Abstract
Checkpoint blockade therapies that reactivate tumour-associated T cells can induce durable tumour control and result in the long-term survival of patients with advanced cancers1. Current predictive biomarkers for therapy response include high levels of intratumour immunological activity, a high tumour mutational burden and specific characteristics of the gut microbiota2,3. Although the role of T cells in antitumour responses has thoroughly been studied, other immune cells remain insufficiently explored. Here we use clinical samples of metastatic melanomas to investigate the role of B cells in antitumour responses, and find that the co-occurrence of tumour-associated CD8+ T cells and CD20+ B cells is associated with improved survival, independently of other clinical variables. Immunofluorescence staining of CXCR5 and CXCL13 in combination with CD20 reveals the formation of tertiary lymphoid structures in these CD8+CD20+ tumours. We derived a gene signature associated with tertiary lymphoid structures, which predicted clinical outcomes in cohorts of patients treated with immune checkpoint blockade. Furthermore, B-cell-rich tumours were accompanied by increased levels of TCF7+ naive and/or memory T cells. This was corroborated by digital spatial-profiling data, in which T cells in tumours without tertiary lymphoid structures had a dysfunctional molecular phenotype. Our results indicate that tertiary lymphoid structures have a key role in the immune microenvironment in melanoma, by conferring distinct T cell phenotypes. Therapeutic strategies to induce the formation of tertiary lymphoid structures should be explored to improve responses to cancer immunotherapy.
This is a preview of subscription content, access via your institution
Access options
Access Nature and 54 other Nature Portfolio journals
Get Nature+, our best-value online-access subscription
$29.99 / 30 days
cancel any time
Subscribe to this journal
Receive 51 print issues and online access
$199.00 per year
only $3.90 per issue
Buy this article
- Purchase on SpringerLink
- Instant access to full article PDF
Prices may be subject to local taxes which are calculated during checkout
Similar content being viewed by others
Data availability
All relevant data are available and are included as Source Data. Digital spatial-profiling data used in Fig. 2 and gene-expression microarray data from Danish patients treated with anti-CTLA4 are available as Source Data. Data from public repositories were accessed from GSE65904 (ref. 23), TCGA data portal SKCM level 3 release 3.1.14.0, PRJEB23709 (ref. 22), https://github.com/riazn/bms038_analysis/tree/master/data, GSE115978 (ref. 18) and GSE120575 (ref. 17). Any other relevant data and code can be obtained from the corresponding authors upon reasonable request.
Change history
20 March 2020
A Correction to this paper has been published: https://doi.org/10.1038/s41586-020-2155-6
References
Robert, C. et al. Pembrolizumab versus ipilimumab in advanced melanoma. N. Engl. J. Med. 372, 2521–2532 (2015).
Gopalakrishnan, V. et al. Gut microbiome modulates response to anti-PD-1 immunotherapy in melanoma patients. Science 359, 97–103 (2018).
Cristescu, R. et al. Pan-tumor genomic biomarkers for PD-1 checkpoint blockade-based immunotherapy. Science 362, eaar3593 (2018).
Ladányi, A. et al. Prognostic impact of B-cell density in cutaneous melanoma. Cancer Immunol. Immunother. 60, 1729–1738 (2011).
Messina, J. L. et al. 12-Chemokine gene signature identifies lymph node-like structures in melanoma: potential for patient selection for immunotherapy? Sci. Rep. 2, 765 (2012).
Cipponi, A. et al. Neogenesis of lymphoid structures and antibody responses occur in human melanoma metastases. Cancer Res. 72, 3997–4007 (2012).
Sautès-Fridman, C., Petitprez, F., Calderaro, J. & Fridman, W. H. Tertiary lymphoid structures in the era of cancer immunotherapy. Nat. Rev. Cancer 19, 307–325 (2019).
Petitprez, F. A. d. R et al. B cells are associated with survival and immunotherapy response in sarcoma. Nature https://doi.org/10.1038/s41586-019-1906-8 (2020).
Helmink, B. A. et al. B cells and tertiary lymphoid structures promote immunotherapy response. Nature https://doi.org/10.1038/s41586-019-1922-8 (2020).
Mihm, M. C., Jr & Mulé, J. J. Reflections on the histopathology of tumor-infiltrating lymphocytes in melanoma and the host immune response. Cancer Immunol. Res. 3, 827–835 (2015).
Dieu-Nosjean, M. C., Goc, J., Giraldo, N. A., Sautès-Fridman, C. & Fridman, W. H. Tertiary lymphoid structures in cancer and beyond. Trends Immunol. 35, 571–580 (2014).
Germain, C., Gnjatic, S. & Dieu-Nosjean, M. C. Tertiary lymphoid structure-associated B cells are key players in anti-tumor immunity. Front. Immunol. 6, 67 (2015).
Bindea, G. et al. Spatiotemporal dynamics of intratumoral immune cells reveal the immune landscape in human cancer. Immunity 39, 782–795 (2013).
Amaria, R. N. et al. Neoadjuvant immune checkpoint blockade in high-risk resectable melanoma. Nat. Med. 24, 1649–1654 (2018).
De Silva, N. S. & Klein, U. Dynamics of B cells in germinal centres. Nat. Rev. Immunol. 15, 137–148 (2015).
Rogers, P. R., Song, J., Gramaglia, I., Killeen, N. & Croft, M. OX40 promotes Bcl-xL and Bcl-2 expression and is essential for long-term survival of CD4 T cells. Immunity 15, 445–455 (2001).
Sade-Feldman, M. et al. Defining T cell states associated with response to checkpoint immunotherapy in melanoma. Cell 175, 998–1013 (2018).
Jerby-Arnon, L. et al. A cancer cell program promotes T cell exclusion and resistance to checkpoint blockade. Cell 175, 984–997 (2018).
Angelova, M. et al. Characterization of the immunophenotypes and antigenomes of colorectal cancers reveals distinct tumor escape mechanisms and novel targets for immunotherapy. Genome Biol. 16, 64 (2015).
Tarte, K., Zhan, F., De Vos, J., Klein, B. & Shaughnessy, J. Jr. Gene expression profiling of plasma cells and plasmablasts: toward a better understanding of the late stages of B-cell differentiation. Blood 102, 592–600 (2003).
Suan, D. et al. CCR6 defines memory B cell precursors in mouse and human germinal centers, revealing light-zone location and predominant low antigen affinity. Immunity 47, 1142–1153 (2017).
Gide, T. N. et al. distinct immune cell populations define response to anti-PD-1 monotherapy and anti-PD-1/anti-CTLA-4 combined therapy. Cancer Cell 35, 238–255 (2019).
Cirenajwis, H. et al. NF1-mutated melanoma tumors harbor distinct clinical and biological characteristics. Mol. Oncol. 11, 438–451 (2017).
Cancer Genome Atlas Network. Genomic classification of cutaneous melanoma. Cell 161, 1681–1696 (2015).
Becht, E. et al. Estimating the population abundance of tissue-infiltrating immune and stromal cell populations using gene expression. Genome Biol. 17, 218 (2016).
Tirosh, I. et al. Dissecting the multicellular ecosystem of metastatic melanoma by single-cell RNA-seq. Science 352, 189–196 (2016).
van Allen, E. M. et al. Genomic correlates of response to CTLA-4 blockade in metastatic melanoma. Science 350, 207–211 (2015).
Riaz, N. et al. Tumor and microenvironment evolution during immunotherapy with nivolumab. Cell 171, 934–949 (2017).
Lauss, M. et al. Mutational and putative neoantigen load predict clinical benefit of adoptive T cell therapy in melanoma. Nat. Commun. 8, 1738 (2017).
Roh, W. et al. Integrated molecular analysis of tumor biopsies on sequential CTLA-4 and PD-1 blockade reveals markers of response and resistance. Sci. Transl. Med. 9, eaah3560 (2017).
Harbst, K. et al. Molecular profiling reveals low- and high-grade forms of primary melanoma. Clin. Cancer Res. 18, 4026–4036 (2012).
Li, J. et al. CONTRA: copy number analysis for targeted resequencing. Bioinformatics 28, 1307–1313 (2012).
Hupé, P., Stransky, N., Thiery, J. P., Radvanyi, F. & Barillot, E. Analysis of array CGH data: from signal ratio to gain and loss of DNA regions. Bioinformatics 20, 3413–3422 (2004).
Pertea, M., Kim, D., Pertea, G. M., Leek, J. T. & Salzberg, S. L. Transcript-level expression analysis of RNA-seq experiments with HISAT, StringTie and Ballgown. Nat. Protocols 11, 1650–1667 (2016).
Rodriguez, J. M. et al. APPRIS: annotation of principal and alternative splice isoforms. Nucleic Acids Res. 41, D110–D117 (2013).
Lauss, M. et al. Monitoring of technical variation in quantitative high-throughput datasets. Cancer Inform. 12, 193–201 (2013).
Tusher, V. G., Tibshirani, R. & Chu, G. Significance analysis of microarrays applied to the ionizing radiation response. Proc. Natl Acad. Sci. USA 98, 5116–5121 (2001).
Acknowledgements
The study was supported by the Swedish Cancer Society, the Swedish Research Council, BioCARE, the Berta Kamprad Foundation, the King Gustaf V Jubilee foundation, Mats Paulsson’s foundation, Stefan Paulsson’s foundation and governmental funding for healthcare research (ALF). The Danish Cancer Society, the Aase and Einar Danielsen’s Fund and the Capital Region of Denmark Research Foundation. This project has received funding from the European Union’s Horizon 2020 research and innovation programme under the Marie Skłodowska-Curie grant agreement no. 641458.
Author information
Authors and Affiliations
Contributions
G.J. conceived and supervised the study. R.C., M.L. and G.J. analysed and drafted text. R.C., B.P., K.L. and K.J. generated immunostaining data. R.C., A.S., I.J., B.P. and G.J. analysed immunostaining data. R.C., K.P. and G.J. generated and analysed immunofluorescence data. A.v.S. and S.W. generated digital spatial-profiling data. M.L. and G.J. analysed digital spatial-profiling data. R.C., M.L., S.M., K.H. and G.J. performed statistical analyses. M.L. and G.J. performed bioinformatic analyses. M.L. analysed scRNA-seq data. J.V.-C. generated RNA-seq data. M.L., A.S., M.D., M.S.L., I.J., B.P., K.H., J.V.-C., A.v.S., K.L., S.W., K.J., K.P., D.S., J.A.W. and G.J. interpreted data. M.D., M.S.L., H.O., C.I., K.I., H.S., L.B., A.C. and I.M.S. collected clinical specimens and clinical data. All authors approved and read the final draft.
Corresponding author
Ethics declarations
Competing interests
S.W and A.v.S. are employees of Nanostring Inc. and declare that there are competing interests. All other authors declare no conflict of interest.
Additional information
Peer review information Nature thanks James J. Mulé, Caroline Robert and the other, anonymous, reviewer(s) for their contribution to the peer review of this work.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Extended data figures and tables
Extended Data Fig. 1 Characterization of TLSs in melanoma tumours.
a, CD20 (B cells), CD3 (T cells), CD8 (CD8+ T cells) and CD4 (CD4+ T cells) immunostaining in a representative melanoma with a TLS (n = 44 cases with TLS in the cohort of 177 cases). b, Subset survival analysis using CD8 and CD20 immunostaining in distant and lymph node metastases separately. n = 27 and 97 patients with available follow-up information, respectively. P values from Cox regression. c, Gene-expression characterization of the three groups using previously described signatures13. aDCs, activated dendritic cells; BVs, blood vessels; DCs, dendritic cells; IDCs, immature dendritic cells; LVs, lymph vessels; NK, NK cells; Tem, T effector memory cells; Tfh, T follicular helper cells; Tfh.Th2, T follicular helper 2 cells; Th, T helper cell; Th1, T helper 1 cell; Th2, T helper 2 cell. d, CD20, CD3, CD8, Ki67 and SOX10 immunostainings in three distant metastases. Arrows indicate the TLS. e, Survival analysis of 33 patients with TLS-containing tumours from regional lymph node metastases, stratified according to whether the TLS is located at the tumour border or is tumour-infiltrative. P value from Cox regression. f, Bar plot showing quantification of TLSs in tumours. Numbers in the box corresponds to TLSs per square millimetre. g, TLS gene score and type of lesion. n = 159 tumours. h, TLS score and immunological group. n = 159 tumours. In the box plots, the centre line represents the median, the box limits represent the lower and upper quartiles, and the whiskers extend to the most extreme values within 1.5× IQR. Numbers below the graphs represent numbers of patients.
Extended Data Fig. 2 High-plex proteomic analysis using the GeoMx assay and genomic characterization of tumours containing TLSs.
a, Workflow of the GeoMx assay. b, Immunofluorescence imaging of TLSs in tumour samples used in the GeoMx analysis. TLSs are sorted according to the unsupervised clustering of the high-plex proteomic data, performed on the different B cell populations. Pink, CD3+ T cells; green, tumour cells positive for PMEL and/or S100B; cyan, CD20+ B cells. For Ki67high 13 of 13 TLSs are displayed, and for Ki67low 15 of 17 TLSs are displayed. c, GeoMx data from 83 captured tumour cell regions. FDRs are from Kruskal–Wallis test, adjusted for multiple testing using the Benjamini–Hochberg method. d, Left, B2M immunostaining shows a significant difference between CD8/CD20 groups. P = 1× 10−11, Fisher’s exact test, n = 172 tumours). Right, plot shows B2M copy number status (blue = loss). P = 0.002, FDR adjustment for multiple comparisons = 0.007, Fisher’s exact test, n = 127 tumours. e–g, MHC-I (e) and MHC-II (f) expression (n = 160 tumours, P value from ANOVA) and mutational load (g) (n = 118 tumours, Kruskal–Wallis test) in relation to immunological groupings. h, Mutation heat map of melanoma-relevant genes in relation to immunological grouping. In the box plots, the centre line represents the median, the box limits represent the lower and upper quartiles, and the whiskers extend to the most extreme values within 1.5× IQR.
Extended Data Fig. 3 scRNA-seq analysis of tumour-associated B cells.
a, Box plots of gene-expression scores, based on different B cell developmental states in 812 B cells from 27 tumours from a previous study18. b, Heat map of selected genes across all 812 B cells. IGLL5and CD69 were two of the five genes with highest expression variation across all B cells. The heat map is sorted on IGLL5 and CD69 expression, excluding the cells that displayed increased expression of the plasma-cell signature. Genes showing a Pearson correlation >0.4 to IGLL5 or CD69 expression are also indicated. SDC1 and PRDM1 mark plasma cells, BCL6 and AICDA mark germinal centres, HLA-DRA mark MHC-II and HLA-A, HLA-B and HLA-C mark MHC-I. TLS-hallmark genes, germinal-centre-related genes and other B cell genes are also indicated. c, Extracting the single B cell RNA-seq data from a previous study17 using pretreatment samples (n = 16). The fraction of CD69+ B cells was higher in responders to ICB than in nonresponders (n = 8), but the fraction of IGLL5+ B cells was not. The fraction of IGLL5− CD69+ cells was also higher in responders. Plots of fraction of IGHD+ and IGHG+ B cells in relation to response to ICB therapy. P values from two-sided Wilcoxon test. In a, the centre lines in the box plot represent the median, the box limits represent the lower and upper quartiles, and the whiskers extend to the most extreme values within 1.5× IQR. d, Pearson correlation between expression of CD69 and germinal centre genes (CD83 and CXCR4) in data from a previous study18. Pie charts display the fact that the fraction of CD83+ and CXCR4+ B cells is increased among CD69+ B cells. Expression > 1 was used as a cut-off for being present. Seven hundred and fifty-three B cells without a present plasma-cell signature were analysed. P value from two-sided Fisher’s exact test. e, f, Heat map of gene-expression values corresponding to our TLS signature (e) and TLS-hallmark genes from the literature (f). Blue corresponds to increased expression. Mal., malignant cells. In e, f, single cells from the seven cell types on the left are from ref. 18, and from the four cell types on the right are from ref. 17.
Extended Data Fig. 4 Comparison of the derived TLS gene signature to other immune signatures.
a, Pearson correlation plots of the data from the cohort obtained at Skåne University Hospital, Lund (top, n = 160), data from cases of melanoma metastasis in the TCGA (bottom, n = 363) and baseline data from a previous publication22 (right, n = 69). Black box indicates the TLS signature. All signatures are taken from refs. 11, 19, 26. Red, positive correlation; blue, negative correlation. b, TLS gene-signature scores in primary tumours in comparison to distant and lymph node metastases. The number of tumours assigned to the TLShigh category is indicated above the plot.
Extended Data Fig. 5 TLS gene signature in cohorts treated by ICB.
a, Progression-free survival (PFS) and TLS gene signature in the Danish cohort of patients treated with anti-CTLA4. P value from Cox regression. b, TLS gene signature in relation to tumour mutational load, in data from a previous publication27 (n = 40 melanoma tumours). P value from Kruskal–Wallis test. c, Survival analyses on data from a previous study28, stratified according to whether patients are naive to anti-CTLA4 treatment or have progressed on anti-CTLA4. P values from Cox regression. d, Meta Cox regression analysis across the four cohorts treated using ICB (n = 186). P values from Cox regression adjusted for study. e, TLS gene signature of pretreatment (n = 16) and on-treatment samples (n = 10) in relation to therapy response in data from a previous publication30. P value from two-sided t-test. f, TLS gene signature of pretreatment (n = 38) and on-treatment (n = 39) samples in relation to RECIST response in data from a previous study28. P value from ANOVA test. g, TLS gene-signature score in 13 melanoma tumours that were also stained for CD20 protein. As an example, the tumour with the third highest score had TLSs. The two top tumours also had TLSs, whereas the other tumours did not. In the box plots in b, d, e, centre lines represent the median, the box limits represent the lower and upper quartiles, and the whiskers extend to the most extreme values within 1.5× IQR.
Supplementary information
Supplementary Data
Source Data 1: Microarray Affymetrix gene expression data derived from paraffin embedded tissue RNA. RNA was extracted from tumour blocks obtained from patients receiving anti-CTLA4 treatment as first-line therapy. Values are log2 transformed.
Supplementary Data
Source Data 2: Nanostring GeoMxTM high-plex proteomics data. Protein measurement of 60 immune proteins in T cells, B cells and tumor cells from melanoma tumors. Each value is normalized against IgG measurement.
Rights and permissions
About this article
Cite this article
Cabrita, R., Lauss, M., Sanna, A. et al. Tertiary lymphoid structures improve immunotherapy and survival in melanoma. Nature 577, 561–565 (2020). https://doi.org/10.1038/s41586-019-1914-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/s41586-019-1914-8
This article is cited by
-
CD8+ T cell-based cancer immunotherapy
Journal of Translational Medicine (2024)
-
TCL1A-expressing B cells are critical for tertiary lymphoid structure formation and the prognosis of oral squamous cell carcinoma
Journal of Translational Medicine (2024)
-
The potential and promise for clinical application of adoptive T cell therapy in cancer
Journal of Translational Medicine (2024)
-
Atypical memory B cells increase in the peripheral blood of patients with breast cancer regardless of lymph node involvement
BMC Immunology (2024)
-
Single-cell sequencing reveals the heterogeneity of B cells and tertiary lymphoid structures in muscle-invasive bladder cancer
Journal of Translational Medicine (2024)
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.