MYC regulates CSF1 expression via microRNA 17/20a to modulate tumor-associated macrophages in osteosarcoma
Bikesh K. Nirala, Tajhal D. Patel, Lyazat Kurenbekova, Ryan Shuck, Atreyi Dasgupta, Nino Rainusso, Cristian Coarfa, Jason T. Yustein
Bikesh K. Nirala, Tajhal D. Patel, Lyazat Kurenbekova, Ryan Shuck, Atreyi Dasgupta, Nino Rainusso, Cristian Coarfa, Jason T. Yustein
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Research Article Oncology

MYC regulates CSF1 expression via microRNA 17/20a to modulate tumor-associated macrophages in osteosarcoma

Abstract

Osteosarcoma (OS) is the most common primary bone tumor of childhood. Approximately 20%–30% of OSs carry amplification of chromosome 8q24, which harbors the oncogene c-MYC and correlates with a poor prognosis. To understand the mechanisms that underlie the ability of MYC to alter both the tumor and its surrounding tumor microenvironment (TME), we generated and molecularly characterized an osteoblast-specific Cre-Lox-Stop-Lox-c-MycT58A p53fl/+ knockin genetically engineered mouse model (GEMM). Phenotypically, the Myc-knockin GEMM had rapid tumor development with a high incidence of metastasis. MYC-dependent gene signatures in our murine model demonstrated significant homology to the human hyperactivated MYC OS. We established that hyperactivation of MYC led to an immune-depleted TME in OS demonstrated by the reduced number of leukocytes, particularly macrophages. MYC hyperactivation led to the downregulation of macrophage colony-stimulating factor 1, through increased microRNA 17/20a expression, causing a reduction of macrophage population in the TME of OS. Furthermore, we developed cell lines from the GEMM tumors, including a degradation tag–MYC model system, which validated our MYC-dependent findings both in vitro and in vivo. Our studies utilized innovative and clinically relevant models to identify a potentially novel molecular mechanism through which MYC regulates the profile and function of the OS immune landscape.

Authors

Bikesh K. Nirala, Tajhal D. Patel, Lyazat Kurenbekova, Ryan Shuck, Atreyi Dasgupta, Nino Rainusso, Cristian Coarfa, Jason T. Yustein

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Figure 4

MYC association with CSF1 expression.

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MYC association with CSF1 expression. (A) Western blot of CSF1 protein e...
(A) Western blot of CSF1 protein expression in Myc-knockin tumors compared with the p53-driven tumor. The quantified expression is shown in the right panel. (B) The RNA-Seq analyzed relative mRNA expression, demonstrating reduced Csf1 mRNA expression in Myc-knockin (n = 5) tumors compared with the p53-driven (n = 4) tumor samples. (C) IHC staining for CSF1 in paraffin-embedded GEMM tumor tissue samples in the Myc-knockin tumors (lower panel) compared with p53-driven tumor (upper panel). The quantified expression is shown in the right panel. (D) MYC and CSF1 mRNA expression in the PDX samples of the OS. (E) Negative correlation between the MYC and CSF1 mRNA expression in human OS TARGET data set patients. (F) Kaplan-Meier curve of human OS TARGET data set for CSF1 expression with top quartile (n = 22) or bottom quartile (n = 22) samples; log-rank (Mantel-Cox) test was performed for the Kaplan-Meier analyses. (G) Csf1 expression upon transient knockdown of Myc in Myc-knockin murine OS cell lines. (H) Csf1 mRNA expression after dTAG-13 and -v1 treatment. (I) Western blot of MYC and CSF1 protein expression after dTAG-13 and -v1 treatment; blot quantification is shown in the right panel. (*P < 0.05, **P < 0.01, ****P < 0.0001.)