Distinct macrophage phenotypes contribute to kidney injury and repair

The ischemically injured kidney undergoes tubular cell necrosis and apoptosis, accompanied by an interstitial inflammatory cell infiltrate. In this study, we show that iNos-positive proinflammatory (M1) macrophages are recruited into the kidney in the first 48 hours after ischemia/reperfusion injury, whereas arginase 1- and mannose receptor-positive, noninflammatory (M2) macrophages predominate at later time points. Furthermore, depletion of macrophages before ischemia/reperfusion diminishes kidney injury, whereas depletion at 3 to 5 days after injury slows tubular cell proliferation and repair. Infusion of Ifnγ-stimulated, bone marrow-derived macrophages into macrophage-depleted mice at the time of kidney reperfusion restored injury to the level seen without macrophage depletion, suggesting that proinflammatory macrophages worsen kidney damage. In contrast, the appearance of macrophages with the M2 phenotype correlated with the proliferative phase of kidney repair. In vitro studies showed that IFNγ-stimulated, proinflammatory macrophages begin to express markers of M2 macrophages when cocultured with renal tubular cells. Moreover, IL-4-stimulated macrophages with an M2 phenotype, but not IFNγ-stimulated proinflammatory macrophages, promoted renal tubular cell proliferation. Finally, tracking fluorescently labeled, IFNγ-stimulated macrophages that were injected after injury showed that inflammatory macrophages can switch to an M2 phenotype in the kidney at the onset of kidney repair. Taken together, these studies show that macrophages undergo a switch from a proinflammatory to a trophic phenotype that supports the transition from tubule injury to tubule repair.     

Adult stem cells in renal injury and repair

There has been considerable focus on the ability of bone marrow-derived cells to differentiate into non-haematopoietic cells of various tissue lineages, including cells of the kidney. This growing evidence has led to a reconsideration of the source of cells contributing to renal repair following injury. The kidney has an inherent ability for recovery and regeneration following acute damage. It is thought that dedifferentiation of glomerular and tubular cells to a more embryonic/mesenchymal phenotype represent key processes for recovery in response to damage. However, there has been much contention as to the source of regenerating renal cells. The present review focuses on new aspects of the plasticity of intrinsic renal cells and their role in renal remodelling and scarring. Growing support also suggests that bone marrow-derived cells have the ability to contribute to structural and functional repair following acute renal failure. Evidence for bone marrow cell engraftment in the repairing kidney leading to incorporation into a variety of tissue types is discussed. Because cell death and fibrosis is a common end-point in a variety of acute and chronic renal nephropathies, the paradigm of stem cell plasticity may have important implications in the cellular and pathological mechanisms of renal injury and repair. A better understanding of the processes controlling extra-renal cell engraftment and intrinsic renal cell differentiation may provide important clues for the development of new cell-based therapies in the field of renal reparative medicine.     

Blockage of JAK/STAT signalling attenuates renal ischaemia-reperfusion injury in rat.

BACKGROUND: JAK/STAT signalling is one of the major pathways for cytokine signal transduction. However, the role of JAK/STAT in renal ischaemia/reperfusion (I/R) injury is not clear. The present study investigated the protection against renal I/R injury by in vivo inhibition of JAK2 activation. METHODS: Rats subjected to renal I/R were either treated with daily intraperitoneal injection of selective JAK2 inhibitor tyrphostin AG490 (10 mg/kg) or vehicle alone starting 4 h before, immediately after or until 3 h after I/R. Renal function, histology, infiltration of macrophages, apoptosis, expression of chemokines and adhesion molecules were assessed. RESULTS: AG490 treatment significantly inhibited the phosphorylation of JAK2 and its downstream molecule STAT1 and STAT3. Rats pretreated with AG490 exhibited improved renal function, attenuated histological lesions and reduced apoptosis of tubular epithelial cells. AG490 significantly inhibited renal expression of MCP-1 and ICAM-1 mRNA, as well as the expression of ICAM-1 protein, accompanied by decreased macrophage accumulation in the kidney. Immediate post-ischaemic treatment of AG490 also significantly ameliorated renal injury. However, delayed post-ischaemic treatment until 3 h after I/R failed to attenuate renal damage. CONCLUSIONS: This study demonstrated the involvement of JAK/STAT signalling in the pathogenesis of renal I/R injury, suggesting that JAK/STAT pathway may serve as a potential target for early intervention in ischaemic acute renal failure.     

Determinants of tubular bone marrow-derived cell engraftment after renal ischemia/reperfusion in rats

BACKGROUND: Ischemia/reperfusion (I/R) injury is a major cause of acute renal failure (ARF). ARF is reversible, due to an innate regenerative process, which is thought to depend partly on bone marrow-derived progenitor cells. The significance of these cells in the repair process has been questioned in view of their relatively low frequency. Here, we hypothesize that the severity of renal damage and the postischemic recovery time are determinants of tubular bone marrow-derived cell (BMDC) engraftment. METHODS: We used a model of unilateral renal I/R in F344 rats reconstituted with R26-human placental alkaline phosphatase (hPAP) transgenic bone marrow, in which we quantified and characterized tubular BMDC engraftment with increasing severity of damage and in time. RESULTS: After I/R injury, BMDC engrafted the tubular epithelium and acquired an epithelial phenotype. Tubular epithelial BMDC engraftment increased with longer ischemic time, indicating that tubular epithelial BMDC engraftment increases with the severity of damage. The number of circulating progenitor cells doubled early after I/R injury and was followed by a transient increase in tubular epithelial BMDC engraftment. The latter positively correlated with morphological recovery of the kidney over time. CONCLUSION. The extent of tubular BMDC engraftment depends on the severity of renal damage and follows a distinct time course after I/R injury. Therefore, the severity of damage and time course need to be taken into account when interpreting data on the role of tubular BMDC engraftment in renal repair after I/R injury.     

Hypoxia-inducible factor prolyl hydroxylase inhibitor roxadustat (FG-4592) protects against renal ischemia/reperfusion injury by inhibiting inflammation

Hypoxia-induced inflammation is the critical pathological feature of acute kidney injury (AKI). Activation of hypoxia-inducible factor (HIF) signaling is considered as a central mechanism of body adapting to hypoxia. Hypoxia-inducible factor prolyl hydroxylase inhibitor FG-4592 (Roxadustat) is a first-in-class HIF stabilizer for the treatment of patients with renal anemia. The current study aimed to investigate whether FG-4592 could protect against ischemia/reperfusion (I/R)-induced kidney injury via inhibiting inflammation. Here, efficacy of FG-4592 was evaluated in a mice model of I/R-induced AKI. Interestingly, improved renal function and renal tubular injuries, combined with reduced kidney injury molecule-1 were observed in the mice with FG-4592 administration. Meanwhile, inflammation responses in FG-4592-treated mice were also strikingly attenuated, as evidenced by the decreased infiltration of macrophages and neutrophils and down-regulated expression of inflammatory cytokines. In vitro, FG-4592 treatment significantly protected the tubular epithelial cells against hypoxia-induced injury, with suppressed inflammation and cell injuries. In summary, FG-4592 treatment could protect against the I/R-induced kidney injury possibly through diminishing tubular cells injuries and suppression of sequence inflammatory responses. Thus, our findings definitely offered a clinical potential approach in treating AKI.     

MicroRNA-24 Antagonism Prevents Renal Ischemia Reperfusion Injury

Ischemia-reperfusion (I/R) injury of the kidney is a major cause of AKI. MicroRNAs (miRs) are powerful regulators of various diseases. We investigated the role of apoptosis-associated miR-24 in renal I/R injury. miR-24 was upregulated in the kidney after I/R injury of mice and in patients after kidney transplantation. Cell-sorting experiments revealed a specific miR-24 enrichment in renal endothelial and tubular epithelial cells after I/R induction. In vitro, anoxia/hypoxia induced an enrichment of miR-24 in endothelial and tubular epithelial cells. Transient overexpression of miR-24 alone induced apoptosis and altered functional parameters in these cells, whereas silencing of miR-24 ameliorated apoptotic responses and rescued functional parameters in hypoxic conditions. miR-24 effects were mediated through regulation of H2A histone family, member X, and heme oxygenase 1, which were experimentally validated as direct miR-24 targets through luciferase reporter assays. In vitro, adenoviral overexpression of miR-24 targets lacking miR-24 binding sites along with miR-24 precursors rescued various functional parameters in endothelial and tubular epithelial cells. In vivo, silencing of miR-24 in mice before I/R injury resulted in a significant improvement in survival and kidney function, a reduction of apoptosis, improved histologic tubular epithelial injury, and less infiltration of inflammatory cells. miR-24 also regulated heme oxygenase 1 and H2A histone family, member X, in vivo. Overall, these results indicate miR-24 promotes renal ischemic injury by stimulating apoptosis in endothelial and tubular epithelial cell. Therefore, miR-24 inhibition may be a promising future therapeutic option in the treatment of patients with ischemic AKI.     

Differential Ly6C Expression after Renal Ischemia-Reperfusion Identifies Unique Macrophage Populations

Macrophages are a heterogeneous cell type implicated in injury, repair, and fibrosis after AKI, but the macrophage population associated with each phase is unclear. In this study, we used a renal bilateral ischemia-reperfusion injury mouse model to identify unique monocyte/macrophage populations by differential expression of Ly6C in CD11b⁺ cells and to define the function of these cells in the pathophysiology of disease on the basis of microarray gene signatures and reduction strategies. Macrophage populations were isolated from kidney homogenates by fluorescence-activated cell sorting for whole genome microarray analysis. The CD11b⁺/Ly6C^high population associated with the onset of renal injury and increase in proinflammatory cytokines, whereas the CD11b⁺/Ly6C^intermediate population peaked during kidney repair. The CD11b⁺/Ly6C^low population emerged with developing renal fibrosis. Principal component and hierarchical cluster analyses identified gene signatures unique to each population. The CD11b⁺/Ly6C^intermediate population had a distinct phenotype of wound healing, confirmed by results of studies inhibiting the macrophage colony-stimulating factor 1 receptor,whereas the CD11b⁺/Ly6C^low population had a profibrotic phenotype. All populations, including the CD11b⁺/Ly6C^high population, carried differential inflammatory signatures. The expression of M2-specific markers was detected in both the CD11b⁺/Ly6C^intermediate and CD11b⁺/Ly6C^low populations, suggesting these in vivo populations do not fit into the traditional classifications defined by in vitro systems. Results of this study in a renal ischemia-reperfusion injury model allow phenotype and function to be assigned to CD11b⁺/Ly6C⁺ monocyte/macrophage populations in the pathophysiology of disease after AKI.     

The Macrophage Mediates the Renoprotective Effects of Endotoxin Preconditioning

Preconditioning is a preventative approach, whereby minimized insults generate protection against subsequent larger exposures to the same or even different insults. In immune cells, endotoxin preconditioning downregulates the inflammatory response and yet, preserves the ability to contain infections. However, the protective mechanisms of preconditioning at the tissue level in organs such as the kidney remain poorly understood. Here, we show that endotoxin preconditioning confers renal epithelial protection in various models of sepsis in vivo. We also tested the hypothesis that this protection results from direct interactions between the preconditioning dose of endotoxin and the renal tubules. This hypothesis is on the basis of our previous findings that endotoxin toxicity to nonpreconditioned renal tubules was direct and independent of immune cells. Notably, we found that tubular protection after preconditioning has an absolute requirement for CD14-expressing myeloid cells and particularly, macrophages. Additionally, an intact macrophage CD14-TRIF signaling pathway was essential for tubular protection. The preconditioned state was characterized by increased macrophage number and trafficking within the kidney as well as clustering of macrophages around S1 proximal tubules. These macrophages exhibited increased M2 polarization and upregulation of redox and iron-handling molecules. In renal tubules, preconditioning prevented peroxisomal damage and abolished oxidative stress and injury to S2 and S3 tubules. In summary, these data suggest that macrophages are essential mediators of endotoxin preconditioning and required for renal tissue protection. Preconditioning is, therefore, an attractive model to investigate novel protective pathways for the prevention and treatment of sepsis.     

IL-25 Elicits Innate Lymphoid Cells and Multipotent Progenitor Type 2 Cells That Reduce Renal Ischemic/Reperfusion Injury

IL-25 is an important immune regulator that can promote Th2 immune response-dependent immunity, inflammation, and tissue repair in asthma, intestinal infection, and autoimmune diseases. In this study, we examined the effects of IL-25 in renal ischemic/reperfusion injury (IRI). Treating IRI mice with IL-25 significantly improved renal function and reduced renal injury. Furthermore, IL-25 treatment increased the levels of IL-4, IL-5, and IL-13 in serum and kidney and promoted induction of alternatively activated (M2) macrophages in kidney. Notably, IL-25 treatment also increased the frequency of type 2 innate lymphoid cells (ILC2s) and multipotent progenitor type 2 (MPP^type2) cells in kidney. IL-25–responsive ILC2 and MPP^type2 cells produced greater amounts of Th2 cytokines that associated with the induction of M2 macrophages and suppression of classically activated (M1) macrophages in vitro. Finally, adoptive transfer of ILC2s or MPP^type2 cells not only reduced renal functional and histologic injury in IRI mice but also induced M2 macrophages in kidney. In conclusion, our data identify a mechanism whereby IL-25-elicited ILC2 and MPP^type2 cells regulate macrophage phenotype in kidney and prevent renal IRI.     

Regulatory effects of dermal papillary pluripotent stem cells on polarization of macrophages from M1 to M2 phenotype in vitro

The M1:M2 macrophage ratio is important for spinal cord injury (SCI) repair. Bone marrow mesenchymal stem cells (BMSCs) can alter macrophage activation, promoting M1 to M2 macrophage conversion and SCI repair; however, clinical BMSC applications have limitations. Previously, we found DPCs to be superior to BMSCs in promoting tissue repair after SCI, which we hypothesized to be mediated by M1 to M2 macrophage conversion. We investigated the regulatory effect of DPCs on M1/M2 macrophage polarization. Dermal papilla cells (DPCs) were isolated from rat vibrissae and characterized. Bone marrow-derived macrophages (BMDMs) were isolated and identified based on specific marker expression, and stimulated to differentiate into M1 macrophages with GM-CSF, IFN-γ, and LPS. These cells were co-cultured with DPCs to evaluate the effect on macrophage differentiation. DPCs expressed dermal papillae-specific markers, including ALP and Sox2, had MSC-expression patterns like those of BMSCs, and were capable of multi-differentiation. BMDMs expressed ANAE and CD68. Three days after induction, differentiated cells exhibited morphology typical of M1-like macrophages and expressed the macrophage marker CD68 and the M1 macrophage markers iNOS, but lacked expression of the M2 macrophage marker CD206. Co-culture with DPCs resulted in a shift to anti-inflammatory M2-like macrophage differentiation, characterized by morphological changes typical of M2 macrophages, downregulation of the characteristic cytokine TNF-α and the proportion of iNOS⁺ cells, and upregulation of the characteristic cytokine IL-10 and the cell-surface marker CD206. The number of CD206-expressing M2 macrophages also increased. These findings demonstrate that DPCs reprogram macrophages to an anti-inflammatory M2 phenotype, which could improve adverse inflammatory microenvironments and promote tissue repair. Thus, DPCs may be an interesting alternative cell source and merit further investigation in applications for SCI therapy.     

Inflammation-Induced IL-6 Functions as a Natural Brake on Macrophages and Limits GN

IL-6 can mediate proinflammatory effects, and IL-6 receptor (IL-6R) blockade as a treatment for inflammatory diseases has entered clinical practice. However, opposing effects of IL-6 have been observed in models of GN. Although IL-6 is proinflammatory in murine lupus nephritis, protective effects have been observed for IL-6 in the nephrotoxic nephritis (NTN) model of acute crescentic GN. In light of the potential dangers of IL-6–directed treatment, we studied the mechanisms underlying the contradictory findings in GN. IL-6 can signal through the membrane-bound IL-6R, which is expressed only on hepatocytes and certain leukocytes (classic), or through the soluble IL-6R, which binds the ubiquitously expressed gp130 (alternative). Preemptive treatment of mice with anti-IL-6R or anti-IL-6 worsened NTN, whereas selective blockade of alternative IL-6 signaling by the fusion protein sgp130Fc did not. FACS analysis of mouse spleen cells revealed proinflammatory macrophages express the highest levels of IL-6Rα, and in vitro treatment with IL-6 blocked macrophage proliferation. Furthermore, proinflammatory macrophages were expanded during inflammation in IL-6^−/− mice. Late application of anti-IL-6 after establishment of adaptive nephritogenic immunity was sufficient to aggravate NTN within 2.5 days, a period when macrophages are active. Finally, NTN was aggravated in mice with macrophage-specific impairment of IL-6 classic signaling, coincident with enhanced macrophage proliferation and accumulation in the kidney. Our data thus reveal a novel mechanism in which IL-6–mediated dampening of macrophage activation protects tissues from overshooting immune responses. This finding has important implications for potential IL-6–directed therapies and supports the careful choice of recipient patients and timing.     

Sonic Hedgehog Is a Novel Tubule-Derived Growth Factor for Interstitial Fibroblasts after Kidney Injury

Tubular epithelium constitutes the majority of the renal parenchyma and is the primary target of various kidney injuries. However, how the injured tubules drive interstitial fibroblast activation and proliferation remains poorly understood. Here, we investigated the role of sonic hedgehog (Shh), a secreted extracellular signaling protein, in fibroblast proliferation. Shh was induced in renal tubular epithelia in animal models of CKD induced by ischemia/reperfusion injury (IRI), adriamycin, or renal mass ablation, and in renal tubules of kidney biopsy specimens from CKD patients with different etiologies. Using Gli1-CreER^T2 reporter mice, we identified interstitial fibroblasts as the principal targets of renal Shh signaling in vivo. In vitro, incubation with Shh promoted normal rat kidney fibroblast proliferation, which was assessed by cell counting, MTT assay, and BrdU incorporation assay, and stimulated the induction of numerous proliferation-related genes. However, Shh had no effect on the proliferation of renal tubular epithelial cells. In vivo, overexpression of Shh promoted fibroblast expansion and aggravated kidney fibrotic lesions after IRI. Correspondingly, blockade of Shh signaling by cyclopamine, a small molecule inhibitor of Smoothened, inhibited fibroblast proliferation, reduced myofibroblast accumulation, and attenuated renal fibrosis. These studies identify Shh as a novel, specific, and potent tubule-derived growth factor that promotes interstitial fibroblast proliferation and activation. Our data also suggest that blockade of Shh signaling is a plausible strategy for therapeutic intervention of renal fibrosis.     

Cholecystokinin plays a novel protective role in diabetic kidney through anti-inflammatory actions on macrophage: anti-inflammatory effect of cholecystokinin

Inflammatory process is involved in the pathogenesis of diabetic nephropathy. In this article, we show that cholecystokinin (CCK) is expressed in the kidney and exerts renoprotective effects through its anti-inflammatory actions. DNA microarray showed that CCK was upregulated in the kidney of diabetic wild-type (WT) mice but not in diabetic intracellular adhesion molecule-1 knockout mice. We induced diabetes in CCK-1 receptor (CCK-1R) and CCK-2R double-knockout (CCK-1R(-/-),-2R(-/-)) mice, and furthermore, we performed a bone marrow transplantation study using CCK-1R(-/-) mice to determine the role of CCK-1R on macrophages in the diabetic kidney. Diabetic CCK-1R(-/-),-2R(-/-) mice revealed enhanced albuminuria and inflammation in the kidney compared with diabetic WT mice. In addition, diabetic WT mice with CCK-1R(-/-) bone marrow-derived cells developed more albuminuria than diabetic CCK-1R(-/-) mice with WT bone marrow-derived cells. Administration of sulfated cholecystokinin octapeptide (CCK-8S) ameliorated albuminuria, podocyte loss, expression of proinflammatory genes, and infiltration of macrophages in the kidneys of diabetic rats. Furthermore, CCK-8S inhibited both expression of tumor necrosis factor-α and chemotaxis in cultured THP-1 cells. These results suggest that CCK suppresses the activation of macrophage and expression of proinflammatory genes in diabetic kidney. Our findings may provide a novel strategy of therapy for the early stage of diabetic nephropathy.     

Renal microenvironments and macrophage phenotypes determine progression or resolution of renal inflammation and fibrosis

Chronic kidney disease involves renal inflammation, interstitial fibrosis, and tubular and vascular atrophy. Macrophages seem to foster all of these histomorphological abnormalities, but their specific contributions remain controversial. Recruited monocytes differentiate into different tissue macrophage phenotypes, but current classifications are largely based on in vitro studies that do not adequately mirror tissue environments in vivo. To overcome this limitation, we propose to classify tissue macrophages according to their predominant roles in the phases of wound healing tissue environments, that is, inflammation, epithelial healing, mesenchymal healing, and fibrolysis. In this review, we discuss the evidence on respective macrophage phenotypes in renal pathology. This view sheds light on several aspects of renal remodeling in kidney disease: (1) renal infection or cell necrosis induces proinflammatory 'M1' macrophages that exacerbate renal cell damage, (2) uptake of apoptotic cells induces anti-inflammatory 'M2c/suppressor' macrophages that promote epithelial and vascular repair, (3) insufficient vascular and epithelial healing despite abundant growth factor secretion promotes profibrotic 'M2a/wound healing' macrophages that accelerate fibrogenesis, and (4) theoretically, fibrolytic macrophages should exist and await investigation.     

Kidney tubular epithelium is restored without replacement with bone marrow-derived cells during repair after ischemic injury

The kidney has the ability to restore the structural and functional integrity of the proximal tubule, which undergoes extensive epithelial cell death after prolonged exposure to ischemia. In order to study the role that adult bone marrow-derived stem cells might play in kidney remodeling after injury, we employed a murine model of ischemia/reperfusion (I/R) injury in which the degree of injury, dysfunction, repair, tubular cell proliferation and functional recovery have been characterized [Park KM, et al, J Biol Chem 276:11870-11876, 2001]. We generated chimeric mice using marrow from mice expressing the bacterial LacZ gene, or the enhanced green fluorescence protein (eGFP) gene, or from male mice transplanted into female mice. The establishment of chimerism was confirmed at 6 weeks following transplantation in each case. I/R injury was induced in chimeric mice by occluding the renal arteries and veins with microaneurysm clamps for 30 minutes. After functional recovery in the eGFP chimeras, although there were many interstitial cells, no tubular cells were derived from bone marrow cells. In the bacterial beta-galactosidase (beta-gal) chimeric mice we found evidence of mammalian (endogenous) beta-gal by 5-bomo-4-chloro-3-indolyl-beta-D-galactopyranoside (X-gal) staining, but not bacterial beta-gal in tubule cells. Detection of the Y chromosome by fluorescence in situ hybridization (FISH) in the postischemic kidneys of gender-mismatched chimeras revealed Y chromosome positivity only in the nuclei of interstitial cells, when scrutinized by deconvolution microscopy. In our model of I/R injury there was a large amount of proliferation of surviving, injured tubular cells indicating that the injured tubule is repopulated by daughter cells of surviving tubular cells. Analysis of the phenotype of interstitial and vascular cells following I/R injury revealed small numbers of peritubular endothelial cells to be derived from bone marrow cells that may serve in the repair process.     

IL-18 contributes to renal damage after ischemia-reperfusion

IL-18 is a proinflammatory cytokine produced by macrophages and other cell types present in the kidney during ischemia-reperfusion injury (IRI), but its role in this injury is unknown. Here, compared with wild-type mice, IL-18(-/-) mice subjected to kidney IRI demonstrated better kidney function, less tubular damage, reduced accumulation of neutrophils and macrophages, and decreased expression of proinflammatory molecules that are downstream of IL-18. For determination of the relative contributions of leukocytes and parenchymal cells to IL-18 production and subsequent kidney damage during IRI, bone marrow-chimeric mice were generated. Wild-type mice engrafted with IL-18(-/-) hemopoietic cells showed less kidney dysfunction and tubular damage than IL-18(-/-) mice engrafted with wild-type bone marrow. In vitro, macrophages produced IL-18 mRNA and protein in response to ischemia. These data suggest bone marrow-derived cells are the key contributors to IL-18-mediated effects of renal IRI. Finally, similar to IL-18(-/-) mice, pretreatment of wild-type mice with IL-18-binding protein was renoprotective in this model of IRI. In conclusion, IL-18, derived primarily from cells of bone marrow origin, contributes to the renal damage observed during IRI. IL-18-binding protein may have potential as a renoprotective therapy.