A comparison of anionic sites in the glomerular basement membranes from different classes of fishes

Summary Cationized ferritin was injected into the circulatory system of teleosts, the sea raven and Atlantic eelpout, and into elasmobranchs, the spiny dogfish and the skate, to determine if the glomerular basement membranes (GBM) from these different groups of fishes possess anionic binding sites similar to those present in the GBM of mammals. The distribution of cationized ferritin was the same in all fishes listed. Cationized ferritin was localized only in the GBM and the mesangial matrix. The regular distribution of cationized ferritin within the laminae rarae (60 nm intervals) was taken as evidence of the presence of anionic binding sites. Cationized ferritin did not bind to the glomerular capillary endothelium, nor was any of it localized at the base of the slit diaphragms of the foot processes of the podocytes. The distribution of binding sites in the GBM of these fishes is similar to that in another teleost, the winter flounder, and in a cyclostome, the hagfish.     

Ultramicroscopic localization of cationized antigen in the glomerular basement membrane in the course of active, in situ immune complex glomerulonephritis

The sequence of antigen localization and the interaction of immune deposits with the anionic sites of the glomerular basement membrane (GBM) were investigated in an active model of in situ immune complex glomerulonephritis using a cationized ferritin. Three weeks after immunization with native horse spleen ferritin, the left kidneys of rats were perfused with 500 micrograms of cationized ferritin through the left renal artery. One h after renal perfusion, most of ferritin particles localized subendothelially, corresponding to the anionic sites of the lamina rara interna. In the glomerular capillary loops, infiltrating polymorphonuclear leukocytes and monocytes were seen. Some of these monocytes were in direct contact with immune complexes containing ferritin aggregates associated with anionic sites of the lamina rara interna. At 24 h, numerous ferritin aggregates were present subepithelially, preferentially beneath the slit membrane. The subepithelial location of ferritin did not always correspond to the anionic sites of the lamina rara externa. From days 3 to 7, there was remarkable endocapillary cell proliferation in some loops and pronounced effacement of epithelial foot processes. Focal detachment of epithelium from the GBM was observed occasionally. From days 14 to 28, most of ferritin aggregates were located intramembranously and subepithelially. Membranous transformation has already begun around the subepithelial deposits. This morphological study provides insight into the fate of immune deposits and injury to the GBM in the glomerulonephritis.     

Assembly of the glomerular filtration surface. Differentiation of anionic sites in glomerular capillaries of newborn rat kidney

Glomerular development was studied in the newborn rat kidney by electron microscopy and cytochemistry. Glomerular structure at different developmental stages was related to the permeability properties of its components and to the differentiation of anionic sites in the glomerular basement membrane (GBM) and on endothelial and epithelia cell surfaces. Cationic probes (cationized ferritin, ruthenium red, colloidal iron) were used to determine the time of appearance and distribution of anionic sites, and digestion with specific enzymes (neuraminidase, heparinase, chondroitinases, hyaluronidases) was used to determine their nature. Native (anionic) ferritin was used to investigate glomerular permeability. The main findings were: (a) The first endothelial fenestrae (which appear before the GBM is fully assembled) possess transient, negatively charged diaphragms that bind cationized ferritin and are impermeable to native ferritin. (b). Two types of glycosaminoglycan particles can be identified by staining with ruthenium red. Large (30-nm) granules are seen only in the cleft of the S-shaped body at the time of mesenchymal migration into the renal vesicle. They consist of hyaluronic acid and possibly also chondroitin sulfate. Smaller (10-15-nm) particles are seen in the earliest endothelial and epithelial basement membranes (S-shaped body stage), become concentrated in the laminae rarae after fusion of these two membranes to form the GBM, and contain heparan sulfate. They are assumed to be precursors of the heparan sulfate-rich granules present in the mature GBM. (c) Distinctive sialic acid-rich, and sialic acid-poor plasmalemmal domains have been delineated on both the epithelial and endothelial cell surfaces. (d) The appearance of sialoglycoproteins on the epithelial cell surface concides with the development of foot processes and filtration slits. (e) Initially the GBM is loosely organized and quite permeable to native ferritin ;it becomes increasinly impermeable to ferritin as the lamina densa becomes more compact. (f) The number of endothelial fenestrae and open epithelial slits increases as the GBM matures and becomes organized into an effective barrier to the passage of native ferritin.     

Preservation of fixed anionic sites in the GBM in the acute proteinuric phase of cationic antigen mediated in-situ immune complex glomerulonephritis in the rat

Cationic antigens have been observed to bind with the negatively charged glomerular basement membrane (GBM). Using the cationic reagent polyethyleneimine (PEI), the distribution of glomerular anionic sites was evaluated ultrastructurally in the early stage (2 h-day 7) of cationic antigen mediated in-situ immune complex formation type glomerulonephritis (GN) in the rat. Renal perfusion via the renal artery with 100 micrograms of cationized human IgG(pI greater than 9.5), followed by the i.v. injection of specific antibodies, led to an initial increase in urinary albumin excretion, subsequent massive globulinuria and the formation of numerous subepithelial deposits on day 7. The most striking alteration in glomerular anionic sites was observed on the epithelial cell surface coat; the PEI deposition on the epithelial cell surface was almost identical to that in control glomeruli at 2 and 4 h after the induction of GN; thereafter, on day 7, a broad loss of anionic sites was observed on flattened epithelial foot processes. In contrast, fixed anionic sites of the laminae rarae of the GBM showed no apparent alterations in the distribution and number from 2 h to day 7 and did not disappear even in the lamina rara externa adjacent to subepithelial deposits. These findings not only show that fixed anionic sites of the GBM, in contrast to the rapid decrease in those of the epithelial cell surface, are not completely neutralized or destroyed even in GN, in which cationic antigen participates in the in-situ formation of GBM-deposits.(ABSTRACT TRUNCATED AT 250 WORDS)     

Freeze-fracture cytochemistry of rat glomerular capillary tuft. Determination of wheat germ agglutinin binding sites and localization of anionic charges

We propose here the use of freeze-fracture to gain access and to label in vitro glomerular components and locate WGA receptors and anionic sites. Tissues are frozen, fractured under liquid nitrogen, and thawed. Freeze-fracture rendered all glomerular structures directly accessible to the reagents. This made possible study of the nature and topology of cationized ferritin and WGA binding sites. WGA-gold complexes were observed over plasma membranes of podocytes and of endothelial and mesangial cells. Labeling of podocytes and endothelial cells was similar in the mesangial area and in the peripheral part of the capillary loop. Cross-fractures of extracellular matrices showed that WGA bound uniformly to the glomerular basement membrane (GBM) as well as to mesangial matrix. In fractured specimens treated with neuraminidase, WGA was no longer observed over podocytes but it consistently labeled the surface of endothelial and mesangial cells. Whereas in GBM cross-sections WGA binding was greatly reduced or even abolished, it remained unmodified in the mesangium. This shows that only NeuNAc (sialic acid) might account for the binding of WGA to podocytes, whereas GlcNAcs appear to be the main WGA binding sites on endothelial and mesangial cells and in the mesangial matrix. Both NeuNAc and GLcNAc residues are probably associated in GBM. With cationized ferritin (pI 8.3) at pH 7.4, intense, continuous labeling was seen all over the different plasma membranes, denser in podocytes than in endothelial cells. CF was also observed in cross-fractured profiles of extracellular matrices and never appeared agglutinated in discrete sites.     

The anionic barrier system in the mesonephric renal glomerulus of the arctic lamprey,Entosphenus japonicus (Martens) (Cyclostomata)

Summary To examine the selective permeability of the nephrons of lower vertebrates, the permeability of the glomerulus in the kidney of an arctic lamprey, Entosphenus japonicus (Martens), to native anionic ferritin or cationized ferritin was studied by observing the distribution of ionized anionic groups in renal tissues. The cationized ferritin molecules injected into the dorsal aorta penetrated rapidly into the glomerular basement membrane layer through fenestrae present in the capillary endothelium and were subsequently excreted into the urinary spaces via the interstices between foot processes of the visceral epithelial cells. Native anionic ferritin, on the other hand, passed only minimally through the capillary wall. Cytochemical staining of fixed tissue or perfusion of the kidney in situ with cationic cacodylate-iron colloid revealed that the ionized anionic groups of acid mucopolysaccharides were distributed on both the luminal and abluminal surfaces of endothelial cells, and in the thick fibrous lamina rara interna of the glomerular basement membrane; they were especially dense on the surfaces of visceral epithelial cells and their foot processes. These results suggest that the mesonephric glomerulus of the arctic lamprey possesses a functionally well developed anionic barrier system comparable to that of the mammalian metanephric glomerulus.     

Glomerular extracellular matrices and anionic sites in aging ddY mice: a morphometric study

A morphometric study was undertaken to examine age-related changes in glomerular ultrastructure and anionic sites in ddY male mice at various ages. A progressive increase in glomerular extracellular matrices, including thickening of the glomerular basement membrane (GBM), formation of GBM nodules, and mesangial matrix increase, was found to be the primary age-related ultrastructural change in aging mice; there were also electron-dense deposits in mesangial and subepithelial regions. The extent of GBM thickening in mice was less than was reported in rats. Rather, the GBM nodules, which had the same electron density as the lamina densa (LD) and protruded on the subepithelial side of the GBM, were more striking. Quantitative evaluation showed that GBM thickness, number and size of GBM nodules, and the area of the mesangial matrix were significantly correlated with the age of the mice. The distribution of anionic sites in the glomeruli of aging animals was described for the first time. No statistically significant differences were noted between the number of glomerular anionic sites in the different age groups. These results indicate that the increase in glomerular extracellular matrices reported in aged rats was also present in aged mice, although the extent of various changes was different. The results also indicate that this increase in glomerular extracellular matrices with age was not accompanied by significant alteration in glomerular anionic sites.     

Redistribution of surface anionic sites on the luminal front of blood vessel endothelium after interaction with polycationic ligand

The ability of anionic groups on the luminal surface of blood vessels to redistribute by lateral migration under the influence of multivalent ligands was analyzed by electron microscopy, using cationized ferritin (CF). In vitro interaction of blood vessel segments with CF results in rapid aggregation of most anionic sites on the luminal fromt of the endothelium, followed by internalization or detachment of the CF patches, leaving most of the luminal surface devoid of anionic sites. Further incubation of such endothelial cells without CF results in regeneration of binding capacity for the polycationic label. Transport of CF, but not of native ferritin, across the endothelium by vesicle transport, followed by exocytosis of the interiorized CF clusters on the tissue front of the endothelium, was also observed. The possibility that such activities in the blood vessels in vivo may be associated with local changes in the normal distribution of the surface anionic sites as well as in accumulation of debris in the subendothelial layers of the vessels is suggested.     

Electron microscopic histochemical and immunochemical analyses of heparan sulfate proteoglycan distribution in renal glomerular basement membranes.

Renal glomerular basement membranes (GBMs) exhibit a charge-selective barrier, comprised of anionic sites, that restrict the passage of anionic molecules into the urine. These sites are located primarily in the laminae rarae interna (LRI) and externa (LRE) of the GBM and consist of heparan sulfate proteoglycan (HSPG). Previous efforts to localize HSPG core protein within various layers of the GBM have been contradictory. In the present study when rat renal cortex blocks were treated by immersion with the cationic probe, polyethyleneimine (PEI), GBMs exhibited anionic sites concentrated primarily in the LRE and more irregularly within the LRI and lamina densa. All sites were heparitinase sensitive indicating that PEI positive sites represent negatively charged groups associated with heparan sulfate. In order to gain information on the distribution of the HSPG protein core, antibodies to HSPG from the EHS tumor matrix [anti-(EHS) HSPG] and GBMs [anti-(GBM) HSPG] were used together with immunogold to label thin sections of Lowicryl embedded kidney cortex. Depending upon the antisera used, markedly different distributions of HSPG were obtained. Immunolabelling with anti-(GBM) HSPG suggested a distribution of HSPG which was restricted to the laminae rarae, whereas labelling with anti-(EHS) HSPG indicated that the protein core penetrates through all layers of the GBM.     

Integrin beta1-mediated matrix assembly and signaling are critical for the normal development and function of the kidney glomerulus

The human kidneys filter 180 l of blood every day via about 2.5 million glomeruli. The three layers of the glomerular filtration apparatus consist of fenestrated endothelium, specialized extracellular matrix known as the glomerular basement membrane (GBM) and the podocyte foot processes with their modified adherens junctions known as the slit diaphragm (SD). In this study we explored the contribution of podocyte β1 integrin signaling for normal glomerular function. Mice with podocyte specific deletion of integrin β1 (podocin-Cre β1-fl/fl mice) are born normal but cannot complete postnatal renal development. They exhibit detectable proteinuria on day 1 and die within a week. The kidneys of podocin-Cre β1-fl/fl mice exhibit normal glomerular endothelium but show severe GBM defects with multilaminations and splitting including podocyte foot process effacement. The integrin linked kinase (ILK) is a downstream mediator of integrin β1 activity in epithelial cells. To further explore whether integrin β1-mediated signaling facilitates proper glomerular filtration, we generated mice deficient of ILK in the podocytes (podocin-Cre ILK-fl/fl mice). These mice develop normally but exhibit postnatal proteinuria at birth and die within 15 weeks of age due to renal failure. Collectively, our studies demonstrate that podocyte β1 integrin and ILK signaling is critical for postnatal development and function of the glomerular filtration apparatus.     

Localization and distribution of anionic charges in the glomerular mesangium of normal and nephrotic rats

Sulfated glycosaminoglycans and sialoglycoproteins are thought to play a pivotal role in the glomerular capillary wall barrier to filtration since these anionic charged elements are important in the maintenance of capillary wall integrity and constitute a charge-selective filter. The development of proteinuria in puromycin aminonucleoside (PAN) nephrosis is associated with polyanion loss from the glomerular capillary wall structures. Since in PAN nephrosis the permeability of the mesangial area to plasma proteins and tracer substances has also been shown to be increased, the purpose of this study was to analyse the localization and distribution of anionic charges in the glomerular mesangium in this experimental model. Glycosaminoglycans were labeled by perfusion of the kidneys with ruthenium red solution (RR). Electron microscopic examination revealed the presence of distinct small RR granules ("anionic sites") in the mesangial intercellular matrix substance and in the laminae rarae of the glomerular basement membrane (GBM). The center-to-center spacing of the granules was measured and a frequency distribution of intervals in different interval classes was constructed. In normal glomeruli the anionic sites in the mesangial matrix showed a distribution pattern identical to the GBM with a maximal interval incidence at the 31-40 nm class. In nephrotic rats anionic site distributions in matrix and GBM did not change significantly. Sialoglycoproteins were labeled with colloidal iron (CI). In PAN nephrosis a decrease of CI binding was observed at the epithelial-basement membrane junction of the glomerular capillary wall. However, CI labeling of the mesangial matrix and mesangial cell membranes did not differ from that of normal glomeruli.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differentiated microdomains of the luminal plasmalemma of murine muscle capillaries: segmental variations in young and old animals

We investigated the luminal surface of the continuous endothelium of the microvasculature of the murine heart and diaphragm to find out whether it has differentiated microdomains. The probes were ferritin molecules, cationized to pI's 6.8, 7.15, 7.6, 8.0 and 8.4, which were introduced by retrograde or anterograde perfusion through the aorta or vena cava after the blood was removed from the vasculature. The pattern of labeling was analyzed by electron microscopy and assessed quantitatively by morphometry in arterioles, capillaries, and venules identified in bipolar microvascular fields in the diaphragm. The results showed that the plasmalemma proper was heavily but discontinuously labeled by all cationized ferritins (CF) used, the labeling being less extensive on the venular endothelium. CF had access as individual molecules to a fraction of the vesicular population opened on the luminal front of the endothelium. Plasmalemmal vesicle labeling increased from approximately 10 to approximately 25% as the pI decreased from 8.4 to 6.8. Vesicle labeling also increased with CF concentration in the perfusate. All CF binding sites were removed by pronase and papain. Heparinase and heparitinase caused only a slight reduction in CF labeling. Neuraminidase decreased the extent and density of labeling, especially on the plasmalemma proper of the venular endothelium; this decrease was particularly pronounced in old animals.     

Permeation of endogenous IgG with an anionic subpopulation into glomerular basement membrane in rat

Conflicting results of previous electron microscopy studies and concerns about the validity of immunoperoxidase technique employed in those studies to accurately localize endogenous IgG in rat glomerular basement membrane (GBM) prompted us to use other techniques to answer the following question: Does endogenous IgG permeate the matrix of GBM? Immunofluorescence, radioimmunoassay (RIA), isoelectric focusing, sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE), and immunodetection on Western blots were used to detect endogenous IgG in GBM. Direct immunofluorescence of normal frozen rat kidney sections prepared from in vivo perfused kidney showed endogenous IgG in a linear pattern of staining in the GBM. RIA for rat IgG found the IgG content of collagenase-solubilized GBM to be 0.48% of the dry weight. Immunodetection for rat IgG on Western blots of SDS-PAGE-separated GBM demonstrated endogenous IgG in purified collagenase-solubilized GBM. IgG was detected as an intact molecule with covalently linked light and heavy chains and not as small immunoreactive catabolic fragments. Isoelectric focusing followed by immunodetection on Western blot showed that part of the endogenous IgG in GBM was anionic. The results clearly show that under normal conditions, endogenous IgG can permeate into the collagen matrix of GBM in rat and that some of this IgG is more anionic than the IgG in serum. These findings may assist in understanding the transit of autoantibodies to subepithelial glomerular antigens located beneath the matrix of GBM in membranous glomerulonephropathy.     

Anionic sites in glomerular basement membrane of rats with serum sickness nephritis: quick-freezing and deep-etching study

Summary Serum sickness nephritis was induced in male Fisher 344/JCL rats by injecting egg albumin into the foot pads and peritoneal cavity. The alteration of anionic sites in the glomerular basement membrane (GBM) of the rats with significant proteinuria was studied with a quick-freezing and deep-etching method using polyethyleneimine as a cationic probe. In control rats, anionic sites were located around the fibrils of the lamina rara externa, which radiated perpendicularly from the lamina densa to podocyte cell membranes. In the glomeruli of proteinuric rats, many electron-dense deposits were observed in the subepithelial side of the GBM, where the fibrils of the lamina rara externa were usually obscured and anionic sites around them could not be recognized. However, in some areas, a clear boundary could be observed between deposits and the lamina densa. Electron micrographs of freeze-fractured deposits showed that the fibrils radiated perpendicularly from the lamina densa and that anionic sites around them had been preserved. These results suggest that some of the deposits simply passed through the GBM and masked transiently the fibril structures of the GBM, but others probably destroyed these fibril structures, including anionic sites.     

Only the initial binding of cationic immune complexes to glomerular anionic sites is mediated by charge-charge interactions

The role of charge-charge interactions between cationic immune complexes and the anionic sites on the glomerular basement membrane was examined. For this purpose, soluble immune complexes at fivefold antigen excess were prepared with human serum albumin and cationized rabbit antibodies to this protein. When unrelated cationic proteins, protamine sulfate or cationized rabbit serum albumin, were given 1 min before the cationized immune complexes, glomerular immune deposits did not form. Cationic immune complexes allowed to deposit in glomeruli could readily be displaced by protamine sulfate or cationized rabbit serum albumin injected 1 min after the immune complexes. If the same cationic molecules were injected 1 hr after the immune complexes, the complexes could not be displaced from glomeruli. In contrast, cationic complexes that were deposited in glomeruli in the presence of a very high degree of antigen excess in circulation to prevent their condensation into larger complexes in glomeruli were readily displaced at 1 min and 1 hr with protamine sulfate or with cationized rabbit serum albumin. On the basis of these results, we concluded that the initial binding of cationic immune complexes to glomeruli occurs by charge-charge interactions. Once the immune complexes in glomeruli condense to larger deposits, forces other than charge-charge interactions are responsible for their retention in glomeruli.     

Model anionic polysaccharide matrices exhibit lower charge selectivity than is normally associated with kidney ultrafiltration

The influence of the anionic polysaccharide matrix (APM) of the glomerular basement membrane (GBM) on water transport and macromolecular transport charge selectivity has been studied in model systems which enable the analysis of the specific properties of the APM. Various APMs were studied including heparin and heparin-like polysaccharides, chondroitin sulfate and dextran sulfate. Upper estimates of the APM concentration in the GBM were obtained by relating measurements of the specific hydraulic conductivity of the heparin-like polysaccharides to measurements of single nephron glomerular filtration rate. This gave values of 40-45 mg ml-1 of polysaccharide, which was then used to analyse factors contributing to macromolecular charge selectivity. Transport analysis of the test dextran probes, used for previous in vivo clearance studies, in APMs demonstrated that there were no differential charge effects at APM concentrations in the range predicted above in the GBM. This was also found to be the case for the partitioning of anionic test probes at the APM-solution interface as measured directly using frontal gel chromatography and through thermodynamic analysis of sedimentation and diffusion data. These studies demonstrated that previous biophysical interpretations of glomerular charge selectivity have severely overestimated the partitioning effect due to the electrostatic effects of polyion-polyion interaction.     

Masking of anionic sites by deposits in lamina rara externa in immune complex nephritis in rats.

Alterations in glomerular basement membrane (GBM) anionic sites associated with immune deposits (ID) were observed using polyethyleneimine (PEI) as a cationic probe in serum sickness nephritis induced by egg albumin (EA). The anionic sites were fewer in number than in other GBM segments and were irregular in distribution in most, but not all, of the segments of the GBM with ID on the epithelial side of the lamina densa (LD). The disappearance of anionic sites was obvious in areas where the internal aspects of the lamina rara externa (LRE) of the GBM were occupied by ID, even if the ID were very small. In contrast, the disappearance of anionic sites was not evident, even though no change in anionic sites was found in some areas, where the ID had departed from the internal aspects of the LRE and a pale band was seen between the ID and the LD. Further, PEI aggregates, showing localization of anionic sites, were seen within the low density ID, but no PEI aggregates were seen within the high density ID. The results suggest that: 1) whether or not ID induce the disappearance of anionic sites is independent of the size of the ID, but is dependent on the density of and the place occupied by the ID, and 2) the ID seem to induce the disappearance of anionic sites by masking rather than destroying them.     

Localization of basement membrane glycoproteins in rat kidney during foetal development

The distribution of basement membrane glycoproteins (type IV collagen, laminin, fibronectin, and proteoglycans) was studied in foetal rat kidney by immunohistochemical techniques using polyclonal antibodies. From the first stages of nephron differentiation, all these glycoproteins were detectable by immunofluorescence in the tubular and glomerular basement membranes and in the mesangial matrix. As differentiation proceeded, labelling of glycoproteins progressively intensified, except for that of fibronectin, which gradually decreased in the glomerular basement membrane (GBM) and was barely observable at full differentiation. With immunoperoxidase staining in electron microscopy, all glycoproteins were seen to be widely dispersed in the spaces between the epithelial and endothelial glomerular cells so long as the GBM remained a loose structure. However, after it became a compact, 3-layered formation, type IV collagen and laminin were distributed throughout the GBM, whereas proteoglycans and anionic sites appeared as 2 rows of granules confined to the laminae rarae.     

Extralysosomal localisation of acid phosphatase in the rat kidney

 There is strong evidence that acid phosphatase (AcPase) plays an important role in the catabolism of the glomerular basement membrane (GBM) and the removal of macromolecular debris resulting from ultrafiltration. Recent enzyme histochemical investigations provide new evidence of the antithrombotic and anti-inflammatory function of ADPase and on the distribution of AcPase in mouse kidney tubule cells. By means of 3 mM cerium as the trapping agent and 1 mM p-nitrophenyl phosphate as the substrate, extralysosomal AcPase could be demonstrated at the ultrastructural level. Following a mild perfusion fixation (2% formaldehyde + 0.07% glutaraldehyde), an effective postfixation and short enzyme incubations (20 min) with microwave irradiation, highly specific enzyme histochemical reaction product and reasonable structural preservation were obtained. Extralysosomal, membrane-bound AcPase was observed along the endoplasmic reticulum, the trans-Golgi cisternae, the nuclear envelope, basal infoldings of the proximal and distal tubular cells and on glomerular profiles, e.g. cell membranes of podocytes, endothelium and basement membrane. Large amounts of extralysosomal AcPase were observed in the basement membrane of glomeruli, in contrast to no AcPase activity in the tubular and mesangial basement membrane. The observed difference in AcPase activity in the tubular epithelial basement membrane and the GBM supports the idea that AcPase in GBM specifically serves in the clearance of macromolecular debris to facilitate ultrafiltration. In the GBM a laminar distribution is observed, suggesting that both epithelial and endothelial cells are involved in the production of AcPase. Accepted: 16 September 1997     

Detection of glomerular anionic sites in post-embedded ultra-thin sections using cationic colloidal gold

We detected glomerular anionic sites in fixed, LR Gold-embedded ultra-thin tissue sections using cationic colloidal gold. Manual and computer-assisted quantitation were compared, and the influence of pH and glycosaminoglycan-degrading enzymes on site expression was examined. Both quantitation methods produced similar results. Alteration of pH within a narrow range (pH 2.5-3.0) markedly affected the staining pattern. At pH 2.5, epithelial and endothelial glycocalyx and regular sites restricted to the lamina rara externa were stained. At pH 3.0 and above, glycocalyx was unstained but intracellular and nuclear staining was present; glomerular basement membrane (GBM) and mesangial matrix sites were abundant. After chondroitinase ABC or hyaluronidase digestion, GBM staining was eliminated at pH 2.0 and reduced at pH 7.0 (p less than 0.001), suggesting that degraded sites are associated with chondroitin sulfate or hyaluronic acid. By contrast, prolonged heparitinase I digestion was ineffective at either pH. Digestion of purified substrates revealed crossreactivity of heparitinase towards chondroitin sulfate and of chondroitinase towards hyaluronic acid. Since tissue sites were reduced by chondroitinase but not heparitinase, we suggest that degradation is due to hyaluronidase activity of chondroitinase and the anionic sites are associated with hyaluronic acid. However, the influence of pH indicates that lamina rara externa sites are structurally distinct from other GBM anionic sites.