Stephanie M. Pyonteck scite author profile

Glioblastoma multiforme (GBM) comprises several molecular subtypes including proneural GBM. Most therapeutic approaches targeting glioma cells have failed. An alternative strategy is to target cells in the glioma microenvironment, such as tumor-associated macrophages and microglia (TAMs). Macrophages depend upon colony stimulating factor (CSF)-1 for differentiation and survival. A CSF-1R inhibitor was used to target TAMs in a mouse proneural GBM model, which dramatically increased survival, and regressed established tumors. CSF-1R blockade additionally slowed intracranial growth of patient-derived glioma xenografts. Surprisingly, TAMs were not depleted in treated mice. Instead, glioma-secreted factors including GM-CSF and IFN-γ facilitated TAM survival in the context of CSF-1R inhibition. Alternatively activated/ M2 macrophage markers decreased in surviving TAMs, consistent with impaired tumor-promoting functions. These gene signatures were associated with enhanced survival in proneural GBM patients. Our results identify TAMs as a promising therapeutic target for proneural gliomas, and establish the translational potential of CSF-1R inhibition for GBM.

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Macrophage Ontogeny Underlies Differences in Tumor-Specific Education in Brain Malignancies

Bowman

et al. 2016

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SUMMARY Extensive transcriptional and ontogenetic diversity exists among normal tissue-resident macrophages, with unique transcriptional profiles endowing the cells with tissue-specific functions. However, it is unknown whether the origins of different macrophage populations affect their roles in malignancy. Given potential artifacts associated with irradiation-based lineage tracing, it remains unclear if bone marrow-derived macrophages (BMDM) are present in tumors of the brain, a tissue with no homeostatic involvement of BMDM. Here, we employed multiple models of murine brain malignancy and genetic lineage tracing to demonstrate that BMDM are abundant in primary and metastatic brain tumors. Our data indicate that distinct transcriptional networks in brain-resident microglia and recruited BMDM are associated with tumor-mediated education, yet are also influenced by chromatin landscapes established before tumor initiation. Furthermore, we demonstrate that microglia specifically repress Itga4 (CD49D), enabling its utility as a discriminatory marker between microglia and BMDM in primary and metastatic disease in mouse and human.

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Sonic Hedgehog Pathway Activation Is Induced by Acute Brain Injury and Regulated by Injury-Related Inflammation

et al. 2009

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The adult mammalian brain responds to injury by activating a program of cell proliferation during which many oligodendrocyte precursors, microglia, and some astrocytes proliferate. Another common response to brain injury is the induction of reactive gliosis, a process whereby dormant astrocytes undergo morphological changes and alter their transcriptional profiles. Although brain injury-induced reactive gliosis is concurrent with the proliferation of surrounding cells, a functional relationship between reactive gliosis and this cell proliferation has not been clearly demonstrated. Here, we show that the mitogen sonic hedgehog (SHH) is produced in reactive astrocytes after injury to the cerebral cortex and participates in regulating the proliferation of Olig2-expressing (Olig2 ϩ ) cells after brain injury. Using a cortical freeze injury to induce reactive gliosis in a Gli-luciferase reporter mouse, we show that the SHH pathway is maximally active 3 d after brain injury and returns to baseline levels by 14 d. SHH expression parallels Gli activation and localizes to glial fibrillary acidic protein-expressing reactive astrocytes. Inhibition of the SHH pathway with cyclopamine blocks the Gli response and significantly reduces both the proliferating and overall number of Olig2 ϩ cells in the injured cortex. To provide mechanistic insight into SHH pathway activation in astrocytes, we show that proinflammatory stimuli activate SHH-expressing reactive astrocytes, whereas inhibition of inflammation-induced reactive gliosis by macrophage depletion abolishes SHH activation after brain injury and dampens cell proliferation after injury. Our data describes a unique reactive astrocyte-based, SHH-expressing niche formed in response to injury and inflammation that regulates the proliferation of Olig2 ϩ cells.

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Deficiency of the macrophage growth factor CSF-1 disrupts pancreatic neuroendocrine tumor development

et al. 2011

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Tumor-associated macrophages have recently emerged as a key regulatory cell type during cancer progression, and have been found to promote tumor malignancy in the majority of studies performed to date. We show in this study that CD68þ macrophages positively correlate with tumor grade and liver metastasis in human pancreatic neuroendocrine tumors (PNETs). To investigate the potential mechanisms whereby macrophages can promote PNET progression, we crossed the RIP1-Tag2 (RT2) mouse model of pancreatic islet cancer to colonystimulating factor-1 (CSF-1)-deficient Csf1 op/op mice, which have reduced numbers of tissue macrophages. Csf1 op/op RT2 mice had a substantial reduction in cumulative tumor burden, which interestingly resulted from a significant decrease in angiogenic switching and tumor number, rather than an evident effect on tumor growth. In the tumors that did develop in CSF-1-deficient animals, however, there were no significant differences in tumor cell proliferation, apoptosis, angiogenesis or invasion. CSF-1 deficiency decreased macrophage infiltration by approximately 50% during all stages of RT2 tumor progression. Interestingly, several cytokines were upregulated in CSF-1-deficient RT2 tumors, and neutrophil infiltration was increased. These results show that macrophages are important for promoting PNET development and suggest that additional factors contribute to the recruitment and survival of myeloid cells in RT2 tumors in the absence of CSF-1.

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