Chemotherapy-induced reactive myelopoiesis promotes expansion of immunosuppressive neutrophil-like monocytes in mice and humans
Huidong Shi, Zhi-Chun Ding, Ogacheko D. Okoko, Xin Wang, George Zhou, Yan Ye, Md Yeashin Gazi, Caitlin Brandle, Lirong Pei, Rafal Pacholczyk, Catherine C. Hedrick, Locke J. Bryan, Gang Zhou
Huidong Shi, Zhi-Chun Ding, Ogacheko D. Okoko, Xin Wang, George Zhou, Yan Ye, Md Yeashin Gazi, Caitlin Brandle, Lirong Pei, Rafal Pacholczyk, Catherine C. Hedrick, Locke J. Bryan, Gang Zhou
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Research Article Immunology Oncology

Chemotherapy-induced reactive myelopoiesis promotes expansion of immunosuppressive neutrophil-like monocytes in mice and humans

Abstract

Cytotoxic chemotherapy primarily targets rapidly proliferating cancer cells but also depletes normal myeloid cells. The resulting cell loss triggers reactive myelopoiesis, a compensatory process in which hematopoietic stem and progenitor cells in the bone marrow (BM) regenerate myeloid lineages. We previously showed that the alkylating agent cyclophosphamide (CTX) induces myelopoiesis, leading to the expansion of immunosuppressive monocytes in mice. However, the molecular features and clinical relevance of these cells remain poorly understood. Here, we report the emergence of immunosuppressive monocytes in the peripheral blood of lymphoma patients receiving CTX-containing chemotherapy. To gain mechanistic insight into CTX-induced myelopoiesis, we performed single-cell RNA sequencing (scRNA-seq) and assay for transposase-accessible chromatin using sequencing (ATAC-seq) on BM monocytes from CTX-treated mice. These analyses revealed a heterogeneous monocyte population and demonstrated that CTX skews myelopoiesis toward the generation of neutrophil-like monocytes (NeuMo). Moreover, CTX-induced NeuMo cells, enriched within the CXCR4+CX3CR1– monocyte subset, exhibited potent T cell–suppressive activity. Using the NeuMo gene signature, reanalysis of public scRNA-seq datasets identified a transcriptionally similar monocyte subset in chemotherapy-treated cancer patients. Collectively, our findings suggest that the expansion of NeuMo cells following chemotherapy represents a conserved immunoregulatory feedback mechanism with potential impact on tumor response to chemoimmunotherapy.

Authors

Huidong Shi, Zhi-Chun Ding, Ogacheko D. Okoko, Xin Wang, George Zhou, Yan Ye, Md Yeashin Gazi, Caitlin Brandle, Lirong Pei, Rafal Pacholczyk, Catherine C. Hedrick, Locke J. Bryan, Gang Zhou

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Figure 2

scRNA-seq analysis reveals the dynamic changes in immune composition in the BM following chemotherapy.

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scRNA-seq analysis reveals the dynamic changes in immune composition in ...
(A) The procedures and timeline are depicted in the schema. Briefly, BM cells were collected from CTX-treated mice on days 2 and 7. BM cells from naive mice were used as controls. After removal of dead cells, the whole BM cells were subjected to 10x Genomics scRNA-seq analysis. UMAP plots show annotated myeloid cell populations based on gene expression profiles in BM samples from naive and day 2 and day 7 CTX-treated mice. (B) Dot plot of myeloid cell subtype–specific markers that distinguishes these cell populations. (C) RNA velocity and pseudotime analyses demonstrating lineage relationships and potential differentiation trajectories of myeloid cell subsets in response to chemotherapy. (D) Bar graph summarizing the proportions of each identified cell type across the 3 conditions. (E) Violin plots displaying expression levels of several known NeuMo marker genes in CD11b+ monocytes across naive and day 2 and day 7 samples. (F) Violin plot showing the NeuMo gene signature score, based on the gene set identified by Barman et al. (16). Pairwise comparisons were performed using 2-sided Wilcoxon’s rank-sum tests with Benjamini-Hochberg correction for multiple comparisons. **P < 0.01; ****P < 0.0001. (G) Nebulosa density plot illustrating the coexpression pattern of 4 NeuMo signature genes in monocyte subsets. High-density regions represent clusters of cells coexpressing these genes. mat_Neu, mature neutrophil; imm _Neu, immature neutrophil; preNeu, pre-neutrophil; proNeu, progenitor neutrophil; GMP, granulocyte-monocyte progenitor; MDP, monocyte–dendritic cell progenitor; DC, dendritic cell; Mo, monocyte; Mp, macrophage.