Competition between polyanions in glomerular binding and renal clearance

The renal clearance of dextran sulfate decreases in puromycin aminonucleoside-induced glomerulosclerosis: A puzzle observation

BACKGROUND

Puromycin aminonucleoside-induced nephrosis is characterized by increased renal excretion of plasma proteins. We employed this experimental model to study the urinary clearance of dextran sulfate.

METHODS

The dextran sulfate eliminated by the urine was determined using a metachromatic assay. Polysaccharide fragments were analyzed by chromatographic and electrophoretic procedures. Disaccharide composition of the glomerular heparan sulfate was assessed using digestion with specific lyases.

RESULTS

In normal rats dextran sulfate is partially degraded to lower molecular weight fragments and only then eliminated by the urine. Surprisingly, in puromycin aminonucleoside-induced glomerulosclerosis the molecular size of the fragments of dextran sulfate found in the urine is the same or even lower than in control animals in spite of the marked proteinuria. Furthermore, urinary excretion of dextran sulfate decreases in the experimentally induced nephrosis. This observation cannot be totally attributed to a reduced number of physiologically active nephrons since the glomerular filtration rate decreases approximately 32% after puromycin aminonucleoside administration while the urinary excretion of 8 kDa-dextran sulfate decreases 3-fold. The glomerular heparan sulfate shows reduced sulfation when compared with normal animals. Possibly puromycin aminonucleoside decreases the activity of kidney endoglycosidases, which reduce the molecular size of the sulfated polysaccharide, leading to a decrease in its renal clearance. Reduced sulfation of the glomerular heparan sulfate in the puromycin aminonucleoside-induced nephrosis does not alter the size of the dextran sulfate eliminated by the kidney, as suggested for protein.

CONCLUSIONS

Each pathological process induces a particular modification in the kidney, which in turn can affect the renal selectivity to specific macromolecules in different ways.

Low molecular weight heparin in the treatment of puromycin-induced nephrosis

Heparin may have a beneficial effect in proteinuric renal diseases, where negative charges of the glomerular capillary membrane are compromised. We evaluated the role of low molecular weight heparin (LMWH - 3000 Da) in puromycin aminonucleoside (PAN)-induced focal and segmental glomerulosclerosis in male Wistar rats: Controls (C) n=7, LMWH-treated group, n=9, subcutaneously (SC), 6 mg/kg every day. The PAN group (n=7) received 7 doses on weeks 0, 1, 2, 4, 6, 8, 10 (SC - 2mg/100g), and a group PAN+LMWH (n=6). After 12 weeks, cholesterol and triglycerides were higher in nephrotic groups, as well as proteinuria and urinary IgG. Kidney weight, glomerular volume, and glomerular sclerosis index were higher in the PAN-treated groups. Glomerular capillary length density (L(Vcap)) and glomerular capillary surface density (S(Vcap)) were lower in the PAN group, and mesangial fractional volume was higher. Fibronectin immunostaining was more intense in the PAN group, and collagens I and III were absent in the studied glomeruli. Thus, LMWH prevented mesangial expansion and capillaries changes, showing antiproliferative properties, despite worsening glomerular permeability changes in the PAN model. In conclusion, LMWH interferes in the complications of PAN model, but not through inhibition of the proteinuria.

Urinary clearance of albumin is critically determined by its tertiary structure

The excretion of serum albumin in the urine is considered the net result of renal glomerular filtration and tubular uptake. During routine experiments, we observed that a batch of tritium-labeled albumin yielded anomalous results, being excreted in the urine of isolated perfused kidneys at 10 times the rate of normal tritiated albumin. This anomalous albumin, when simultaneously studied with normal carbon 14-labeled albumin, exhibited 10 times greater excretion than normal [(14)C]albumin. Anomalous albumin could not be reversed to normal albumin by means of conditioning with blood. In vivo clearances of anomalous albumin could not be quantitated because anomalous albumin is degraded during circulation. Anomalous albumin appeared to have the same molecular size (as determined with sodium dodecyl sulfate-polyacrylamide gel electrophoresis, capillary electrophoresis, and gel chromatography) and isoelectric-point profile (2-dimensional electrophresis) as normal albumin. Normal albumin could be transformed to anomalous albumin with alkali/heat treatment. Reverse-phase high-pressure liquid chromatography analysis of fragments from tryptic digests of anomalous albumin, alkali/heat-treated albumin, and normal albumin suggest that anomalous albumin and alkali/heat-treated albumin have altered tertiary structure, possibly as a result of denaturation and disulfide exchange. These studies show that the tertiary structure of albumin, beyond simple size and charge, is a critical determinant for albumin processing by the kidney and suggest that a specific albumin-recognition event by the kidneys is critical to normal renal handling of albumin.

Structural determinants of glomerular permeability

Recent progress in relating the functional properties of the glomerular capillary wall to its unique structure is reviewed. The fenestrated endothelium, glomerular basement membrane (GBM), and epithelial filtration slits form a series arrangement in which the flow diverges as it enters the GBM from the fenestrae and converges again at the filtration slits. A hydrodynamic model that combines morphometric findings with water flow data in isolated GBM has predicted overall hydraulic permeabilities that are consistent with measurements in vivo. The resistance of the GBM to water flow, which accounts for roughly half that of the capillary wall, is strongly dependent on the extent to which the GBM surfaces are blocked by cells. The spatial frequency of filtration slits is predicted to be a very important determinant of the overall hydraulic permeability, in keeping with observations in several glomerular diseases in humans. Whereas the hydraulic resistances of the cell layers and GBM are additive, the overall sieving coefficient for a macromolecule (its concentration in Bowman's space divided by that in plasma) is the product of the sieving coefficients for the individual layers. Models for macromolecule filtration reveal that the individual sieving coefficients are influenced by one another and by the filtrate velocity, requiring great care in extrapolating in vitro observations to the living animal. The size selectivity of the glomerular capillary has been shown to be determined largely by the cellular layers, rather than the GBM. Controversial findings concerning glomerular charge selectivity are reviewed, and it is concluded that there is good evidence for a role of charge in restricting the transmural movement of albumin. Also discussed is an effect of albumin that has received little attention, namely, its tendency to increase the sieving coefficients of test macromolecules via steric interactions. Among the unresolved issues are the specific contributions of the endothelial glycocalyx and epithelial slit diaphragm to the overall hydraulic resistance and macromolecule selectivity and the nanostructural basis for the observed permeability properties of the GBM.

The return of glomerular filtered albumin to the rat renal vein--the albumin retrieval pathway

BACKGROUND

Recent studies have demonstrated that the normal glomerular capillary wall (GCW) is not charge selective to albumin. This means that albumin flux across the GCW is high. This has been confirmed in studies where albumin uptake by the tubules has been inhibited. Therefore, there must be a high capacity postglomerular retrieval pathway in normal kidneys that returns filtered albumin back to the blood supply.

METHODS

This study identifies the presence of glomerular filtered albumin in the renal vein from the analysis of the decrease of radioactivity in the venous effluent after the injection of a pulse of tritium labeled albumin into the renal artery in vivo and in the isolated perfused kidney (IPK).

RESULTS

The glomerular filtered albumin is returned to the blood supply by a high capacity pathway that transports this albumin at a rate of 1830+/-292 microg/min rat kidney (n= 14) (mean+/-SEM). This pathway has been identified under physiological conditions in vivo and in the IPK. The pathway is specific for albumin as it does not occur for horseradish peroxidase (HRP). The pathway is inhibited in a non-filtering kidney. The pathway is also inhibited by NH4Cl, an inhibitor of protein uptake.

CONCLUSIONS

The high capacity retrieval pathway for albumin is most likely associated with transtubular cell transport. It is also apparent that most albuminuric states could be accounted for by the malfunctioning of this pathway without resorting to any change in glomerular permselectivity.

Characteristics of albumin processing during renal passage in anti-Thy1 and anti-glomerular basement membrane glomerulonephritis

Recent studies have shown that glomerular-filtered albumin appears to be processed by two distinct cellular pathways. The major pathway, a high-capacity retrieval pathway, returns most of the filtered albumin to the blood supply intact. The albumin not taken up by the retrieval pathway is degraded by lysosomes during renal passage and excreted as fragments in urine. We studied the interplay of the albumin retrieval pathway and the degradation pathway in the disease models of anti-Thy1 nephritis, a model of mild proteinuria, and anti-glomerular basement membrane (anti-GBM) disease, a model of severe proteinuria. This is achieved by investigating the integrity of urinary albumin and its excretion rate. Total albumin excretion (intact plus fragments) did not change significantly in the rats with anti-Thy1 nephritis. However, it was established that intact albumin excretion had a strong positive correlation with increasing total-protein excretion, which showed that the degradation pathway was being predominantly affected in this disease. For the rats with anti-GBM disease, total protein excretion increased 26-fold compared with the control group, and intact albumin excretion increased 250-fold. The profound changes in albumin excretion in anti-GBM disease are consistent with inhibition primarily of the retrieval pathway.

Puromycin aminonucleoside nephrosis results in a marked increase in fractional clearance of albumin

Puromycin aminonucleoside nephrosis (PAN) results in a marked increase in the fractional clearance of albumin. The increase in the fractional clearance of [(3)H]albumin to approximately 0.045, as measured both in vivo and in the isolated perfused rat kidney (IPK) with PAN, occurs without an accompanying equivalent increase in glomerular capillary wall size selectivity as previously measured with dextrans. This is very similar to the marked increase in albuminuria seen with kidneys treated with inhibitors of endocytosis by the tubular epithelium, particularly lysine (T. M. Osicka, L. M. Pratt, and W. D. Comper. Nephrology 2: 199-212, 1996). The similarity is further established that, like in the presence of lysine, [(3)H]albumin excreted in urine from rats with PAN is essentially intact whereas, in both in vivo and IPK control experiments, excreted [(3)H]albumin is heavily degraded. The same observations have also been made for (3)H-labeled anionic horseradish peroxidase. These observations suggest that the significant albuminuria that occurs in PAN is primarily post-glomerular basement membrane in origin.

The return of glomerular-filtered albumin to the rat renal vein

BACKGROUND

Recent studies have demonstrated that the normal glomerular capillary wall (GCW) is not charge selective to albumin. This means that albumin flux across the GCW is high, and this has been confirmed in studies in which albumin uptake by the tubules has been inhibited. Therefore, there must be a high-capacity postglomerular retrieval pathway in normal kidneys that returns filtered albumin back to the blood supply.

METHODS

This study identifies the presence of glomerular-filtered albumin in the renal vein from the analysis of the decrease of radioactivity in the venous effluent after the injection of a pulse of tritium-labeled albumin into the renal artery in vivo and in the isolated perfused kidney.

RESULTS

The postglomerular filtered albumin is returned to the blood supply by a high-capacity pathway that transports this albumin at a rate of 1830 +/- 292 micrograms/min.rat kidney (N = 14, mean +/- SEM). This pathway has been identified under physiological conditions in vivo and in the isolated perfused kidney. The pathway is specific for albumin, as it does not occur for horseradish peroxidase. The pathway is inhibited in a nonfiltering kidney. The pathway is also inhibited by ammonium chloride (an agent that inhibits tubular protein uptake but does not alter glomerular size selectivity) and by albumin peptides (which compete for the tubular albumin receptor).

CONCLUSIONS

The high-capacity retrieval pathway for albumin is most likely associated with transtubular cell transport. It is also apparent that most albuminuric states could be accounted for by the malfunctioning of this pathway without resorting to any change in glomerular permselectivity.

Tubular inhibition destroys charge selectivity for anionic and neutral horseradish peroxidase

The fractional clearance of [3H]anionic HRP and [3H]neutral HRP in the isolated perfused kidney as determined by radioactivity analysis was 0.0160+/-0.0028 (n=6) and 0.0388+/-0.0076 (n=8) respectively. The apparent charge selectivity for both the anionic and neutral forms of HRP observed was destroyed with the inclusion of the tubular uptake inhibitors, 150 mM lysine and 10 mM NH4Cl, in the perfusate. In the presence of 150 mM lysine, the clearances of [3H]anionic HRP and [3H]neutral HRP were 0.0645+/-0.0110 (n=4) and 0. 0784+/-0.0120 (n=4) respectively, and 0.0564+/-0.0035 (n=4) and 0. 0694+/-0.0054 (n=4) respectively in the presence of 10 mM NH4Cl. The clearance for both the anionic and neutral HRP probes in these tubular uptake inhibited systems fits precisely the size selective characteristics of the glomerular capillary wall as determined by transport probes calibrated for hydrodynamic size by size exclusion chromatography. The tubular uptake inhibitors were observed not to alter glomerular permselectivity as determined using polydisperse dextran fractions and the behaviour of neutral HRP. This study demonstrates that charge selectivity for differently charged proteins is not as great as originally thought and suggests that the clearance differences between anionic and neutral forms may be due to differential handling by the tubules.

Anomalous decrease in dextran sulfate clearance in the diabetic rat kidney

The anomalous increase in charge selectivity as previously observed with reduced dextran sulfate clearances in diabetic rats (L. D. Michels, M. Davidman, and W. F. Keane. Kidney Int. 21: 699-705, 1982) was confirmed in 4-wk streptozotocin (STZ) diabetic Sprague-Dawley rats using the isolated perfused kidney technique. The apparent charge selectivity in both control and diabetic rats could be abolished by increasing the dextran sulfate concentration to 200 micrograms/ml in the perfusate. This was demonstrated by a high rate of processing of dextran sulfate (approximately 1,700 ng.min-1.kidney-1) by glomeruli in both control and diabetic kidneys and by the fact that charge interaction could not explain the concentration dependence. The amount of urinary desulfation of dextran sulfate was also found to be significantly less in the diabetic kidney as was glomerular sulfatase activity compared with controls. Dextran sulfate glomerular processing is therefore altered in the STZ diabetic rat kidney but could be rationalized in terms of previous models of endothelial cell receptor-mediated uptake of dextran sulfate. The results are consistent with recent work demonstrating that there is little or no electrostatic charge interaction operating on dextran sulfate or other negatively charged molecules at the glomerular capillary wall.