Single-cell spatial transcriptomics unravels cell states and ecosystems associated with clinical response to immunotherapy

Ziena Abdulrahman; Roderick C Slieker; Daniel McGuire; Marij J P Welters; Mariette I E van Poelgeest; Sjoerd H van der Burg

doi:10.1136/jitc-2024-011308

Single-cell spatial transcriptomics unravels cell states and ecosystems associated with clinical response to immunotherapy

J Immunother Cancer. 2025 Mar 13;13(3):e011308. doi: 10.1136/jitc-2024-011308.

Authors

Ziena Abdulrahman^{1

2}, Roderick C Slieker^{1

3}, Daniel McGuire⁴, Marij J P Welters^{1

2}, Mariette I E van Poelgeest⁵, Sjoerd H van der Burg^{6

2}

Affiliations

¹ Department of Medical Oncology, Leiden University Medical Center, Leiden, ZH, Netherlands.
² Oncode Institute, Utrecht, Netherlands.
³ Department of Cell and Chemical Biology, Leiden University Medical Center, Leiden, Netherlands.
⁴ NanoString Technologies Inc, Seattle, Washington, USA.
⁵ Gynaecology, Leiden University Medical Center, Leiden, Zuid-Holland, Netherlands.
⁶ Department of Medical Oncology, Leiden University Medical Center, Leiden, ZH, Netherlands shvdburg@lumc.nl.

Abstract

Background: The tumor microenvironment (TME) is a complex and dynamic ecosystem that is known to influence responses to immunotherapy. We leveraged single-cell spatial transcriptomics to systematically dissect the intricate complexity of the TME, in particular the cellular heterogeneity and spatial interactions. Their collective impact on immunotherapy efficacy was studied in the context of a homogeneous group of patients with vulvar high-grade squamous intraepithelial lesions (vHSIL) treated with an immunotherapeutic tumor-specific peptide vaccine.

Methods: We performed single-cell spatial transcriptomics on 20 pretreatment vHSIL lesions, stratified by clinical response to immunotherapeutic vaccination into complete responders (CR), partial responders (PR) and non-responders (NR). Using a 1,000-gene panel, we mapped over 274,000 single cells in situ, identifying 18 cell clusters and 99 distinct non-epithelial cell states. Findings were validated against public single-cell transcriptomic data sets to assess their broader relevance across tumor types.

Results: Profound heterogeneity within the TME was detected across the response groups. CR lesions exhibited a higher ratio of immune-supportive to immune-suppressive cells-a pattern mirrored in other solid tumors following neoadjuvant checkpoint blockade. Key immune populations enriched in CRs included CD4+CD161+ effector T cells and chemotactic CD4+ and CD8+ T cells. Conversely, PRs were characterized by increased proportions of T helper 2 cells and CCL18-expressing macrophages, which are associated with the recruitment of type 2 T cells and regulatory T cells. NRs displayed preferential infiltration with immunosuppressive fibroblasts. Distinct spatial immune ecosystems further defined response groups. Although a number of immune cells were detected in all patients, type 1 effector cells dominated interactions in CRs, type 2 cells were prominently interacting in PRs, while NRs lacked organized immune cell interactions.

Conclusions: This study underscores the dual importance of both cellular composition and spatial organization in steering clinical response to immunotherapy.

Keywords: Biomarker; Immunotherapy; Vaccine.

MeSH terms

Female
Humans
Immunotherapy* / methods
Single-Cell Analysis / methods
Transcriptome
Tumor Microenvironment*