posted on 2023-04-03, 22:41authored byGrant M. Fischer, Ali Jalali, David A. Kircher, Won-Chul Lee, Jennifer L. McQuade, Lauren E. Haydu, Aron Y. Joon, Alexandre Reuben, Mariana P. de Macedo, Fernando C. L. Carapeto, Chendong Yang, Anuj Srivastava, Chandrashekar R. Ambati, Arun Sreekumar, Courtney W. Hudgens, Barbara Knighton, Wanleng Deng, Sherise D. Ferguson, Hussein A. Tawbi, Isabella C. Glitza, Jeffrey E. Gershenwald, Y. N. Vashisht Gopal, Patrick Hwu, Jason T. Huse, Jennifer A. Wargo, P. Andrew Futreal, Nagireddy Putluri, Alexander J. Lazar, Ralph J. DeBerardinis, Joseph R. Marszalek, Jianjun Zhang, Sheri L. Holmen, Michael T. Tetzlaff, Michael A. Davies
Table S1: Clinical Characteristics of Melanoma Brain Metastases, Extracranial Metastases, and Primary Tumors. Tab 1. Clinical data for the MBMs and ECMs from melanoma patients utilized in this manuscript. Tab 2. Clinical data for primary melanomas from melanoma patients utilized in this manuscript.
Funding
University of Texas MD Anderson
National Center for Advancing Translational Sciences
Dr. Miriam and Sheldon G. Adelson Medical Research Foundation
AIM at Melanoma Foundation
NIH
NCI
Cancer Prevention Research Institute of Texas
CPRIT
Melanoma Research Alliance
Dr. John M. Skibber Professorship of MD Anderson, the Robert and Lynne Grossman Family Foundation, and the Michael and Patricia Booker Melanoma Research Endowment
Anderson Melanom
ACS
Baylor College of Medicine
History
ARTICLE ABSTRACT
There is a critical need to improve our understanding of the pathogenesis of melanoma brain metastases (MBM). Thus, we performed RNA sequencing on 88 resected MBMs and 42 patient-matched extracranial metastases; tumors with sufficient tissue also underwent whole-exome sequencing, T-cell receptor sequencing, and IHC. MBMs demonstrated heterogeneity of immune infiltrates that correlated with prior radiation and post-craniotomy survival. Comparison with patient-matched extracranial metastases identified significant immunosuppression and enrichment of oxidative phosphorylation (OXPHOS) in MBMs. Gene-expression analysis of intracranial and subcutaneous xenografts, and a spontaneous MBM model, confirmed increased OXPHOS gene expression in MBMs, which was also detected by direct metabolite profiling and [U-13C]-glucose tracing in vivo. IACS-010759, an OXPHOS inhibitor currently in early-phase clinical trials, improved survival of mice bearing MAPK inhibitor–resistant intracranial melanoma xenografts and inhibited MBM formation in the spontaneous MBM model. The results provide new insights into the pathogenesis and therapeutic resistance of MBMs.
Improving our understanding of the pathogenesis of MBMs will facilitate the rational development and prioritization of new therapeutic strategies. This study reports the most comprehensive molecular profiling of patient-matched MBMs and extracranial metastases to date. The data provide new insights into MBM biology and therapeutic resistance.See related commentary by Egelston and Margolin, p. 581.This article is highlighted in the In This Issue feature, p. 565