No Change in Glomerular Heparan Sulfate Structure in Early Human and Experimental Diabetic Nephropathy

Born, Jacob van den; Pisa, Brenda J.M.; Bakker, Marinka A.H.; Celie, Johanna W.A.M.; Straatman, Carin; Thomas, Steven R.; Viberti, Gian Carlo; Kjellén, Lena; Berden, Jo H. M.

doi:10.1074/jbc.m601552200

Cited by 44 publications

(37 citation statements)

References 48 publications

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“…51,52 Although these studies support the theory that reductions in GBM-HS contribute directly to loss of barrier function, labeling with mAb JM-403 was recently reported to be normal in diabetic humans and rats with microalbuminuria, and it was concluded that loss of GBM-HS may be a secondary event that occurs in advanced disease. 53 Here, immunostaining with both antibodies revealed that adult conditional mutants lack GBM-HS. This confirms that mouse agrin exists as a HSPG in vivo but questions the importance of GBM-HS for kidney function.…”

Section: Discussionmentioning

confidence: 76%

Disruption of Glomerular Basement Membrane Charge through Podocyte-Specific Mutation of Agrin Does Not Alter Glomerular Permselectivity

Harvey

Jarad

Cunningham

et al. 2007

The American Journal of Pathology

157

127

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Glomerular charge selectivity has been attributed to anionic heparan sulfate proteoglycans (HSPGs) in the glomerular basement membrane (GBM). Agrin is the predominant GBM-HSPG, but evidence that it contributes to the charge barrier is lacking, because newborn agrin-deficient mice die from neuromuscular defects. To study agrin in adult kidney, a new conditional allele was used to generate podocyte-specific knockouts. Mutants were viable and displayed no renal histopathology up to 9 months of age. Perlecan, a HSPG normally confined to the mesangium in mature glomeruli, did not appear in the mutant GBM, which lacked heparan sulfate. Moreover, GBM agrin was found to be derived primarily from podocytes. Polyethyleneimine labeling of fetal kidneys revealed anionic sites along both laminae rarae of the GBM that became most prominent along the subepithelial aspect at maturity; labeling was greatly reduced along the subepithelial aspect in agrin-deficient and conditional knockout mice. Despite this severe charge disruption, the glomerular filtration barrier was not compromised, even when challenged with bovine serum albumin overload. We conclude that agrin is not required for establishment or maintenance of GBM architecture. Although agrin contributes significantly to the anionic charge to the GBM, both it and its charge are not needed for glomerular permselectivity. This calls into question whether charge selectivity is a

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Section: Discussionmentioning

confidence: 76%

Disruption of Glomerular Basement Membrane Charge through Podocyte-Specific Mutation of Agrin Does Not Alter Glomerular Permselectivity

Harvey

Jarad

Cunningham

et al. 2007

The American Journal of Pathology

157

127

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“…Furthermore, although the enzyme heparanase was found to be increased in STZ-induced diabetic rats, this was actually not found to imply a significant reduction in the GBM HS content (37). Furthermore, no change in HS sulfation or charge density has been detected in early STZ-induced diabetes (35). Hence, the contribution of a decreased charge selectivity in the urinary hyperexcretion of albumin in early DNP is controversial.…”

Section: Discussionmentioning

confidence: 92%

Size and charge selectivity of the glomerular filter in early experimental diabetes in rats

Rippe¹,

Rippe²,

Torffvit³

et al. 2007

American Journal of Physiology-Renal Physiology

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Rippe C, Rippe A, Torffvit O, Rippe B. Size and charge selectivity of the glomerular filter in early experimental diabetes in rats. Am J Physiol Renal Physiol 293: F1533-F1538, 2007. First published August 15, 2007; doi:10.1152 doi:10. /ajprenal.00271.2007 is an early sign of diabetic nephropathy. The aim of the present study was to investigate whether the changes of the glomerular filtration barrier in early experimental diabetes are due to size-or charge-selective alterations. Wistar rats, made diabetic by streptozotocin (STZ) and having their blood glucose maintained at ϳ20 mM for 3 or 9 wk, were compared with age-matched controls. Glomerular clearances of native albumin (Cl-HSA) and neutralized albumin (Cl-nHSA) were assessed using a renal uptake technique. Glomerular filtration rate and renal plasma flow were assessed using 51 Cr-EDTA and [125 I]iodohippurate, respectively. In a separate set of animals, diabetic for 9 wk, and in controls, glomerular sieving coefficients () for neutral FITC-Ficoll (molecular radius: 15-90 Å) were assessed using size exclusion chromatography. At 3 wk of diabetes, Cl-HSA and Cl-nHSA remained unchanged, indicating no alteration in either size or charge selectivity. By contrast, at 9 wk of diabetes, there was a twofold increase of Cl-HSA, whereas Cl-nHSA remained largely unchanged, at first suggesting a glomerular charge defect. However, according to a two-pore model, the number of large pores, assessed from both Ficoll and Cl-HSA, increased twofold. In addition, a small reduction in proximal tubular reabsorption was observed at 3 wk, which was further reduced at 9 wk. In conclusion, no functional changes were observed in the glomerular filtration barrier at 3 wk of STZ-induced diabetes, whereas at 9 wk there was a decrease in size selectivity due to an increased number of large glomerular pores. sieving coefficient; proteinuria; capillary permeability; fractional clearance; macromolecules; diabetic nephropathy DIABETIC NEPHROPATHY (DNP) is currently the leading cause of end-stage renal disease in the Western world. In the early course of insulin-dependent diabetes, several functional and structural alterations occur in the kidney. Some of these alterations include glomerular hyperperfusion/hyperfiltration (34), hypertrophy of the nephrons and gross renal enlargement (3,25), and also changes in the glomerular extracellular matrix mass and composition. Microalbuminuria, i.e., moderately increased levels of albumin excretion (20 -200 g/min), is an early sign of DNP, reflecting either alterations in the glomerular barrier to (negatively charged) albumin or a reduction in the protein-reabsorbing properties of the proximal tubules, the latter supported by a recent study (29). According to the "Steno hypothesis," loss of negative charges in the filtration barrier, conceivably due to altered activity of the enzymes involved in the metabolism of extracellular matrix components, may be the cause of the microalbuminuria in early DNP (6). The Steno hypothesis is supported by the preferenti...

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“…However, several recent studies suggest that heparan sulphate in the GBM may not play a primary decisive role in the chargeselective permeability properties and development of proteinuria. For example, van den Born recently reported that there was no change in glomerular heparan sulphate content in early human and experimental diabetic nephropathy, although in both cases albuminuria was present [15]. Additional studies have shown that rats did not develop acute albuminuria after in vivo degradation of heparan sulphate by heparinase III [35].…”

Section: Discussionmentioning

confidence: 99%

“…Production of the core protein of agrin, the major heparan sulphate proteoglycan in the GBM, was not aberrant [11,13]. However, these heparan sulphate changes occur at the macroalbuminuric stage of diabetic nephropathy, since no glomerular heparan sulphate alterations were found at the microalbuminuric stage [15]. Recently, we showed that glomerular production of heparanase, an endo-β-1,4-D-glucuronidase involved in the hydrolytic cleavage of the β-1,4-glycosidic bond between glucuronic acid and glucosamine residues within N-sulphated and/or Nacetylated/N-sulphated domains of heparan sulphate [16,17], was increased in patients with overt diabetic nephropathy [11,18].…”

Section: Introductionmentioning

confidence: 87%

Heparanase induces a differential loss of heparan sulphate domains in overt diabetic nephropathy

et al. 2007

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Aims/hypothesis Recent studies suggest that loss of heparan sulphate in the glomerular basement membrane (GBM) of the kidney with diabetic nephropathy is due to the increased production of heparanase, a heparan sulphate-degrading endoglycosidase. Our present study addresses whether heparan sulphate with different modifications is differentially reduced in the GBM and whether heparanase selectively cleaves heparan sulphate with different domain specificities. Methods The heparan sulphate content of renal biopsies (14 diabetic nephropathy, five normal) were analysed by immunofluorescence staining with four anti-heparan sulphate antibodies: JM403, a monoclonal antibody (mAb) recognising N-unsubstituted glucosamine residues; two phage displayderived single chain antibodies HS4C3 and EW3D10, defining sulphated heparan sulphate domains; and anti-K5 antibody, an mAb recognising unmodified heparan sulphate domains. Results We found that modified heparan sulphate domains (JM403, HS4C3 and EW3D10), but not unmodified domains (anti-K5) and agrin core protein were reduced in the GBM of kidneys from patients with diabetic nephropathy, compared with controls. Glomerular heparanase levels were increased in diabetic nephropathy kidneys and inversely correlated with the amounts of modified heparan sulphate domains. Increased heparanase production and loss of JM403 staining in the GBM Diabetologia (2008) 51:372-382

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No Change in Glomerular Heparan Sulfate Structure in Early Human and Experimental Diabetic Nephropathy

Cited by 44 publications

References 48 publications

Disruption of Glomerular Basement Membrane Charge through Podocyte-Specific Mutation of Agrin Does Not Alter Glomerular Permselectivity

Disruption of Glomerular Basement Membrane Charge through Podocyte-Specific Mutation of Agrin Does Not Alter Glomerular Permselectivity

Size and charge selectivity of the glomerular filter in early experimental diabetes in rats

Heparanase induces a differential loss of heparan sulphate domains in overt diabetic nephropathy

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