Authors
Minghao Dang, Luz Yurany Moreno Rueda, Maria Jose Acevedo Calado, Hima Bansal, David Alejandro Berrios Nolasco, Amishi U Vora, Jonathan D Mejia, Mei Huang, Wei Tan, Li Qin, Yunhe Liu, Yang Liu, David E Mery, Yan Cheng, Fenghuang Zhan, John D Shaughnessy, Qing Yi, Pei Lin, Mahmoud R Gaballa, Oren Pasvolsky, Hans C Lee, Sheeba K Thomas, Donna M Weber, Krina K Patel, Melody R Becnel, Jing Christine Ye, Isere Kuiatse, Elisabet E Manasanch, Linghua Wang, Robert Z Orlowski
Published in
Blood. Jul 07, 2026. Epub Jul 07, 2026.
Abstract
Multiple myeloma progresses from precursor states to active disease, and studying tumor microenvironment (TME) evolution across these stages is key to understanding immune dysregulation and therapeutic resistance. Here, we integrated paired single-cell RNA, T-, and B-cell receptor sequencing data from bone marrow samples of 235 patients spanning the disease spectrum. This dataset revealed dynamic changes in the abundance and functional states of diverse immune populations, including T-, natural killer, B-, and myeloid cells. Using non-negative factorization of cell-subset composition, we identified five reproducible TME subtypes, or "ecotypes," defined by coordinated cellular architectures. These ecotypes captured structured variation beyond disease stage and were associated with distinct cell-cell communication networks, cytokine signaling landscapes, transcription factor programs, and shared gene modules, reflecting coordinated immune adaptation to microenvironmental constraints. By linking tumor features with immune changes and ecotype distributions, we identified context-dependent associations influenced by both disease biology and treatment effects on the TME. We found that an ecotype enriched for bone marrow-resident populations and limited immune infiltration was associated with tumor expansion and inferior clinical outcomes, whereas ecotypes reflecting T-cell functional states showed distinct associations with immunotherapy response and survival. Our study provides a comprehensive single-cell immune atlas of multiple myeloma and its precursors, offering insights into TME organization and progression, and may guide development of stage-specific or ecotype-targeted immunotherapies.
PMID:
42413006
Bibliographic data and abstract were imported from PubMed on 08 Jul 2026.
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