The Immune Suppressive Microenvironment of Human Gliomas Depends on the Accumulation of Bone Marrow-derived Macrophages in the Center of the Lesion

Overview

Journal J Immunother Cancer

Specialties Allergy & Immunology
Oncology
Pharmacology

Date 2019 Mar 1

PMID 30813960

Citations 93

Authors

Laura Pinton

Elena Masetto

Marina Vettore

Samantha Solito

Sara Magri

Marta DAndolfi

Paola Del Bianco

Giovanna Lollo

Jean-Pierre Benoit

Hideho Okada

Aaron Diaz

Alessandro Della Puppa

Susanna Mandruzzato

Affiliations

Soon will be listed here.

Abstract

Background: Systemic and local immune suppression plays a significant role in glioma progression. Glioma microenvironment contains both brain-resident microglial cells (MG) and bone marrow-derived macrophages (BMDM), but the study of their functional and immune regulatory activity has been hampered until now by the lack of markers allowing a proper identification and isolation to collect pure populations.

Methods: Myeloid and lymphoid infiltrate were characterized in grade II, III and IV gliomas by multicolor flow cytometry, along with the composition of the cell subsets of circulating myeloid cells. Macrophages were sorted and tested for their immunosuppressive ability. Moreover, following preoperative administration of 5-aminolevulinic acid to patients, distinct areas of tumor lesion were surgically removed and analyzed, based on protoporphyrin IX fluorescence emission.

Results: The immune microenvironment of grade II to grade IV gliomas contains a large proportion of myeloid cells and a small proportion of lymphocytes expressing markers of dysfunctional activity. BMDM and resident MG cells were characterized through a combination of markers, thus permitting their geographical identification in the lesions, their sorting and subsequent analysis of the functional characteristics. The infiltration by BMDM reached the highest percentages in grade IV gliomas, and it increased from the periphery to the center of the lesion, where it exerted a strong immunosuppression that was, instead, absent in the marginal area. By contrast, MG showed little or no suppression. Functional differences, such as iron metabolism and phagocytosis, characterized resident versus blood-derived macrophages. Significant alterations in circulating monocytes were present in grade IV patients, correlating with accumulation of tumor macrophages.

Conclusions: Grade IV gliomas have an alteration in both circulating and tumor-associated myeloid cells and, differently from grade II and III gliomas, show a significant presence of blood-derived, immune suppressive macrophages. BMDM and MG have different functional properties.

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