J. van der Vlag

Apoptosis in the pathogenesis of systemic lupus erythematosus

Systemic lupus erythematosus (SLE) is a prototype inflammatory autoimmune disease resulting from autoimmune responses against nuclear autoantigens. During apoptosis many lupus autoantigens congregate inside the cells and are susceptible to modifications. Modified nuclear constituents are considered foreign and dangerous. Therefore, apoptotic cells have to has to be efficiently removed to avoid the accumulation of apoptotic debris and the subsequently development of autoimmune responses. Hence, apoptosis and clearance of apoptotic cells/material are considered key processes in the aetiology of SLE. Clearance deficiencies may account for the development of autoimmunity by inducing a loss of tolerance in lymphoid tissues. Furthermore, phagocytosis of apoptotic cells may lead to a pro-inflammatory response in the presence of autoantibodies. This may sustain inflammatory conditions and the pathology found in overt lupus.

Triggers for anti-chromatin autoantibody production in SLE

The formation of autoantibodies against chromatin is the main feature of systemic lupus erythematosis (SLE), an autoimmune disease, which is T-cell dependent and autoantigen-driven. Historically, antibodies against dsDNA, one ofthe components of chromatin, are considered as a hallmark of SLE. However, dsDNA is poorly immunogenic. Nucleosome-specific T helper cells have been identified. These T cells propagate not only nucleosome-specific antibodies, but also anti-dsDNA antibodies Nucleosomes are formed during apoptosis by cleavage of chromatin, and evidence of disturbed apoptosis has been foundespecially in certain murine models of lupus. In addition to an increased rate of apoptosis, autoimmunity against chromatin might also result from an impaired phagocytosis ofapoptotic material, for which strong evidence has been provided by studies in certain knock-out mice (C1q, SAP, Dnase I). The induction of an immune response to nucleosomes could be enhanced by modifi cations of histones or DNA during apoptosis, altered presentation by antigen presenting cells or a viral infection. The release of nucleosomes and the formation of anti-chromatin autoantibodies result in formation of complexes, which bind to the glomerular basement membrane via heparan sulfate. This deposition incites glomerulonephritis, the most serious manifestation of SLE.

The role of reactive oxygen species in apoptosis of the diabetic kidney

Increased levels of reactive oxygen species (ROS) by hyperglycemia can induce apoptosis of renal cells and diabetic nephropathy. The redox balance in the renal cell seems, therefore, of the utmost importance. ROS-mediated apoptosis may be further aggravated by an inadequate cytoprotective response against ROS. When there are insufficient cytoprotective and ROS scavenging molecules, ROS lead to considerable cellular damage and to a point of no return in apoptosis. Induction of cytoprotective proteins may prevent or attenuate apoptosis, renal cell injury, and finally diabetic nephropathy. Here, we discuss some mechanisms of apoptosis and several strategies that have been probed to ameliorate, or to prevent apoptosis in the diabetic kidney.

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

Aims/hypothesisRecent 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.MethodsThe 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 display-derived single chain antibodies HS4C3 and EW3D10, defining sulphated heparan sulphate domains; and anti-K5 antibody, an mAb recognising unmodified heparan sulphate domains.ResultsWe 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 correlated with the severity of proteinuria. Loss of modified heparan sulphate in the GBM as a result of degradation by heparanase was confirmed by heparan sulphate staining of heparanase-treated normal kidney biopsy specimens.Conclusions/interpretationOur data suggest that loss of modified heparan sulphate in the GBM is mediated by an increased heparanase presence and may play a role in the pathogenesis of diabetes-induced proteinuria.

Apoptosis and NET formation in the pathogenesis of SLE.

Systemic Lupus Erythematosus is an autoimmune disease characterized by the formation of anti-nuclear autoantibodies, particularly anti-chromatin. Although the aetiology of the disease has not yet been fully elucidated, several mechanisms have been proposed to be involved. Due to an aberrant apoptosis or decreased removal of apoptotic cells, apoptotic blebs containing chromatin are released. During apoptosis, chromatin is modified that increases its immunogenicity. Myeloid dendritic cells (myDC) can take up apoptotic blebs and stimulate autoreactive T helper cells, and subsequently the formation of autoantibodies by autoreactive B cells. Immune complexes formed by anti-chromatin autoantibodies and modified chromatin deposit on basal membranes, and incite a local inflammation, but can also stimulate plasmacytoid dendritic cells to produce IFN-α. In addition to apoptotic blebs, neutrophil extracellular traps released by dying neutrophils, in a process called NETosis, may serve as a source of autoantigens as well. In this review, we describe the role of both apoptosis and NETosis in the pathogenesis of SLE, and show how both processes may interact with each other.

Nephritogenic antibodies bind in glomeruli through interaction with exposed chromatin fragments and not with renal cross-reactive antigens

Cross-reactivity of anti-double stranded DNA (anti-dsDNA) antibodies with glomerular antigens has been postulated as a key factor in the development of lupus nephritis. Because no direct proof has been presented on anti-dsDNA antibodies binding in vivo to glomerular structures, we have analysed the binding of potentially nephritogenic anti-dsDNA antibodies to α-actinin and laminin. By enzyme-linked immunosorbent assay and surface plasmon resonance (SPR) analyses, we demonstrate that monoclonal antibodies (mAbs) bind both double-stranded DNA and α-actinin at high affinity. However, when added to nephritic kidney sections they did not bind to such structures, but rather to nucleosome-containing structures within the mesangial matrix or the glomerular basement membranes (GBMs). Nucleosomes, anti-nuclear antibodies and complexes of them were tested for their binding to glomerular components such as agrin, perlecan and laminin using SPR analysis. Nucleosomes bound to laminin, marginally to agrin, but not to perlecan or heparan sulphate-depleted agrin. Anti-histone H2B and anti-nucleosome antibodies in complex with nucleosomes slightly increased the binding of nucleosomes to agrin, while binding to laminin was slightly decreased compared to nucleosomes alone. In conclusion, the availability of nucleosomal antigens and the binding of these antigens to components of the mesangial matrix and GBM seem crucial for the glomerular deposition of immune complexes.

Role of heparanase-driven inflammatory cascade in pathogenesis of diabetic nephropathy

Renal involvement is a major medical concern in the diabetic population, and with the global epidemic of diabetes, diabetic nephropathy (DN) became the leading cause of end-stage renal failure in the Western world. Heparanase (the only known mammalian endoglycosidase that cleaves heparan sulfate) is essentially involved in DN pathogenesis. Nevertheless, the exact mode of heparanase action in sustaining the pathology of DN remains unclear. Here we describe a previously unrecognized combinatorial circuit of heparanase-driven molecular events promoting chronic inflammation and renal injury in individuals with DN. These events are fueled by heterotypic interactions among glomerular, tubular, and immune cell compartments, as well as diabetic milieu (DM) components. We found that under diabetic conditions latent heparanase, overexpressed by glomerular cells and posttranslationally activated by cathepsin L of tubular origin, sustains continuous activation of kidney-damaging macrophages by DM components, thus creating chronic inflammatory conditions and fostering macrophage-mediated renal injury. Elucidation of the mechanism underlying the enzyme action in diabetic kidney damage is critically important for the proper design and future implementation of heparanase-targeting therapeutic interventions (which are currently under intensive development and clinical testing) in individuals with DN and perhaps other complications of diabetes.

Improvement in chromatin maturity of human spermatozoa selected through density gradient centrifugation

A two-step gradient density centrifugation system has been set up to isolate two contrasting sperm populations of normozoospermic and oligoasthenoteratozoospermic (OAT) men. High- and low-density fractions were characterized by total and free thiol fluorescence as determined by monobromobimane-flow cytometry and by protamine/DNA ratios after protamine extraction and polyacrylamide acid-urea gel electrophoresis. Further chromatin characterization was performed through immunofluorescence (IF) with specific antibodies to nucleosomes, histone subtypes (H3.1/H3.2 and TH2B), histone modifications (KM-2 and H4K8ac) and precursor protamine 2. The native sperm samples from normozoospermic and OAT patients showed a biphasic distribution of total thiol levels, which changed in the sperm fractions obtained using the density isolation protocol presented here. Moreover, significant differences were detected in the protamine content in the different fractions of OAT and fertile donor samples. In addition, in the high-density fractions from OAT and normozoospermics, higher IF levels for H4K8ac and TH2B were seen. These results would be consistent with the intended beneficial effect on chromatin maturity of the density selection techniques currently being used in assisted fertilization procedures. However, most nucleosome and related proteins/modifications differ between OAT and normozoospermic men, even after gradient centrifugation, providing evidence for incomplete nuclear maturity in OAT patients.

Endothelin-1 Induces Proteinuria by Heparanase-Mediated Disruption of the Glomerular Glycocalyx

Diabetic nephropathy (DN) is the leading cause of CKD in the Western world. Endothelin receptor antagonists have emerged as a novel treatment for DN, but the mechanisms underlying the protective effect remain unknown. We previously showed that both heparanase and endothelin-1 are essential for the development of DN. Here, we further investigated the role of these proteins in DN, and demonstrated that endothelin-1 activates podocytes to release heparanase. Furthermore, conditioned podocyte culture medium increased glomerular transendothelial albumin passage in a heparanase-dependent manner. In mice, podocyte-specific knockout of the endothelin receptor prevented the diabetes-induced increase in glomerular heparanase expression, consequent reduction in heparan sulfate expression and endothelial glycocalyx thickness, and development of proteinuria observed in wild-type counterparts. Our data suggest that in diabetes, endothelin-1 signaling, as occurs in endothelial activation, induces heparanase expression in the podocyte, damage to the glycocalyx, proteinuria, and renal failure. Thus, prevention of these effects may constitute the mechanism of action of endothelin receptor blockers in DN.

The binding of lupus-derived autoantibodies to the C-terminal peptide (83–119) of the major SmD1 autoantigen can be mediated by double-stranded DNA and nucleosomes

Objectives: To evaluate the binding of lupus-derived autoantibodies, double-stranded DNA and nucleosomes to the positively charged C-terminal SmD1(residues 83–119) peptide and the full-length SmD protein. Methods: The binding of lupus-derived monoclonal antibodies, sera from patients with systemic lupus erythematosus, rheumatoid arthritis and systemic sclerosis, dsDNA and nucleosomes to the SmD1(83–119) peptide or the full-length SmD protein was determined using different ELISA methods. Results: Monoclonal anti-dsDNA antibodies and the serum of patients with systemic lupus erythematosus that are positive for anti-dsDNA antibodies react with the SmD1(83–119) peptide in ELISA. However, DNaseI treatment of the blocking reagents leads to a decreased reactivity. Purified dsDNA and nucleosomes bind to the SmD1 peptide but not to the full-length SmD protein. Conclusions: The SmD1(83–119) peptide is able to bind dsDNA and nucleosomes, and dsDNA or nucleosomes in applied reagents lead to an apparent reactivity of anti-dsDNA, anti-histone or nucleosome-specific antibodies with the SmD1(83–119) peptide in ELISA.