Ron receptor-dependent gene regulation of Kupffer cells during endotoxemia.

BACKGROUND: Ron receptor tyrosine kinase signaling in macrophages, including Kupffer cells and alveolar macrophages, suppresses endotoxin-induced proinflammatory cytokine/chemokine production. Further, we have also identified genes from Ron replete and Ron deplete livers that were differentially expressed during the progression of liver inflammation associated with acute liver failure in mice by microarray analyses. While important genes and signaling pathways have been identified downstream of Ron signaling during progression of inflammation by this approach, the precise role that Ron receptor plays in regulating the transcriptional landscape in macrophages, and particular in isolated Kupffer cells, has still not been investigated. METHODS: Kupffer cells were isolated from wild-type (TK+/+) and Ron tyrosine kinase deficient (TK-/-) mice. Ex vivo, the cells were treated with lipopolysaccharide (LPS) in the presence or absence of the Ron ligand, hepatocyte growth factor-like protein (HGFL). Microarray and qRT-PCR analyses were utilized to identify alterations in gene expression between genotypes. RESULTS: Microarray analyses identified genes expressed differentially in TK+/+ and TK-/- Kupffer cells basally as well as after HGFL and LPS treatment. Interestingly, our studies identified Mefv, a gene that codes for the anti-inflammatory protein pyrin, as an HGFL-stimulated Ron-dependent gene. Moreover, lipocalin 2, a proinflammatory gene, which is induced by LPS, was significantly suppressed by HGFL treatment. Microarray results were validated by qRT-PCR studies on Kupffer cells treated with LPS and HGFL. CONCLUSION: The studies herein suggest a novel mechanism whereby HGFL-induced Ron receptor activation promotes the expression of anti-inflammatory genes while inhibiting genes involved in inflammation with a net effect of diminished inflammation in macrophages.

Ron receptor signaling is protective against DSS-induced colitis in mice.

Inflammatory bowel diseases (IBD) are chronic inflammatory disorders of the intestine that result in painful and debilitating complications. Currently no cure exists for IBD, and treatments are primarily aimed at reducing inflammation to alleviate symptoms. Genome-wide linkage studies have identified the Ron receptor tyrosine kinase (TK) and its ligand, hepatocyte growth factor-like protein (HGFL), as genes highly associated with IBD. However, only scant information exists on the role of Ron or HGFL in IBD. Based on the linkage of Ron to IBD, we directly examined the biological role of Ron in colitis. Wild-type mice and mice lacking the TK signaling domain of Ron (TK-/- mice) were utilized in a well-characterized model of chronic colitis induced by cyclic exposure to dextran sulfate sodium. In this model, TK-/- mice were more susceptible to injury as judged by increased mortality compared with control mice and developed more severe colitis. Loss of Ron led to significantly reduced body weights and more aggressive clinical and histopathologies. Ron loss also resulted in a dramatic reduction in colonic epithelial cell proliferation and increased proinflammatory cytokine production, which was associated with alterations in important signaling pathways known to regulate IBD. Examination of human gene expression data further supports the contention that loss of Ron signaling is associated with IBD. In total, our studies point to important functional roles for Ron in IBD by regulating healing of the colonic epithelium and by controlling cytokine secretion.

Myeloid-specific expression of Ron receptor kinase promotes prostate tumor growth.

Ron receptor kinase (MST1R) is important in promoting epithelial tumorigenesis, but the potential contributions of its specific expression in stromal cells have not been examined. Herein, we show that the Ron receptor is expressed in mouse and human stromal cells of the prostate tumor microenvironment. To test the significance of stromal Ron expression, prostate cancer cells were orthotopically implanted into the prostates of either wild-type or Ron tyrosine kinase deficient (TK(-/-); Mst1r(-/-)) hosts. In TK(-/-) hosts, prostate cancer cell growth was significantly reduced as compared with tumor growth in TK(+/+) hosts. Prostate tumors in TK(-/-) hosts exhibited an increase in tumor cell apoptosis, macrophage infiltration and altered cytokine expression. Reciprocal bone marrow transplantation studies and myeloid cell-specific ablation of Ron showed that loss of Ron in myeloid cells is sufficient to inhibit prostate cancer cell growth. Interestingly, depletion of CD8(+) T cells, but not CD4(+) T cells, was able to restore prostate tumor growth in hosts devoid of myeloid-specific Ron expression. These studies show a critical role for the Ron receptor in the tumor microenvironment, whereby Ron loss in tumor-associated macrophages inhibits prostate cancer cell growth, at least in part, by derepressing the activity of CD8(+) T cells.

Ron receptor-dependent gene regulation in a mouse model of endotoxin-induced acute liver failure.

BACKGROUND: Prior experimentation has shown that loss of the tyrosine kinase (TK) signaling domain of the Ron receptor leads to marked hepatocyte protection in a model of lipopolysaccharide-induced acute liver failure (ALF) in D-galactosamine (GalN)-sensitized mice. The aim of this study was to identify the role of Ron in the regulation of hepatic gene expression. METHODS: Microarray analyses were performed on liver RNA isolated sequentially from wild-type (WT) and TK-/- mice during the progression of ALF. Gene array data were validated using Western and immunohistochemistry analyses as well as with ex vivo culture systems. RESULTS: At baseline, 101 genes were differentially expressed between WT and TK-/- livers, which regulate processes involved in hypoxia, proliferation, apoptosis and metabolism. One hour after ALF induction, WT livers exhibited increased cytokine expression compared to TK-/- livers, and after 4 hours, an induction of suppressor of cytokine signaling (SOCS) genes as well as JAK-STAT pathway activation were prominent in TK-/- livers compared to controls. CONCLUSION: Our studies suggest a novel hepato-protective mechanism in Ron TK-/- mice wherein increased and sustained SOCS production and JAK-STAT activation in the hepatocyte may inhibit the destructive proinflammatory milieu and promote survival factors which blunt hepatic death and the ensuing development of ALF.

Ron receptor regulates Kupffer cell-dependent cytokine production and hepatocyte survival following endotoxin exposure in mice.

UNLABELLED: Previous studies demonstrated that targeted deletion of the Ron receptor tyrosine kinase (TK) domain in mice leads to marked hepatocyte protection in a well-characterized model of lipopolysaccharide (LPS)-induced acute liver failure in D-galactosamine (GalN)-sensitized mice. Hepatocyte protection in TK-/- mice was observed despite paradoxically elevated serum levels of tumor necrosis factor alpha (TNF-α). To understand the role of Ron in the liver, purified populations of Kupffer cells and hepatocytes from wildtype (TK+/+) and TK-/- mice were studied. Utilizing quantitative reverse-transcription polymerase chain reaction (RT-PCR), we demonstrated that Ron is expressed in these cell types. Moreover, we also recapitulated the protected hepatocyte phenotype and exaggerated cytokine production observed in the TK-/- mice in vivo through the use of purified cultured cells ex vivo. We show that isolated TK-/- Kupffer cells produce increased levels of TNF-α and select cytokines compared to TK+/+ cells following LPS stimulation. We also show that conditioned media from LPS-treated TK-/- Kupffer cells was more toxic to hepatocytes than control media, suggesting the exaggerated levels of cytokines produced from the TK-/- Kupffer cells are detrimental to wildtype hepatocytes. In addition, we observed that TK-/- hepatocytes were more resistant to cell death compared to TK+/+ hepatocytes, suggesting that Ron functions in both the epithelial and inflammatory cell compartments to regulate acute liver injury. These findings were confirmed in vivo in mice with hepatocyte and macrophage cell-type-specific conditional Ron deletions. Mice with Ron loss selectively in hepatocytes exhibited less liver damage and increased survival compared to mice with Ron loss in macrophages. CONCLUSION: We dissected cell-type-specific roles for Ron such that this receptor modulates cytokine production from Kupffer cells and inhibits hepatocyte survival in response to injury.

Ron receptor deficient alveolar myeloid cells exacerbate LPS-induced acute lung injury in the murine lung.

Previous studies have shown that the Ron receptor tyrosine kinase is an important regulator of the acute lung inflammatory response induced by intranasal administration of bacterial LPS. Compared to wild-type mice, complete loss of the Ron receptor in all cell types in vivo was associated with increased lung damage as determined by histological analyses and several markers of lung injury including increases in pro-inflammatory cytokines such as TNF-α. Tumor-necrosis factor-α is a multifunctional cytokine secreted by macrophages, which plays a major role in inflammation and is a central mediator of several disease states including rheumatoid arthritis and sepsis. Based on increased TNF-α production observed in the Ron-deficient mice, we hypothesized that Ron receptor function in the inflammatory cell compartment is essential for the regulating lung injury in vivo. To test this hypothesis, we generated myeloid lineage-specific Ron-deficient mice. In this study, we report that loss of Ron signaling selectively in myeloid cells results in increased lung injury following intranasal administration of LPS as measured by increases in TNF-α production, ensuing neutrophil accumulation and increased lung histopathology. These findings corroborate the role of Ron receptor tyrosine kinase as a negative regulator of inflammation and further demonstrate the in vivo significance of Ron signaling selectively in myeloid cells as a major regulator of this response in vivo. These data authenticate Ron as a potential target in innate immunity and TNF-α-mediated pathologies.

Lymphatic ontogeny and effect of hypoplasia in developing lung.

The pulmonary lymphatic vasculature plays a vital role in maintaining fluid homeostasis required for efficient gas exchange at capillary alveolar barriers and contributes to lung fluid clearance at birth. To further understanding of pulmonary lymphatic function at birth, lineage-tracing analysis of mouse lung was used. Lineage analysis confirmed that lymphatic endothelial cells (LEC) bud from extrapulmonary lymphatics and demonstrated that LEC migrate into developing lung along precise pathways. LEC cluster first in the primary bronchovascular region then along the secondary broncho-arterial regions and along veins. Small lymphatic vessels in distal lung develop from LEC that have migrated into lung mesenchyme from the extrapulmonary lymphatics. Finally, proximal and distal lymphatics remodel to form vessels with lumens in stereotypical locations. Loss of function analysis with lung-specific expression of a secreted form of the extracellular domain of vascular endothelial growth factor receptor-3 (dnR3) caused significant embryonic pulmonary lymphatic hypoplasia with fourfold reduction in distal LEC. Lung-specific expression of dnR3 did not affect blood vascular development, overall lung organogenesis or lymphatic development in other organs. Neonatal mice with pulmonary lymphatic hypoplasia developed respiratory distress with significantly increased mortality. During the transition to air breathing, lymphatic hypoplasia adversely affected fetal lung fluid clearance as determined by wet/dry weight analysis and morphometric analysis of bronchovascular cuffing and mesenchymal thickening. Surfactant synthesis was unaffected. Together, these data demonstrate that lung lymphatics develop autonomously and that pulmonary lymphatic hypoplasia is detrimental to survival of the neonate due to impaired lung fluid clearance.

NFATc1 regulates lymphatic endothelial development.

NFATc1 transcription factor is critical for lineage selection in T-cell differentiation, cardiac valve morphogenesis and osteoclastogenesis. We identified a role for calcineurin-NFAT signaling in lymphatic development and patterning. NFATc1 was colocalized with lymphatic markers Prox-1, VEGFR-3 and podoplanin on cardinal vein as lymphatic endothelial cells (LEC) are specified and as they segregate into lymph sacs and mature lymphatics. In NFATc1 null mice, Prox-1, VEGFR-3 and podoplanin positive endothelial cells sprouted from the cardinal vein at E11.5, but poorly coalesced into lymph sacs. NFAT activation requires the phosphatase calcineurin. Embryos treated in utero with the calcineurin inhibitor cyclosporine-A showed cytoplasmic NFATc1, diminished podoplanin and FGFR-3 expression by the lymphatics and irregular patterning of the LEC sprouts coming off the jugular lymph sac, which suggests a role for calcineurin-NFAT signaling in lymphatic patterning. In a murine model of injury-induced lymphangiogenesis, NFATc1 was expressed on the neolymphatics induced by lung-specific overexpression of VEGF-A. Mice lacking the calcineurin Abeta regulatory subunit, with diminished nuclear NFAT, failed to respond to VEGF-A with increased lymphangiogenesis. In vitro, endogenous and VEGF-A-induced VEGFR-3 and podoplanin expression by human microvascular endothelial cells was reduced by siRNA to NFATc1, to levels comparable to reductions seen with siRNA to Prox-1. In reporter assays, NFATc1 activated lymphatic specific gene promoters. These results demonstrate the role of calcineurin-NFAT pathway in lymphangiogenesis and suggest that NFATc1 is the principle NFAT involved.

Lymphangiogenesis in the developing lung promoted by VEGF-A.

Understanding the basic processes of late-stage pulmonary vascular development is essential as this period corresponds to the stage when preterm infants have increased chance of survival. During this period, refinement of the gas exchange unit leads to close apposition of the capillary vasculature and airway epithelium through thinning of the mesenchyme, formation of alveolar septae and functional adaptation of endothelial cells into vessels including pulmonary lymphatics. The pulmonary lymphatic network promotes efficient gas exchange through maintaining interstitial fluid balance. Through conditional transgene regulation, we found that a modest, pathologically relevant increase in vascular endothelial growth factor A (VEGF-A) in distal lung during only the perinatal period adversely affected final refinement of the gas exchange unit. VEGF-A induction disrupted the established vascular network, increased endothelial cell number, altered endothelial ultrastructure and reduced mesenchymal thinning. In addition, VEGF-A induction caused a 3-fold increase in small vessels identified as lymphatics in distal lung. mRNA levels of lymphangiogenic factors VEGF-D/-C were unchanged, while levels of the cognate receptor VEGFR-3 increased. The responses to VEGF-A induction in the perinatal period differ from those during early lung development when endothelial migration, but not proliferation altered initial vascular patterning (Akeson, A.L., Greenberg, J.M., Cameron, J.E., Thompson, F.Y., Brooks, S.K., Wiginton, D., Whitsett, J.A., 2003. Temporal and spatial regulation of VEGF-A controls vascular patterning in the embryonic lung. Dev. Biol. 264, 443-455). The late-stage response resembles that of adult lung to VEGF-inducing stimuli including injury and disease. These data suggest that VEGF-A influences the balance between development of blood and lymphatic vasculature during lung organogenesis.