α3 Integrin of Cell-Cell Contact Mediates Kidney Fibrosis by Integrin-Linked Kinase in Proximal Tubular E-Cadherin Deficient Mice.

Loss of E-cadherin marks a defect in epithelial integrity and polarity during tissue injury and fibrosis. Whether loss of E-cadherin plays a causal role in fibrosis is uncertain. α3ß1 Integrin has been identified to complex with E-cadherin in cell-cell adhesion, but little is known about the details of their cross talk. Herein, E-cadherin gene (Cdh1) was selectively deleted from proximal tubules of murine kidney by Sglt2Cre. Ablation of E-cadherin up-regulated α3ß1 integrin at cell-cell adhesion. E-cadherin-deficient proximal tubular epithelial cell displayed enhanced transforming growth factor-ß1-induced α-smooth muscle actin (α-SMA) and vimentin expression, which was suppressed by siRNA silencing of α3 integrin, but not ß1 integrin. Up-regulation of transforming growth factor-ß1-induced α-SMA was mediated by an α3 integrin-dependent increase in integrin-linked kinase (ILK). Src phosphorylation of ß-catenin and consequent p-ß-catenin-Y654/p-Smad2 transcriptional complex underlies the transcriptional up-regulation of ILK. Kidney fibrosis after unilateral ureteric obstruction or ischemia reperfusion was increased in proximal tubule E-cadherin-deficient mice in comparison to that of E-cadherin intact control mice. The exacerbation of fibrosis was explained by the α3 integrin-dependent increase of ILK, ß-catenin nuclear translocation, and α-SMA/proximal tubular-specific Cre double positive staining in proximal tubular epithelial cell. These studies delineate a nonconventional integrin/ILK signaling by α3 integrin-dependent Src/p-ß-catenin-Y654/p-Smad2-mediated up-regulation of ILK through which loss of E-cadherin leads to kidney fibrosis.

Failed renoprotection by alternatively activated bone marrow macrophages is due to a proliferation-dependent phenotype switch in vivo.

Alternatively activated macrophages (M2) regulate immune responses and ex vivo polarized splenic M2 are able to ameliorate renal injury including models of renal disease, such as adriamycin nephropathy. Whether M2 derived from other organs have similar protective efficacy is unknown. Here, we report adoptively transferred bone marrow M2 macrophages did not improve renal function or reduce renal injury in adriamycin nephropathy, whereas splenic M2 macrophages were protective. Bone marrow and splenic M2 macrophages showed similar regulatory phenotypes and suppressive functions in vitro. Within the inflamed kidney, suppressive phenotypes in bone marrow but not in splenic M2 macrophages, were dramatically reduced. Loss of the suppressive phenotype in bone marrow M2 was related to strong proliferation of bone marrow M2. Bone marrow M2 proliferation in vivo correlated with M-CSF expression by tubular cells in the inflamed kidney. Inhibition of M-CSF in vitro limited bone marrow M2 proliferation and prevented switch of phenotype. Proliferating cells derived from transfused bone marrow M2 were inflammatory rather than regulatory in their phenotype and function. Thus bone marrow in contrast to splenic M2 macrophages do not protect against renal structural and functional injury in murine adriamycin nephropathy. The failed renoprotection of bone marrow M2 is due to the switch of transfused M2 macrophages from a regulatory to an inflammatory phenotype.

Discrete functions of M2a and M2c macrophage subsets determine their relative efficacy in treating chronic kidney disease.

Two types of alternatively activated macrophages, M(2a) induced by IL-4/IL-13 and M(2c) by IL-10/TGF-ß, exhibit anti-inflammatory functions in vitro and protect against renal injury in vivo. Since their relative therapeutic efficacy is unclear, we compared the effects of these two macrophage subsets in murine adriamycin nephrosis. Both subsets significantly reduced renal inflammation and renal injury; however, M(2c) macrophages more effectively reduced glomerulosclerosis, tubular atrophy, interstitial expansion, and proteinuria than M(2a) macrophages. The M(2c) macrophages were also more effective than M(2a) in reduction of macrophage and CD4(+) T-cell infiltration in kidney. Moreover, nephrotic mice treated with M(2c) had a greater reduction in renal fibrosis than those treated with M(2a). M(2c) but not M(2a) macrophages induced regulatory T cells (Tregs) from CD4(+)CD25(-) T cells in vitro, and increased Treg numbers in local draining lymph nodes of nephrotic mice. To determine whether the greater protection with M(2c) was due to their capability to induce Tregs, the Tregs were depleted by PC61 antibody in nephrotic mice treated with M(2a) or M(2c). Treg depletion diminished the superior effects of M(2c) compared to M(2a) in protection against renal injury, inflammatory infiltrates, and renal fibrosis. Thus, M(2c) are more potent than M(2a) macrophages in protecting against renal injury due to their ability to induce Tregs.

Transfused macrophages ameliorate pancreatic and renal injury in murine diabetes mellitus.

BACKGROUND: Alternatively activated macrophages (M2 macrophages) are able to reduce renal injury in murine adriamycin nephropathy. However, the effect of M2 macrophages in other renal diseases such as diabetic nephropathy remains unknown. METHODS: Macrophages were separated from splenocytes and polarized with IL-4 and IL-13 into a protective phenotype. Mice underwent adoptive transfer with M2 macrophages, and then diabetes was induced by tail vein injection with streptozotocin (STZ). Blood glucose levels were monitored daily. Mice were sacrificed at week 10 after STZ. Renal function and histopathological injury were assessed quantitatively. RESULTS: Transfused M2 macrophages accumulated progressively in kidneys for up to 10 weeks after STZ. Kidneys from diabetic mice transfused with M2 macrophages had less tubular atrophy, glomerular hypertrophy and interstitial expansion than did control diabetic mice. M2 macrophages suppressed the development of interstitial fibrosis. In addition, the degree of pancreatic islet injury, as assessed by insulin staining, haemoglobin A1c and blood glucose was reduced after transfusion of M2 macrophages. In vivo, activation of kidney endogenous macrophage cytokine expression was inhibited by M2 macrophages. CONCLUSION: Our findings show that M2 macrophages can protect against islet and renal injury in streptozotocin-induced diabetes, providing a potential therapeutic strategy for diabetes and diabetic nephropathy.

The CD40-CD154 co-stimulation pathway mediates innate immune injury in adriamycin nephrosis.

BACKGROUND: Blockade of CD40-CD40 ligand (CD154) interactions protects against renal injury in adriamycin nephropathy (AN) in immunocompetent mice. To investigate whether this protection relied on adaptive or cognate immunity, we tested the effect of CD40-CD154 blockade in severe combined immunodeficient (SCID) mice. METHODS: SCID mice were divided into three groups: normal, AN + hamster IgG (ADR+IgG group) and AN + anti-CD154 antibody (MR1) (ADR+MR1 group). AN was induced by tail vein injection of 5.2 mg/kg of adriamycin (ADR). Hamster IgG (control Ab) or MR1 was administered intraperitoneally on days 5, 7, 9 and 11 after ADR injection. Histological and functional data were collected 4 weeks after ADR injection. In vitro experiments tested the effect of soluble and cell-bound CD154 co-cultured with CD40-expressing cells [macrophages, mesangial cells and renal tubular epithelial cells (RTEC)]. RESULTS: All experimental animals developed nephropathy. Compared to the ADR+IgG group, ADR+MR1 animals had significantly less histological injury (glomerulosclerosis and tubular atrophy) and functional injury (creatinine clearance). Kidneys of ADR+MR1 animals had significantly less macrophage infiltration than those of ADR+IgG animals. Interestingly, expression of CD40 and CD41 (a platelet-specific marker) was significantly less in ADR+MR1 animals compared to ADR+IgG animals. In vitro, CD154 blockade significantly attenuated upregulation of CCL2 gene expression by RTEC stimulated by activated macrophage-conditioned medium. In contrast, platelet-induced upregulation of macrophage and mesangial cell proinflammatory cytokine gene expression were not CD154-dependent. CONCLUSION: CD40-CD154 blockade has a significant innate renoprotective effect in ADR nephrosis. This is potentially due to inhibition of macrophage-derived soluble CD154.