Significance Tumor-associated macrophages (TAMs) are cells of our innate immune system that have been associated with poor prognosis in many types of cancers. When polarized toward the anti-inflammatory state, TAMs promote immune evasion and angiogenesis, thereby driving tumor growth. Using a peptide library selection strategy, we identified a sequence, called M2pep, that preferentially binds to anti-inflammatory murine macrophages. We then used M2pep to carry a proapoptotic peptide to TAMs by i.v. delivery and demonstrated that selective reduction of TAMs resulted in improved survival in tumor-bearing mice. These results suggest that a molecular-targeting approach for TAM depletion is a promising adjunct strategy to add to the arsenal of anticancer therapies.
SUMMARY Inflammatory activation of myeloid cells is accompanied by increased glycolysis, which is required for the surge in cytokine production. Although in vitro studies suggest that increased macrophage glucose metabolism is sufficient for cytokine induction, the pro-inflammatory effects of increased myeloid cell glucose flux in vivo and the impact on atherosclerosis, a major complication of diabetes, are unknown. We therefore tested the hypothesis that increased glucose uptake in myeloid cells stimulates cytokine production and atherosclerosis. Overexpression of the glucose transporter GLUT1 in myeloid cells caused increased glycolysis and flux through the pentose phosphate pathway, but did not induce cytokines. Moreover, myeloid cell-specific overexpression of GLUT1 in LDL receptor-deficient mice was ineffective in promoting atherosclerosis. Thus, increased glucose flux is insufficient for inflammatory myeloid cell activation and atherogenesis. If glucose promotes atherosclerosis by increasing cellular glucose flux, myeloid cells do not appear to be the key targets.
Platelet-derived growth factor (PDGF) is
Osteopontin (OPN) is highly expressed by macrophages and plays a key role in the pathology of several chronic inflammatory diseases including atherosclerosis and the foreign body reaction. However, the molecular mechanism behind OPN regulation of macrophage functions is not well understood. OPN is a secreted molecule and interacts with several integrins via two domains: the RGD sequence binding to α(v) -containing integrins, and the SLAYGLR sequence binding to α(4) β(1), α(4) β(7), and α(9) β(1) integrins. Here we determined the role of OPN in macrophage survival, chemotaxis, and activation state. For survival studies, OPN treated-bone marrow derived macrophages (BMDMs) were challenged with growth factor withdrawal and neutralizing integrin antibodies. We found that survival in BMDMs is mediated primarily through the α(4) integrin. In chemotaxis studies, we observed that migration to OPN was blocked by neutralizing α(4) and α(9) integrin antibodies. Further, OPN did not affect macrophage activation as measured by IL-12 production. Finally, the relative contributions of the RGD and the SLAYGLR functional domains of OPN to leukocyte recruitment were evaluated in an in vivo model. We generated chimeric mice expressing mutated forms of OPN in myeloid-derived leukocytes, and found that the SLAYGLR functional domain of OPN, but not the RGD, mediates macrophage accumulation in response to thioglycollate-elicited peritonitis. Collectively, these data indicate that α(4) and α(9) integrins interacting with OPN via the SLAYGLR domain play a key role in macrophage biology by regulating migration, survival, and accumulation.
Rationale Apoptotic cell phagocytosis (efferocytosis) is mediated by specific receptors and is essential for resolution of inflammation. In chronic inflammation, apoptotic cell clearance is dysfunctional and soluble levels of several apoptotic cell receptors are elevated. Reports have identified proteolytic cleavage as a mechanism capable of releasing soluble apoptotic cell receptors, but the functional implications of their proteolysis are unclear. Objective To test the hypothesis that ADAM17-mediated cleavage of apoptotic cell receptors limits efferocytosis in vivo. Methods and Results In vivo comparison of macrophage efferocytosis in wildtype and Adam17-null hematopoietic chimeras demonstrates that ADAM17 deficiency leads to a 60% increase in efferocytosis and an enhanced anti-inflammatory phenotype in a model of peritonitis. In vitro uptake of phosphatidylserine liposomes identifies the dual-pass apoptotic cell receptor CD36 as a major contributor to enhanced efferocytosis, and CD36 surface levels are elevated on macrophages from Adam17-null mice. Further, temporal elevation of CD36 expression with inflammation may also contribute to its impact. Soluble CD36 from macrophage-conditioned media is comprised of two species based on Western blotting, and mass spectrometry identifies three N-terminal peptides, which represent probable cleavage sites. Levels of soluble CD36 are decreased in Adam17-null conditioned media, providing evidence for involvement of ADAM17 in CD36 cleavage. Importantly, enhanced efferocytosis in vivo by macrophages lacking ADAM17 is CD36 dependent and accelerates macrophage clearance from the peritoneum, thus promoting resolution of inflammation and highlighting the impact of increased apoptotic cell uptake. Conclusions Our studies demonstrate the importance of ADAM17-mediated proteolysis for in vivo efferocytosis regulation, and suggest a possible mechanistic link between chronic inflammation and defective efferocytosis.
TNF-␣-converting enzyme (TACE, herein denoted as Adam17) proteolytically sheds several cell-surface inflammatory proteins, but the physiologic importance of the cleavage of these substrates from leukocyte subsets during inflammation is incompletely understood. In this study, we show that Adam17-null neutrophils have a 2-fold advantage in their initial recruitment during thioglycollate-induced peritonitis, and they roll slower and adhere more readily in the cremaster model than wild-type neutrophils. Although CD44 and ICAM-1 are both in vitro substrates of Adam17, their surface levels are not altered on Adam17-null neutrophils. In contrast, L-selectin levels are elevated up to 10-fold in Adam17-null circulating neutrophils, and their accelerated peritoneal influx, slower rolling, and increased adhesion in the cremaster muscle are dependent on L-selectin. Analysis of mixed chimeras shows that enhanced L-selectin levels and accelerated influx were both cell-intrinsic properties of neutrophils lacking Adam17. In contrast, Adam17-null monocytes display no acceleration of infiltration into the peritoneum in spite of elevated L-selectin surface levels, and their peritoneal influx was independent of L-selectin. Therefore, our data demonstrate substrate and myeloid cell-type specificity of Adam17-mediated cleavage of its substrates, and show that neutrophils and monocytes use distinct mechanisms for infiltration of tissues. IntroductionRecruitment of specific subsets of leukocytes to sites of injury is a complex, multistep process that includes leukocyte tethering and rolling, activation and firm adhesion, and transmigration, 1,2 as well as more recently elaborated steps of slow rolling, adhesion strengthening, intraluminal crawling, paracellular and transcellular migration, and migration through the basement membrane into the tissue. 3 This process can be characterized as a sequential adhesion cascade that is mediated by quantitative and qualitative changes of several distinct surface receptors on leukocytes and the endothelium. Whereas much has been learned about the mechanisms involved in leukocyte adhesion to endothelial cells, less is known about the molecules responsible for de-adhesion and the transition between the sequential steps. However, transendothelial migration is a very rapid event, and it only takes minutes to reach the subendothelial basement membrane once a leukocyte sticks to the endothelium. 4 A useful method to rapidly modulate leukocyte-endothelial interactions is cell-surface proteolysis, a mechanism that can instantly alter the cell-surface protein repertoire. [5][6][7] An array of cell-surface proteins are detected in physiologic fluids as soluble forms representing cleaved extracellular domains. [6][7][8][9] Included in the known soluble proteins cleaved from the cell surface are proteins that are involved in all steps of leukocyte recruitment, several of which are elevated in the plasma of patients with acute or chronic inflammation. 7 This led us to hypothesize that proteolytic shedding of c...
Background: Forkhead box protein f1 (Foxf1) is associated with cell differentiation, and may be a key player in bone homoeostasis. However, the effect of Foxf1 on osteogenesis of bone marrow-derived mesenchymal stem cells (BMSCs) and ovariectomy-induced bone loss, as well as its clinical implications, is unknown. Methods: By quantitative reverse transcriptase-polymerase chain reaction (qRT-PCR) and western blotting, we assayed Foxf1 expression in bone tissue, BMSCs, and bone marrow-derived macrophages (BMMs), derived from ovariectomised (OVX) mice, and during osteogenic differentiation and osteoclast differentiation. Using a loss-of-function approach (small interfering RNA [siRNA]-mediated knockdown) in vitro, we examined whether Foxf1 regulates osteoblast differentiation of BMSCs via the Wnt/b-catenin signalling pathway. Furthermore, we assessed the anabolic effect of Foxf1 knockdown (siFoxf1) in OVX mice in vivo. We also assayed the expression of Foxf1 in bone tissue derived from postmenopausal osteoporosis (PMOP) patients and its link with bone mineral density (BMD). Finally, we examined the effect of Foxf1 knockdown on the osteoblastic differentiation of human BMSCs. Findings: Foxf1 expression was significantly increased in bone extract and BMSCs from OVX mice and gradually decreased during osteoblastic differentiation of BMSCs but did not differ significantly in OVX mousederived BMMs or during osteoclast differentiation. In vitro, Foxf1 knockdown markedly increased the expression of osteoblast specific genes, alkaline phosphatase (ALP) activity, and mineralisation. Moreover, siFoxf1 activated the Wnt/b-catenin signalling pathway. The siFoxf1-induced increase in osteogenic differentiation was partly rescued by inhibitor of Wnt signalling (DKK1). In OVX mice, Foxf1 siRNA significantly reduced bone loss by enhancing bone formation. Foxf1 expression levels negatively correlated with reduced bone mass and bone formation in bone tissue from PMOP patients. Finally, Foxf1 knockdown significantly promoted osteogenesis by human BMSCs. Interpretation: Our findings indicate that Foxf1 knockdown promotes BMSC osteogenesis and prevents OVXinduced bone loss. Therefore, Foxf1 has potential as a biomarker of osteogenesis and may be a therapeutic target for PMOP.
Background: Efflux of macrophages limits inflammation. Results: Macrophage integrin ␣M2 is cleaved during exiting from inflammatory sites, released ␣M2 retains ligand binding capabilities, and inhibition of its metalloproteinase-mediated cleavage impairs macrophage efflux. Conclusion: Metalloproteinase-mediated proteolysis of integrin 2 promotes macrophage efflux from inflammatory sites. Significance: Regulated proteolysis of integrin 2 during inflammation demonstrates the potential of this mechanism to contribute to resolution of inflammation.
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