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Query: EC:4.2.2.7 (
heparinase
)
1,270
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
To evaluate the effect of biochemical modifications not possible in vivo, filters of dog glomerular basement membrane (GBM) were constructed in ultrafiltration cells in vitro. The sieving coefficients (SCs) of three protein markers of differing size and charge (native, anionic bovine albumin-BSA; cationized BSA-cBSA; and immunoglobulin G-IgG) were determined using filters of differing amounts of control GBM, and under varying transmembrane pressures (delta P). Flow rates did not increase proportionately with increasing delta P, indicating filter compressibility. Protein SCs did not change with changing delta P, but did decrease with increasing filter thickness. Control filters showed a small but definite charge selectivity (SCcBSA++ - SCBSA greater than 0); a much greater degree of size selectivity (SCcBSA - SCIgG) was observed. Hexadimethrine (HDM), a polycation which causes
proteinuria
in vivo, led to marked increases in protein SCs. In contrast, removal of the major population of intrinsic GBM negative charges by carboxyl group methylation only produced a small increase in the filtration of BSA, with no change in filtration of cBSA or IgG. Other biochemical modifications (
heparinase
or neuraminidase treatment) had no effect on filter permselectivity. Carboxyl group methylation essentially abolished filter binding of cationized ferritin, which showed substantial binding to control filters. These in vitro studies provide confirmatory evidence for a direct effect of HDM on the permselective properties of GBM. In addition, biochemical modification studies suggest a fundamental difference between the binding of an exogenous polycation to GBM anionic sites and the removal of intrinsic charges.
...
PMID:Macromolecular sieving by glomerular basement membrane in vitro: effect of polycation or biochemical modifications. 207 68
The polycation hexadimethrine (HDM) binds to anionic sites in the glomerular basement membrane (GBM) and causes heavy
proteinuria
when infused in vivo. An in vitro assay of 3H-HDM binding to isolated dog GBM was developed, to permit further analysis of the GBM components binding HDM. 3H-HDM binding to isolated GBM was saturable, reversible in dose-dependent fashion by competing polycations, and inhibited by increasing salt concentration and low pH. The pH dependence of binding suggested that most of the HDM binds to carboxyl groups rather than to the sulfate groups of proteoglycans. Removal of heparan sulfate by
heparinase
or purified heparatinase had no detectable effect on HDM binding. Treatment of GBM with neuraminidase, hyaluronidase, or chondroitinase reduced binding of HDM by a maximum of 20 to 38%. However, substitution of carboxyl anions with nonionizable glycine methyl ester residues resulted in complete elimination of HDM binding. Parallel results were obtained in studies of glomerular localization of cationized ferritin (CatF), pI 8.5. After carboxyl substitution, GBM did not bind CatF;
heparinase
-treated GBM bound CatF in a distribution not demonstrably different from normal. Cellulose acetate electrophoresis of glycosaminoglycan fractions prepared from treated GBM confirmed that carboxyl modification did not alter the content or charge of the heparan sulfate of GBM, but
heparinase
treatment removed at least 90% of heparan sulfate. The results indicate that carboxyl groups are quantitatively more important than heparan sulfate for binding of HDM in vitro. Since HDM causes
proteinuria
in vivo, carboxyl groups may be important for maintenance of normal permselectivity.
...
PMID:Polycation binding to glomerular basement membrane. Effect of biochemical modification. 380 16
Alterations in the permeability of the glomerular basement membrane (GBM) towards native ferritin (NF) and iodinated albumin (125I-BSA) following removal of the major glycosaminoglycans (GAGs) of the GBM, heparan sulfate (HS) and hyaluronic acid (HA), were assessed utilizing the techniques of routine electron microscopy and autoradiography, respectively. Kidneys were incubated with
heparinase
(to degrade the GAGs of the GBM) and subsequently perfused with either NF or 125I-BSA. Control kidneys, which were not treated with
heparinase
, showed a low permeability to both tracers, with NF being confined to the lamina rara interna and 125I-BSA exhibiting a low level of passage into the urinary spaces (as indicated by a low density of autoradiographic grains over the urinary spaces). After
heparinase
treatment there was an increase in the permeability of the GBM such that both NF and 125I-BSA passed through the GBM in larger quantities and entered the urinary spaces. Perfusion of cationized ferritin (CF) into control kidneys revealed this probe to bind to the HS-rich anionic sites present within the GBM. Treatment with
heparinase
resulted in an abolition of the CF binding thereby indicating that the sites are composed mainly of HS and that HS plays a key role in establishing the permeability properties of the GBM. The changes in the pattern of distribution and density of the anionic sites of the GBM following induction of nephrosis was also studied. Animals were rendered nephrotic by subcutaneous injections of an aminonucleoside of puromycin and their kidneys subsequently perfused with either CF or cationized cytochrome c. No difference in either the pattern of distribution on density of the anionic sites in the GBM of nephrotic kidneys was observed when compared to nonnephrotic controls; thus indicating that the
proteinuria
associated with aminonucleoside nephrosis might be due to changes in components of the glomerular capillary wall other than the anionic sites.
...
PMID:Glycosaminoglycans of the glomerular basement membrane in normal and nephrotic states. 730 62
Heparan sulfates (HS) are long, unbranched, negatively charged polysaccharides that are bound to core proteins. HS in the glomerular basement membrane (GBM) is reported to be important for charge-selective permeability. Aberrant GBM HS expression has been observed in several glomerular diseases, such as diabetic nephropathy and membranous glomerulopathy, and a decrease in HS generally is associated with
proteinuria
. This study, with the use of a controlled in vivo approach, evaluated whether degradation of HS in rat GBM resulted in acute
proteinuria
. Rats received two intravenous injections of either
heparinase
III to digest HS or neuraminidase to remove neuraminic acids (positive control). Urine samples were taken at various time points, and at the end of the experiment, kidneys were removed and analyzed. Injection with
heparinase
III resulted in a complete loss of glomerular HS as demonstrated by immunofluorescence staining using anti-HS antibodies and by electron microscopy using cupromeronic blue in a critical electrolyte concentration mode. In the urine, a strong increase in HS was found within 2 h after the first injection. Staining for agrin, the major HS proteoglycan core protein in the GBM, was unaltered. No urinary albumin or other proteins were detected at any time point, and no changes in glomerular morphology were noticed. Injection of rats with neuraminidase, however, resulted in a major increase of urinary albumin and was associated with an increase in urinary free neuraminic acid. An increased glomerular staining with Peanut agglutinin lectin, indicative of removal of neuraminic acid, was noted. In conclusion, removal of HS from the GBM does not result in acute albuminuria, whereas removal of neuraminic acid does.
...
PMID:In vivo degradation of heparan sulfates in the glomerular basement membrane does not result in proteinuria. 1830 8
