Osteosarcoma is characterized by extensive inter- and intra-tumoral heterogeneity, contributing to treatment resistance and poor outcomes. Here, we present a comprehensive spatial transcriptomics analysis of osteosarcoma, encompassing primary tumors and local or metastatic relapses across diverse phenotypic subtypes. Despite this heterogeneity, we identify a nine-gene cell surface signature with theranostic potential, validated in independent datasets and shown by immunohistochemistry to be distributed across distinct tumor compartments, supporting multi-targeted therapeutic strategies. Analysis of the tumor immune microenvironment reveals systematic lymphoid exclusion, differential myeloid infiltration patterns, and a type I interferon response signature that may explain the failure of IFN-α supplementation in prior trials. Notably, we provide evidence of monocyte-derived osteoclastic differentiation within human osteosarcoma lung metastases, identifying precursor populations with complex secretory phenotypes representing potential immunomodulatory targets. This study offers biological insights and translational opportunities while providing a resource for the osteosarcoma research community. Osteosarcoma shows marked cellular heterogeneity that complicates treatment. Here, authors use spatial transcriptomics of primary and metastatic tumors to identify a shared 9-gene cell-surface signature and distinct immune patterns, highlighting potential diagnostic and therapeutic targets.
Moquin‐Beaudry et al. (Fri,) studied this question.
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