Lymphatic neoangiogenesis in human kidney transplants is associated with immunologically active lymphocytic infiltrates.

Renal transplant rejection is caused by a lymphocyte-rich inflammatory infiltrate that attacks cortical tubules and endothelial cells. Immunosuppressive therapy reduces the number of infiltrating cells; however, their exit routes are not known. Here a >50-fold increase of lymphatic vessel density over normal kidneys in grafts with nodular mononuclear infiltrates is demonstrated by immunohistochemistry on human renal transplant biopsies using antibodies to the lymphatic endothelial marker protein podoplanin. Nodular infiltrates are constantly associated with newly formed, Ki-67-expressing lymphatic vessels and contain the entire repertoire of T and B lymphocytes to provide specific cellular and humoral alloantigenic immune responses, including Ki-67(+) CD4(+) and CD8(+) T lymphocytes, S100(+) dendritic cells, and Ki-67(+)CD20(+) B lymphocytes and lambda- and kappa-chain-expressing plasmacytoid cells. Numerous chemokine receptor CCR7(+) cells within the nodular infiltrates seemed to be attracted by secondary lymphatic chemokine (SLC/CCL21) that is produced and released by lymphatic endothelial cells in a complex with podoplanin. From these results, it is speculated that lymphatic neoangiogenesis not only contributes to the export of the rejection infiltrate but also is involved in the maintenance of a potentially detrimental alloreactive immune response in renal transplants and provides a novel therapeutic target.

Antioxidant treatment of therapy-resistant idiopathic membranous nephropathy with probucol: a pilot study.

BACKGROUND: Proteinuria in Heymann's nephritis, an experimental rat model disease corresponding to membranous nephropathy, has been shown to be due to lipid peroxidation. Since the pathophysiology might be similar to idiopathic membranous nephropathy in humans, we performed a prospective multicenter trial to investigate the efficacy of the lipid peroxidation scavenger, probucol. METHODS: Fifteen patients with biopsy-proven idiopathic membranous nephropathy resistant to conventional immunosuppressive therapy (n = 7) and/or ACEI treatment (n = 12) were recruited. Probucol (1 g/d orally) was administered for three months, followed by a washout period of four weeks, whereon lovastatin (10-20 mg/d orally) was administered for additional three months. RESULTS: A significant reduction in proteinuria was seen during the probucol treatment (median (range): 6.4 (3.8-9.1) g/d vs. 4.7 (1.3-16) g/d; P < 0.05), with partial remission achieved in four patients. Three of these patients had previously been resistant to immunosuppressive therapy. Median protein excretion increased to pretreatment values during the washout period (6.2 (1.9-15) g/d; P < 0.05) and was not significantly different after the intake of lovastatin (4.9 (1.8-19) g/d; P = NS). None of the patients achieved partial remission during lovastatin therapy (P < 0.05 vs. probucol). CONCLUSION: The present study led us to conclude that proteinuria can be reduced by probucol in some patients with idiopathic membranous nephropathy. A randomized multicenter study to further elucidate the influence of lipid peroxidation scavengers on membranous nephropathy is warranted.

Glomerular expression of dystroglycans is reduced in minimal change nephrosis but not in focal segmental glomerulosclerosis.

Extensive flattening of podocyte foot processes and increased permeability of the glomerular capillary filter are the major pathologic features of minimal change nephrosis (MCN) and focal segmental glomerulosclerosis (FSGS). Adhesion proteins anchor and stabilize podocytes on the glomerular basement membrane (GBM), and presumably are involved in the pathogenesis of foot process flattening. Thus far, ao3 P,-integrin was localized to basal cell membrane domains. In this report, ao- and 3-dystroglycan (DG) were detected at precisely the sa-ne location by immunoelectron microscopy. and the presence of ac- and /-DG chains was confirmed by immunoblotting on isolated human glomeruli. Because the major DG binding partners in the GBM (laminin, agrin, perlecan), and the intracellular dystrophin analogue utrophin are also present in glomeruli, it appears that podocytes adhere to the GBM via DG complexes, similar to muscle fibers in which actin is linked via dystrophin and DG to the extracellular matrix. As with muscle cells, it is therefore plausible that podocytes use precisely actin-guided DG complexes at their "soles" to actively govern the topography of GBM matrix proteins. Expression of the a//3-DG complex was reported to be reduced in muscular dystrophies. and therefore a search for similar pathologic alterations in archival kidney biopsies from patients with MCN (it = 16) and FSGS (ni = 8) was conducted by quantitative immunoelectron microscopy. The density of a-DG on the podocyte's soles was significantly reduced to 25% in MCN, whereas it was not different in normal kidneys and FSGS. The expression of 3-DG was reduced to >50% in MCN, and was slightly increased in FSGS. Levels of DG expression returned to normal in MCN after steroid treatment (7 = 4). Expression of /3-integrin remained at normal levels in all conditions. These findings point to different potentially pathogenic mechanisms of foot process flattening in MCN and FSGS.