[Anti-NEP and anti-PLA2R antibodies in membranous nephropathy: an update]. / Anticorps anti-EPN et anti-PLA2R dans les glomerulopathies extramembraneuses: le point en 2014.

Membranous nephropathy (MN) is the most common cause for nephrotic syndrome in adults and occurs as an idiopathic (primary) or secondary disease. Since the early 2000's, substantial advances have been made in the understanding of the molecular bases of MN. The neutral endopeptidase (NEP) and the receptor for secretory phospholipase A2 (PLA2R) have been identified as target antigens for circulating and deposited antibodies in allo-immune neonatal and adult " idiopathic " MN, respectively. These antibodies recognize specific antigens of podocytes, precipitate as subepithelial immune complexes and activate complement leading to proteinuria. Anti-PLA2R antibodies are of particular clinical importance. Indeed, they are detected in approximately 70% of primary MN in adults, demonstrating that MN actually is an autoimmune condition specific to the kidney. In Europeans, genome-wide studies have shown an association between alleles of PLA2R1 and HLA DQA1 (class II genes of tissue histocompatibility complex) genes and idiopathic MN. Newly developed diagnostic tests detecting circulating anti-PLA2R antibody and PLA2R antigen in glomerular deposits have induced a change in paradigm in the diagnostic approach of idiopathic MN. Measurement of circulating anti-PLA2R antibody is also very useful for the monitoring of MN activity. However, the mechanisms responsible for the formation of anti-PLA2R antibodies as well as those involved in the progression of MN to end-stage renal disease remain to be defined.

Aristolochic acid induces proximal tubule apoptosis and epithelial to mesenchymal transformation.

Aristolochic acid contamination in herbal remedies leads to interstitial fibrosis, tubular atrophy, and renal failure in humans. To study the cellular mechanisms contributing to the pathophysiology of this renal disease, we studied Wistar rats treated with aristolochic acid and measured tubular and interstitial cell proliferation, epithelial/mesenchymal cell marker expression, tubular membrane integrity, myofibroblast accumulation, oxidative stress, mitochondrial damage, tubular apoptosis, and fibrosis. Oxidative stress, a loss of cadherin concomitant with vimentin expression, basement membrane denudation with active caspase-3 expression, and mitochondrial injury within tubular cells were evident within 5 days of administration of the toxin. During the chronic phase, interstitial mesenchymal cells accumulated in areas of collagen deposits. Impaired regeneration and apoptosis of proximal tubular cells resulted in tubule atrophy with a near absence of dedifferentiated cell transmembrane migration. We suggest that resident fibroblast activation plays a critical role in the process of renal fibrosis during aristolochic acid toxicity.