A multidimensional analysis reveals distinct immune phenotypes and the composition of immune aggregates in pediatric acute myeloid leukemia

Joost B. Koedijk; Inge van der Werf; Livius Penter; Marijn A. Vermeulen; Farnaz Barneh; Alicia Perzolli; Joyce I. Meesters-Ensing; Dennis S. Metselaar; Thanasis Margaritis; Marta Fiocco; Hester A. de Groot-Kruseman; Rubina Moeniralam; Kristina Bang Christensen; Billie Porter; Kathleen Pfaff; Jacqueline S. Garcia; Scott J. Rodig; Catherine J. Wu; Henrik Hasle; Stefan Nierkens; Mirjam E. Belderbos; C. Michel Zwaan; Olaf Heidenreich

doi:10.1038/s41375-024-02381-w

A multidimensional analysis reveals distinct immune phenotypes and the composition of immune aggregates in pediatric acute myeloid leukemia

Joost B. Koedijk, Inge van der Werf, Livius Penter, Marijn A. Vermeulen, Farnaz Barneh, Alicia Perzolli, Joyce I. Meesters-Ensing, Dennis S. Metselaar, Thanasis Margaritis, Marta Fiocco, Hester A. de Groot-Kruseman, Rubina Moeniralam, Kristina Bang Christensen, Billie Porter, Kathleen Pfaff, Jacqueline S. Garcia, Scott J. Rodig, Catherine J. Wu, Henrik Hasle, Stefan NierkensMirjam E. Belderbos, C. Michel Zwaan, Olaf Heidenreich^*

^*Corresponding author for this work

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Abstract

Because of the low mutational burden and consequently, fewer potential neoantigens, children with acute myeloid leukemia (AML) are thought to have a T cell-depleted or ‘cold’ tumor microenvironment and may have a low likelihood of response to T cell-directed immunotherapies. Understanding the composition, phenotype, and spatial organization of T cells and other microenvironmental populations in the pediatric AML bone marrow (BM) is essential for informing future immunotherapeutic trials about targetable immune-evasion mechanisms specific to pediatric AML. Here, we conducted a multidimensional analysis of the tumor immune microenvironment in pediatric AML and non-leukemic controls. We demonstrated that nearly one-third of pediatric AML cases has an immune-infiltrated BM, which is characterized by a decreased ratio of M2- to M1-like macrophages. Furthermore, we detected the presence of large T cell networks, both with and without colocalizing B cells, in the BM and dissected the cellular composition of T- and B cell-rich aggregates using spatial transcriptomics. These analyses revealed that these aggregates are hotspots of CD8⁺ T cells, memory B cells, plasma cells and/or plasmablasts, and M1-like macrophages. Collectively, our study provides a multidimensional characterization of the BM immune microenvironment in pediatric AML and indicates starting points for further investigations into immunomodulatory mechanisms in this devastating disease.

Original language	English
Pages (from-to)	2332-2343
Number of pages	12
Journal	Leukemia
Volume	38
Issue number	11
Early online date	26 Aug 2024
DOIs	https://doi.org/10.1038/s41375-024-02381-w
Publication status	Published - Nov 2024

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Koedijk, J. B., van der Werf, I., Penter, L., Vermeulen, M. A., Barneh, F., Perzolli, A., Meesters-Ensing, J. I., Metselaar, D. S., Margaritis, T., Fiocco, M., de Groot-Kruseman, H. A., Moeniralam, R., Bang Christensen, K., Porter, B., Pfaff, K., Garcia, J. S., Rodig, S. J., Wu, C. J., Hasle, H., ... Heidenreich, O. (2024). A multidimensional analysis reveals distinct immune phenotypes and the composition of immune aggregates in pediatric acute myeloid leukemia. Leukemia, 38(11), 2332-2343. https://doi.org/10.1038/s41375-024-02381-w

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title = "A multidimensional analysis reveals distinct immune phenotypes and the composition of immune aggregates in pediatric acute myeloid leukemia",

abstract = "Because of the low mutational burden and consequently, fewer potential neoantigens, children with acute myeloid leukemia (AML) are thought to have a T cell-depleted or {\textquoteleft}cold{\textquoteright} tumor microenvironment and may have a low likelihood of response to T cell-directed immunotherapies. Understanding the composition, phenotype, and spatial organization of T cells and other microenvironmental populations in the pediatric AML bone marrow (BM) is essential for informing future immunotherapeutic trials about targetable immune-evasion mechanisms specific to pediatric AML. Here, we conducted a multidimensional analysis of the tumor immune microenvironment in pediatric AML and non-leukemic controls. We demonstrated that nearly one-third of pediatric AML cases has an immune-infiltrated BM, which is characterized by a decreased ratio of M2- to M1-like macrophages. Furthermore, we detected the presence of large T cell networks, both with and without colocalizing B cells, in the BM and dissected the cellular composition of T- and B cell-rich aggregates using spatial transcriptomics. These analyses revealed that these aggregates are hotspots of CD8+ T cells, memory B cells, plasma cells and/or plasmablasts, and M1-like macrophages. Collectively, our study provides a multidimensional characterization of the BM immune microenvironment in pediatric AML and indicates starting points for further investigations into immunomodulatory mechanisms in this devastating disease.",

author = "Koedijk, {Joost B.} and {van der Werf}, Inge and Livius Penter and Vermeulen, {Marijn A.} and Farnaz Barneh and Alicia Perzolli and Meesters-Ensing, {Joyce I.} and Metselaar, {Dennis S.} and Thanasis Margaritis and Marta Fiocco and {de Groot-Kruseman}, {Hester A.} and Rubina Moeniralam and {Bang Christensen}, Kristina and Billie Porter and Kathleen Pfaff and Garcia, {Jacqueline S.} and Rodig, {Scott J.} and Wu, {Catherine J.} and Henrik Hasle and Stefan Nierkens and Belderbos, {Mirjam E.} and Zwaan, {C. Michel} and Olaf Heidenreich",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = nov,

doi = "10.1038/s41375-024-02381-w",

language = "English",

volume = "38",

pages = "2332--2343",

journal = "Leukemia",

issn = "0887-6924",

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Koedijk, JB, van der Werf, I, Penter, L, Vermeulen, MA, Barneh, F, Perzolli, A, Meesters-Ensing, JI, Metselaar, DS, Margaritis, T, Fiocco, M, de Groot-Kruseman, HA, Moeniralam, R, Bang Christensen, K, Porter, B, Pfaff, K, Garcia, JS, Rodig, SJ, Wu, CJ, Hasle, H, Nierkens, S, Belderbos, ME, Zwaan, CM & Heidenreich, O 2024, 'A multidimensional analysis reveals distinct immune phenotypes and the composition of immune aggregates in pediatric acute myeloid leukemia', Leukemia, vol. 38, no. 11, pp. 2332-2343. https://doi.org/10.1038/s41375-024-02381-w

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T1 - A multidimensional analysis reveals distinct immune phenotypes and the composition of immune aggregates in pediatric acute myeloid leukemia

AU - Koedijk, Joost B.

AU - van der Werf, Inge

AU - Penter, Livius

AU - Vermeulen, Marijn A.

AU - Barneh, Farnaz

AU - Perzolli, Alicia

AU - Meesters-Ensing, Joyce I.

AU - Metselaar, Dennis S.

AU - Margaritis, Thanasis

AU - Fiocco, Marta

AU - de Groot-Kruseman, Hester A.

AU - Moeniralam, Rubina

AU - Bang Christensen, Kristina

AU - Porter, Billie

AU - Pfaff, Kathleen

AU - Garcia, Jacqueline S.

AU - Rodig, Scott J.

AU - Wu, Catherine J.

AU - Hasle, Henrik

AU - Nierkens, Stefan

AU - Belderbos, Mirjam E.

AU - Zwaan, C. Michel

AU - Heidenreich, Olaf

PY - 2024/11

Y1 - 2024/11

N2 - Because of the low mutational burden and consequently, fewer potential neoantigens, children with acute myeloid leukemia (AML) are thought to have a T cell-depleted or ‘cold’ tumor microenvironment and may have a low likelihood of response to T cell-directed immunotherapies. Understanding the composition, phenotype, and spatial organization of T cells and other microenvironmental populations in the pediatric AML bone marrow (BM) is essential for informing future immunotherapeutic trials about targetable immune-evasion mechanisms specific to pediatric AML. Here, we conducted a multidimensional analysis of the tumor immune microenvironment in pediatric AML and non-leukemic controls. We demonstrated that nearly one-third of pediatric AML cases has an immune-infiltrated BM, which is characterized by a decreased ratio of M2- to M1-like macrophages. Furthermore, we detected the presence of large T cell networks, both with and without colocalizing B cells, in the BM and dissected the cellular composition of T- and B cell-rich aggregates using spatial transcriptomics. These analyses revealed that these aggregates are hotspots of CD8+ T cells, memory B cells, plasma cells and/or plasmablasts, and M1-like macrophages. Collectively, our study provides a multidimensional characterization of the BM immune microenvironment in pediatric AML and indicates starting points for further investigations into immunomodulatory mechanisms in this devastating disease.

AB - Because of the low mutational burden and consequently, fewer potential neoantigens, children with acute myeloid leukemia (AML) are thought to have a T cell-depleted or ‘cold’ tumor microenvironment and may have a low likelihood of response to T cell-directed immunotherapies. Understanding the composition, phenotype, and spatial organization of T cells and other microenvironmental populations in the pediatric AML bone marrow (BM) is essential for informing future immunotherapeutic trials about targetable immune-evasion mechanisms specific to pediatric AML. Here, we conducted a multidimensional analysis of the tumor immune microenvironment in pediatric AML and non-leukemic controls. We demonstrated that nearly one-third of pediatric AML cases has an immune-infiltrated BM, which is characterized by a decreased ratio of M2- to M1-like macrophages. Furthermore, we detected the presence of large T cell networks, both with and without colocalizing B cells, in the BM and dissected the cellular composition of T- and B cell-rich aggregates using spatial transcriptomics. These analyses revealed that these aggregates are hotspots of CD8+ T cells, memory B cells, plasma cells and/or plasmablasts, and M1-like macrophages. Collectively, our study provides a multidimensional characterization of the BM immune microenvironment in pediatric AML and indicates starting points for further investigations into immunomodulatory mechanisms in this devastating disease.

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DO - 10.1038/s41375-024-02381-w

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SN - 0887-6924

VL - 38

SP - 2332

EP - 2343

JO - Leukemia

JF - Leukemia

IS - 11

ER -

A multidimensional analysis reveals distinct immune phenotypes and the composition of immune aggregates in pediatric acute myeloid leukemia

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