microRNA-induced IgA nephropathy.

IgA nephropathy (IgAN) is the most common GN in the world. Prevalence of IgAN is extremely high, noted in 30%– 40% of renal biopsies in Asian countries and South Europe. In Japan, the Renal Biopsy Registry compiles information from .1500 cases a year, among which the most frequent pathologic diagnosis is IgAN at 30%. Glomerular IgA deposition is observed in 16% of zero-hour biopsies, and IgA nephropathy with C3 deposition and macrophage infiltration is surprisingly observed in 1.6% of healthy donors’ kidneys. Thirty percent of IgAN cases resolve spontaneously, 30%– 40% smolder, and 30%progress to ESRDwithin 20–30 years. Over the last decade, the etiology of IgAN at the molecular level has been thoroughly investigated, resulting in a proposed four-step mechanism. First, the aberrantly galactosylated IgA1 with the hinge region O-glycans is generated in patients with IgAN. Second, antibodies against the aberrantly galacosylated IgA1 are produced. Third, immune complexes of IgA1-IgA or IgA1-IgG are generated. Fourth, the immune complexes bind to mesangial cells through the transferrin receptor (CD71). Complement activation occurs in response to immune complex deposition, leading to mesangial proliferation and eventually glomerulosclerosis. The first step of aberrant galactosylation at the hinge region of IgA1 was extensively studied during the last decade. The heavy chain of IgA1 contains an 18 amino acid hinge region that is rich in serine and threonine residues. Six O-linked saccharides containing N-acetylgalactosamine are added in a post-translational manner. Galactose is added to the N-acetylgalactosamine by core b1,3-galactosyltransferase 1 (C1b3GALT1). There are three hypotheses to explain the blocking of galactosylation of the N-acetylgalactosamine residue on the hinge region of IgAN. First, a 2,6-siayltransferase is excessively activated and sialic acid is attached to N-acetylgalactosamine, skipping galactose. Second, activity of C1b3GALT1 is attenuated, resulting in decreased galactose at O-glycan. Third, the stability of C1b3GALT is decreased by the reduction in its chaperone (Cosmc). Decreased activity of C1b3GALT1 was reported in freshly isolated and immortalized B cells from patients with IgAN. The level of mRNA encoding C1b3GALT1, but not Cosmc, is low in tonsillar B lymphocytes in IgAN. The aberrant galactosylation at the hinge region of IgA1 in IgAN may be heritable in that a higher IgA1 level with poor galactosylation is observed in first-degree relatives. Mutation of the Cosmc gene may account for the low activity of C1b3GALT1, but no evidence for the mutation was detected in patients with familiar IgAN. In this issue of JASN, Serino et al. report a comprehensive microarray screening of miRNA in IgAN and reveal a novel pathphysiological mechanism whereby the microRNA miR418b regulates the levels of mRNA encoding C1b3GALT1 in IgAN patients. The miR-418b binds to the 39-untranslated region of C1b3GALTmRNA and breaks it down. The expression level of C1b3GALTmRNA is inversely correlated with the expression level of miR-418b in IgAN patients. The C1b3GALT1 single nucleotide polymorphism (SNP) variant is associated with genetic susceptibility to IgAN. miR-418b binding to the C1b3GALT1 mRNA can be modulated by SNP (rs1047763) 1365G/A. The 1365G enhances binding of miR418b and 1365Aweakens it. The level of miR-418 expression is significantly higher in IgAN than Henoch-Schonlein purpura nephritis (HSPN), suggesting the pathophysiology of HSPN may differ from that of IgAN. The authors also show a potential treatment for IgAN using a miR-418b inhibitor that normalizes the galactosylation of IgA1 from patient B cells that reduces the aberrant galactosylation of IgA1. The role of miRNA in the kidney is revealed not only in normal kidney development and homeostasis of electrolytes but also in the inductionof kidneydiseases.Upregulationof miR-192 is associated with diabetic nephropathy, which regulates Smad-interacting protein-1, transforming growth factorb1 (TFGb), and d1-crystallin enhancer binding protein, leading to enhanced fibrosis of the kidney in a diabetic rodents. In addition, TGFb increases miRNA-148b and vice versa, resulting in a positive feedback system. miR-17 is also reported to target polycystic kidney disease (PKD)2 and interfere with the function of a post-transcriptional regulator (Bicc1) of PKD2 at the 39-untranslated region of mRNA encoding PKD2, which in turn enhanced translation of PKD2. Given the compromised Bicc1, the increase in PKD2 causes the development of a PKD-like phenotype. In IgAN, the level of miR-141, miR-205, and miR-192 in the kidney increases, whereas the level of miR-200 decreases. These microRNAs are not investigated in the present study. Published online ahead of print. Publication date available at www.jasn.org.