CFTR mutations cannot be established.     

Effects of inhibition of proteoglycan synthesis on the differentiation of cultured rat Schwann cells

Schwann cells synthesize two heparan sulfate proteoglycans, one that is a component of the Schwann cell basement membrane and a smaller one that is an integral component of the Schwann cell plasma membrane. To determine the functions of these molecules, Schwann cell-nerve cell cultures were grown in medium containing a specific inhibitor of proteoglycan biosynthesis, 4-methylumbelliferyl-beta-D-xyloside. Treatment with 1 mM beta-D-xyloside caused a 90% reduction in the accumulation of 35SO4-labeled proteoglycans in the cell layer of the cultures. Gel filtration analysis revealed that both the basement membrane and plasma membrane proteoglycans were affected. Inhibition of proteoglycan biosynthesis was accompanied by an inhibition of laminin deposition into extracellular matrix as determined by immunostaining of cultures and by immunoblotting of cell-associated proteins. This occurred even though there was no decrease in the amount of laminin detected in the medium of beta-D-xyloside-treated cultures. Deposition of collagen type IV was similarly affected. In addition, there was no myelin produced in beta-D-xyloside treated cultures. However, when beta-xyloside-treated cultures were supplied with exogenous basement membrane, Schwann cells produced numerous myelin segments. These results indicate that Schwann cell proteoglycans play an essential role in basement membrane assembly, and that the integral plasma membrane proteoglycan is not required for the basement membrane to exert its effects on Schwann cell differentiation.     

The connective tissue of the rat lung: electron immunohistochemical studies

The ultrastructural distribution of specific connective-tissue components in the normal rat lung was studied by electron immunohistochemistry. Three of these components were localized: type I collagen, fibronectin and laminin. Type I collagen was present not only in major airways and vascular structures, but also in alveolar septa. Laminin was found in all basement membranes, and only in basement membranes, demonstrating once more that this glycoprotein is an intrinsic component of the basement membrane. Fibronectin was found free in the interstitium and on the surfaces of collagen fibers. The basement membranes of bronchial, glandular and endothelial cells of large vessels lacked fibronectin; however, capillary endothelial and occasionally epithelial alveolar basement membranes contained some fibronectin in an irregular, spotty distribution. This localization suggests that in the lung, as in other tissues, fibronectin is not an intrinsic component of the basement membrane, but rather a stromal and plasma protein. Only basement membranes in the alveolar parenchyma contained "trapped" plasma fibronectin.     

Goodpasture antigen-binding protein/ceramide transporter binds to human serum amyloid P-component and is present in brain amyloid plaques

Serum amyloid P component (SAP) is a non-fibrillar glycoprotein belonging to the pentraxin family of the innate immune system. SAP is present in plasma, basement membranes, and amyloid deposits. This study demonstrates, for the first time, that the Goodpasture antigen-binding protein (GPBP) binds to human SAP. GPBP is a nonconventional Ser/Thr kinase for basement membrane type IV collagen. Also GPBP is found in plasma and in the extracellular matrix. In the present study, we demonstrate that GPBP specifically binds SAP in its physiological conformations, pentamers and decamers. The START domain in GPBP is important for this interaction. SAP and GPBP form complexes in blood and partly colocalize in amyloid plaques from Alzheimer disease patients. These data suggest the existence of complexes of SAP and GPBP under physiological and pathological conditions. These complexes are important for understanding basement membrane, blood physiology, and plaque formation in Alzheimer disease.     

Identification of beta and gamma subunits of laminins localized in the basement membrane of rat circumvallate papillae

Taste bud cells have elongated shape and are anchored to the basement membrane. Here we analyzed the subunits of laminin, a major component of the basement membrane, in circumvallate papillae of rat tongue. Two beta subunits, beta1 and beta2, were detected by RT-PCR, of which the beta2 subunit was immunohistochemically identified as a major component of the basement membrane. The gamma1 subunit was also immunohistochemically identified as a major component. Profiles of these two laminin subunits were nearly the same as that obtained by an anti-laminin antibody, indicating that laminins of the basement membrane in the papillae contain beta2 and gamma1 as major beta and gamma subunits, respectively. As potential receptors for these laminin ligands, integrin subunits were analyzed by RT-PCR. Three integrin beta subunit species, beta1, beta4, and beta5, were shown to be expressed in the epithelium of the circumvallate papillae by RT-PCR among the five species examined.     

The ultrastructural composition of basement membranes in vivo

The ultrastructure of basement membranes has a homogeneous appearance. The enormous cell biological importance of basement membranes and their components for cell proliferation, migration and differentiation implies that their composition is more complex than their structure suggests. To elucidate the molecular composition of basement membranes in vivo, we optimised immunogold histochemistry to allow the determination of the molecular arrangement of matrix molecules. Basically, we apply a mild fixation and embed the tissues in the hydrophilic LR-Gold. This preserves the basement membrane with a quality similar to freeze substitution. The application of two antibodies directed toward the C- and N-terminal ends of a molecule and coupled to gold particles of different sizes allows determination of the orientation of a molecule within the basement membrane. We were able to demonstrate that the molecular orientation of the laminin-1 molecule changes in the basement membrane according to cell biological needs. We also showed that ultrastructurally identical basement membranes like the ones of the proximal and distal tubules of the kidney have a differing molecular arrangement. Integrin alpha7 influences the molecular composition of the basement membranes at the myotendinous junction. With the help of double labelling at the ultrastructural level we could show that nidogen-1 is co-localised with laminin-1 and only found in fully developed, mature basement membranes. In general, laminin-1, nidogen-1 and collagen type IV are localised over the entire width of basement membranes, with laminin-1 and nidogen-1 co-localised, in accordance with the current basement membrane models. Incidentally, our investigations warn us, that not every matrix protein found at the light microscopic level as a linear staining pattern underneath an epithelium (basement membrane zone) is a real basement membrane component when investigated at the ultrastructural level. Instead, one and the same molecule, e.g. endostatin, can be a basement membrane component in one organ and a matrix molecule in another.     

基底膜和肿瘤转移

基底膜是一种特化的细胞外基质,是肿瘤转移过程中必须穿越的物理屏障。基底膜的组成成分通过和细胞表面受体整合素相互作用,在调节肿瘤转移的过程中发挥了重要作用。另一方面,肿瘤细胞通过分泌基质降解酶类破坏基底膜的组织结构,同时调节细胞外基质受体整合素的表达,为穿过：基底膜和在靶器官粘附、增殖创造有利条件。了解细胞和基底膜的相互作用可以为抗转移药物的研发提供新的策略。     

Tenascin/hexabrachion in human skin: biochemical identification and localization by light and electron microscopy

Tenascin/hexabrachion is a large glycoprotein of the extracellular matrix. Previous reports have demonstrated that tenascin is associated with epithelial-mesenchymal interfaces during embryogenesis and is prominent in the matrix of many tumors. However, the distribution of tenascin is more restricted in adult tissues. We have found tenascin to be present in normal human skin in a distribution distinct from other matrix proteins. Immunohistochemical studies showed staining of the papillary dermis immediately beneath the basal lamina. Examination of skin that had been split within the lamina lucida of the basement membrane suggested a localization of tenascin beneath the lamina lucida. In addition, there was finely localized staining within the walls of blood vessels and in the smooth muscle bundles of the arrectori pilorem. Very prominent staining was seen around the cuboidal cells that formed the basal layer of sweat gland ducts. The sweat glands themselves did not stain. The distribution of tenascin in the papillary dermis was studied at high resolution by immunoelectron microscopy. Staining was concentrated in small amorphous patches scattered amongst the collagen fibers beneath the basal lamina. These patches were not associated with cell structures, collagen, or elastic fibers. Tenascin could be partially extracted from the papillary dermis by urea, guanidine hydrochloride, or high pH solution. The extracted protein showed a 320-kD subunit similar to that purified from fibroblast or glioma cell cultures. We have developed a sensitive ELISA assay that can quantitate tenascin at concentrations as low as 5 ng/ml. Tests on extracts of the papillary dermis showed tenascin constituted about 0.02-0.05% of the protein extracted.     

Interleukin-1β and tumor necrosis factor-α have opposite effects on fibroblasts and epithelial cells during basement membrane formation

Interleukin-1beta (IL-1beta) and tumor necrosis factor-alpha (TNF-alpha) are typical proinflammatory cytokines that influence various cellular functions, including metabolism of the extracellular matrix. We examined the roles of IL-1beta and TNF-alpha in basement membrane formation in an in vitro model of alveolar epithelial tissue composed of alveolar epithelial cells and pulmonary fibroblasts. Formation of the basement membrane by immortalized rat alveolar type II epithelial (SV40-T2) cells, which ordinarily do not form a continuous basement membrane, was dose-dependently upregulated in the presence of 2 ng/ml IL-1beta or 5 ng/ml TNF-alpha. IL-1beta or TNF-alpha alone induced increased secretion of type IV collagen, laminin-1, and nidogen-1/entactin, all of which contributed to this upregulation. In contrast, while SV40-T2 cells cultured with a fibroblasts-embedded type I collagen gel were able to form a continuous basement membrane, they failed to form a continuous basement membrane in the presence of IL-1beta or TNF-alpha. Fibroblasts treated with IL-1beta or TNF-alpha secreted matrix metalloproteinase (MMP)-9 and MMP-2, and these MMPs inhibited basement membrane formation and degraded the basement membrane architecture. Neither IL-1beta- nor TNF-alpha-treated SV40-T2 cells increased the secretion of MMP-9 and MMP-2. These results suggest that IL-1beta participates in basement membrane formation in two ways. One is the induction of MMP-2 and MMP-9 secretion by fibroblasts, which inhibits basement membrane formation, and the other is induction of basement membrane component secretion from alveolar epithelial cells to enhance basement membrane formation.     

Cathepsin D and other hydrolases in the kidney of streptozotocin-diabetic mice. Possible relevance to microangiopathy

The lysosomal enzymes cathepsin D (E.C. 3.4.23.5), alpha-glucosidase (E.C. 3.2.1.20) and beta-galactosidase (E.C. 3.2.1.23), potentially involved in the breakdown of the peptide component and the disaccharide units of basement membrane glycoproteins, were studied in the kidney cortex and liver of streptozotocin-diabetic mice. In the liver of diabetic mice, as compared to controls, an increase was found for the total activity (measured in frozen-thawed homogenates) of cathepsin D (+135%, P less than 0.01) and beta-galactosidase (+32%, P less than 0.05). In the kidney a decrease was observed for both the free activity (measured in 12,000 g supernatant) and the total activity of these two enzymes (cathepsin D: -62% and -24%; beta-galactosidase: -29% and -23%; P less than 0.05 in all instances). Alpha-glucosidase did not show significant changes in either tissues. Total protein content of the two organs did not change significantly with diabetes and therefore cannot account for the enzyme alterations observed. These data indicate that the response of kidney to diabetes is opposite to that of liver (decrease versus increase in catabolic enzymes), and suggest decreased degradation of basement membrane in some tissues in diabetes, which may contribute to the thickening of basement membrane and therefore to the development of microangiopathy.     

Localization of perlecan and heparanase in Hertwig's epithelial root sheath during root formation in mouse molars.

During cementogenesis, dental follicular cells penetrate the ruptured Hertwig's epithelial root sheath (HERS) and differentiate into cementoblasts. Mechanisms involved in basement membrane degradation during this process have not been clarified. Perlecan, a heparan sulfate (HS) proteoglycan, is a component of all basement membranes. Degradation of HS of perlecan by heparanase cleavage affects a variety of biological processes. We elucidated immunolocalization of perlecan and heparanase in developing murine molars to clarify their roles in cementoblast differentiation. At the initial stage of root formation, perlecan immunoreactivity was detected on the basement membrane of HERS. Weak heparanase immunoreactivity was detected in HERS cells. HERS showed intense staining for heparanase as root formation progressed. In contrast, labeling for perlecan disappeared from the basement membrane facing the dental follicle, and weak immunoreactivity for perlecan was detected on the inner side of the basement membrane of HERS. These findings suggest that perlecan removal is an important step for root and periodontal tissue formation. Heparanase secreted by the cells of HERS may contribute to root formation by degrading perlecan in the dental basement membrane.     

The extracellular matrix protein WARP is a novel component of a distinct subset of basement membranes.

WARP is a recently described member of the von Willebrand factor A domain superfamily of extracellular matrix proteins, and is encoded by the Vwa1 gene. We have previously shown that WARP is a multimeric component of the chondrocyte pericellular matrix in articular cartilage and intervertebral disc, where it interacts with the basement membrane heparan sulfate proteoglycan perlecan. However, the tissue-specific expression of WARP in non-cartilaginous tissues and its localization in the extracellular matrix of other perlecan-containing tissues have not been analyzed in detail. To visualize WARP-expressing cells, we generated a reporter gene knock-in mouse by targeted replacement of the Vwa1 gene with beta-galactosidase. Analysis of reporter gene expression and WARP protein localization by immunostaining demonstrates that WARP is a component of a limited number of distinct basement membranes. WARP is expressed in the vasculature of neural tissues and in basement membrane structures of the peripheral nervous system. Furthermore, WARP is also expressed in the apical ectodermal ridge of developing limb buds, and in skeletal and cardiac muscle. These findings are the first evidence for WARP expression in non-cartilaginous tissues, and the identification of WARP as a component of a limited range of specialized basement membranes provides further evidence for the heterogeneous composition of basement membranes between different tissues.