Tumor-Recruited Neutrophils and Neutrophil TIMP-Free MMP-9 Regulate Coordinately the Levels of Tumor Angiogenesis and Efficiency of Malignant Cell Intravasation
Tumor-associated neutrophils contribute to neovascularization by supplying matrix metalloproteinase-9 (MMP-9), a protease that has been genetically and biochemically linked to induction of angiogenesis. Specific roles of inflammatory neutrophils and their distinct proMMP-9 in the coordinate regulation of tumor angiogenesis and tumor cell dissemination, however, have not been addressed. We demonstrate that the primary tumors formed by highly disseminating variants of human fibrosarcoma and prostate carcinoma recruit elevated levels of infiltrating MMP-9-positive neutrophils and concomitantly exhibit enhanced levels of angiogenesis and intravasation. Specific inhibition of neutrophil influx by interleukin 8 (IL-8) neutralization resulted in the coordinated diminishment of tumor angiogenesis and intravasation, both of which were rescued by purified neutrophil proMMP-9. However, if neutrophil proMMP-9, naturally devoid of tissue inhibitor of metalloproteinases (TIMP), was delivered in complex with TIMP-1 or in a mixture with TIMP-2, the protease failed to rescue the inhibitory effects of anti-IL8 therapy, indicating that the TIMP-free status of proMMP-9 is critical for facilitating tumor angiogenesis and intravasation. Our findings directly link tumor-associated neutrophils and their TIMP-free proMMP-9 with the ability of aggressive tumor cells to induce the formation of new blood vessels that serve as conduits for tumor cell dissemination. Thus, treatment of cancers associated with neutrophil infiltration may benefit from specific targeting of neutrophil MMP-9 at early stages to prevent ensuing tumor angiogenesis and tumor metastasis.
Key Points• Acquisition of high angiogenesis-inducing capacity by human and murine macrophages requires their polarization toward the M2 phenotype.• M2-polarized macrophages shutdown their TIMP1 gene expression and initiate production of highly angiogenic TIMP-deficient proMMP-9.A proangiogenic function of tissue-infiltrating monocytes/macrophages has long been attributed to their matrix metalloproteinase-9 zymogen (proMMP-9). Herein, we evaluated the capacity of human monocytes, mature M0 macrophages, and M1-and M2-polarized macrophages to induce proMMP-9-mediated angiogenesis. Only M2 macrophages induced angiogenesis at levels comparable with highly angiogenic neutrophils previously shown to release their proMMP-9 in a unique form, free of tissue inhibitor of metalloproteinases-1 (TIMP-1). Macrophage differentiation was accompanied by induction of low-angiogenic, TIMP-1-encumbered proMMP-9. However, polarization toward the M2, but not the M1 phenotype, caused a substantial downregulation of TIMP-1 expression, resulting in production of angiogenic, TIMP-deficient proMMP-9. Correspondingly, the angiogenic potency of M2 proMMP-9 was lost after its complexing with TIMP-1, whereas TIMP-1 silencing in M0/M1 macrophages rendered them both angiogenic. Similar to human cells, murine bone marrow-derived M2 macrophages also shut down their TIMP-1 expression and produced proMMP-9 unencumbered by TIMP-1. Providing proof that angiogenic capacity of murine M2 macrophages depended on their TIMP-free proMMP-9, Mmp9-null M2 macrophages were nonangiogenic, although their TIMP-1 was severely downregulated. Our study provides a unifying molecular mechanism for high angiogenic capacity of TIMP-free proMMP-9 that would be uniquely produced in a pathophysiological microenvironment by influxing neutrophils and/or M2 polarized macrophages. (Blood. 2013;122(25):4054-4067) Introduction A strong link has been established between infiltrating leukocytes and various pathophysiological conditions involving tissue remodeling and transformation. [1][2][3] The leukocyte infiltrate can be represented by hematopoietic cells of different lineages, including lymphocytes, granulocytes, and macrophages. Tumor-associated macrophages (TAMs) have been implicated in cancer progression, 4,5 and high numbers of TAMs have been linked to poor prognosis in certain human malignancies. 6,7 A remarkable plasticity of macrophages allows them to acquire functionally distinct phenotypes. 8,9 Two major alternative phenotypes, namely M1 and M2, have been ascribed to tumor-suppressing and tumor-promoting TAMs, respectively, although a spectrum of activation states has been demonstrated in several settings. [10][11][12][13] In general, M1 macrophages are associated with an induction of strong immune response and tumoricidal activity. In contrast, M2 macrophages appear to suppress immune surveillance and enhance neovascularization.Macrophage-induced angiogenesis involves an angiogenic switch, 14,15 which is triggered by proteolytic release of directacting angiogenic ...
Neutrophil MMP-9 Proenzyme, Unencumbered by TIMP-1, Undergoes Efficient Activation in Vivo and Catalytically Induces Angiogenesis via a Basic Fibroblast Growth Factor (FGF-2)/FGFR-2 Pathway
The structural and catalytic requirements for neutrophil MMP-9 proenzyme (proMMP-9) to induce angiogenesis were investigated using a quantitative angiogenesis model based on grafting of collagen onplants onto the chorioallantoic membrane of chick embryos. Both physiological activation of neutrophil proMMP-9 and proteolytic activity of the generated MMP-9 enzyme were critically dependent on the tissue inhibitor of metalloproteinase (TIMP)-free status of the zymogen. The presence of an intact active site and hemopexin domain were required for full angiogenesis-inducing activity of the MMP-9 enzyme. Timed additions of TIMP-1 to the onplants containing TIMP-free neutrophil proMMP-9 indicated that in vivo activation of the zymogen occurred during the first 24 h after grafting. Within the onplant tissue, MMP-9 activation was accompanied by proteolytic modifications of fibrillar collagen and an influx of host proteins, the rate of which depended on the TIMP-free status of the zymogen. By quantifying the levels of host angiogenic factors, we demonstrated that basic fibroblast growth factor (FGF-2) was a major cytokine becoming bioavailable in the onplant tissue undergoing a neutrophil proMMP-9-mediated angiogenic switch. Inhibition of angiogenesis with specific function-blocking antibodies further indicated an involvement of a FGF-2/FGFR-2 pathway in neutrophil proMMP-9-induced angiogenesis. The enhanced angiogenesis catalyzed by neutrophil MMP-9 appears to evoke also a localized, low threshold level vascular endothelial growth factor (VEGF)/VEGFR-2 pathway, likely functioning in the formation and/or stabilization of blood vessels. That neutrophil proMMP-9, unencumbered by TIMP-1, directly mediates FGF-2-dependent angiogenesis was also demonstrated in our quantitative mouse angiogenesis model employing subcutaneous collagen implants, thus implicating the novel TIMP-free MMP-9/FGF-2/FGFR-2 pathway in proMMP-9-induced angiogenesis in a mammalian setting.Gelatinase B, or matrix metalloproteinase-9 (MMP-9), 3 has been functionally and genetically linked to a number of critical biological functions, including wound healing, inflammation, tumor progression, vascular tissue remodeling, and angiogenesis (1-6). In particular, vascular tissue remodeling and angiogenesis, related histologically and mechanistically, have received a good deal of attention as MMP-9 has been reported to be a major trigger of the angiogenic switch (7). Phenotypic rescue of vasculogenic and angiogenic defects manifested in MMP-9 null mice has suggested a functional link between MMP-9 and the formation, structure, and remodeling of new blood vessels (7-15). The direct contribution of MMP-9 to angiogenesis and vascular performance is thought to involve catalytic activity of the enzyme resulting either in the cleavage of ECM components such as native and denatured collagens (16 -18) and processing of various cytokines and chemokines such as CXCL5, CXCL6, and CXCL8 (interleukin-8) (19,20) or release of angiogenic growth factors such as VEGF (7,12,15,(21)(22...
The VEGF-induced transcriptional response comprises gene clusters at the crossroad of angiogenesis and inflammation
VEGF-A is the major trigger of vasculogenesis and physiologic angiogenesis. We have investigated to which extent the gene repertoire induced by VEGF-A in endothelial cells is distinct from that of other growth factors and inflammatory cytokines. Genes upregulated in human umbilical vein endothelial cells treated with VEGF, EGF or IL-1 were compared by microarray analysis and clusters characteristic for individual or combinations of inducers were defined. VEGF-A upregulated in comparison to EGF a five-fold larger gene repertoire, which surprisingly overlapped to 60% with the inflammatory repertoire of IL-1. As shown by real-time RT-PCR for selected genes, VEGF-induction was mostly mediated by VEGF receptor-2 and the capacity of VEGF-A to induce genes in common with IL-1 largely depended on activation of the calcineurin/NFAT pathway, since cyclosporin A inhibited this induction. Another angiogenic growth factor, bFGF, did not share a comparable induction of inflammatory genes, but partially induced a small group of genes in common with VEGF-A, which were not regulated by EGF. Thus, the data display that VEGF-A induces a distinct gene repertoire, which, contrasting with other growth factors such as EGF or bFGF, includes an inherent inflammatory component possibly contributing to the cross-regulation of angiogenesis and inflammation as further indicated by the VEGF-mediated induction of leukocyte adhesion. Furthermore, a small group of genes selectively induced by VEGF-A with potential importance for angiogenesis is defined.
A novel cluster of lectin-like receptor genes expressed in monocytic, dendritic and endothelial cells maps close to the NK receptor genes in the human NK gene complex
The NK gene complex is a region on human chromosome 12 containing several families of lectin‐like genes including the CD94 and NKG2 NK receptor genes. We report here that the region telomeric of CD94 contains in addition to the LOX‐1 gene the novel human DECTIN‐1 and the CLEC‐1 and CLEC‐2 genes within about 100 kb. Sequence similarities and chromosomal arrangement suggest that these genes form a separate subfamily of lectin‐like genes within the NK gene complex. DECTIN‐1 is selectively expressed in dendritic cells and to a lowerextent in monocytes and macrophages. mRNA forms with and without a stalk exon are observed. During functional maturation of dendritic cells the level of DECTIN‐1 mRNA is down‐regulated several‐fold. CLEC‐1 is found to be not only expressed in dendritic cells, but also in endothelial cells and in the latter aspect resembles the LOX‐1 gene. Whereas recombinant full‐length DECTIN‐1 and LOX‐1 are transported to the cell surface, CLEC‐1 proteins accumulate in perinuclear compartments. We propose that this family of lectin‐like genes encodes receptors with important immune and/or scavenger functions in monocytic, dendritic and endothelial cells.
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