Radiation and the immune system: current knowledge and future perspectives

Editorial

23 January 2018

Editorial: Radiation and the Immune System: Current Knowledge and Future Perspectives

Katalin Lumniczky

Serge M. Candéias

Udo S. Gaipl

and

Benjamin Frey

16,962 views

41 citations

Editors

Katalin Lumniczky

National Center for Public Health and Pharmacy

Serge M. Candéias

Commissariat à l'Energie Atomique et aux Energies Alternatives (CEA)

Udo S Gaipl

University Hospital Erlangen

Benjamin Frey

Department of Radiation Oncology, University Hospital Erlangen

Impact

Review

26 May 2017

Modulating Both Tumor Cell Death and Innate Immunity Is Essential for Improving Radiation Therapy Effectiveness

Qiuji Wu

, 5 more and

Jean-Luc Perfettini

9,739 views

61 citations

Review

07 June 2017

Intercellular Communication of Tumor Cells and Immune Cells after Exposure to Different Ionizing Radiation Qualities

Sebastian Diegeler

and

Christine E. Hellweg

10,167 views

49 citations

Original Research

25 July 2017

Decrease of Markers Related to Bone Erosion in Serum of Patients with Musculoskeletal Disorders after Serial Low-Dose Radon Spa Therapy

Aljona Cucu

, 7 more and

Claudia Fournier

4,514 views

31 citations

Original Research

28 June 2017

Full Length Interleukin 33 Aggravates Radiation-Induced Skin Reaction

Olga Kurow

, 12 more and

Axel J. Hueber

6,501 views

11 citations

Methods

01 June 2017

Measuring Leukocyte Adhesion to (Primary) Endothelial Cells after Photon and Charged Particle Exposure with a Dedicated Laminar Flow Chamber

Nadine Erbeldinger

, 12 more and

Claudia Fournier

6,175 views

12 citations

Immune signaling in the healthy and irradiated brain. In the healthy brain (left panel), intact neurons express and secrete molecules (CD47, CD55, CD20, and CX3CL1), which maintain adjacent microglial cells in a resting state. Brain microvascular endothelial cells, also in a resting state allow the continuous flow of blood lymphocytes and myeloid cells. In the irradiated brain (right panel), radiation-induced direct cellular damage affects neurons and microglia. Neuronal damage leads to the secretion of pro-inflammatory cytokines by the neurons, which activate microglia (mechanism a). In microglia, radiation-induced DNA damage through the NFκB pathway leads to microglia activation (MHC, CD68 upregulation) and secretion of pro-inflammatory cytokines (mechanism a). Damaged neurons secrete high-mobility group protein 1 (HMGB1) in the extracellular environment, which is a ligand for TLR4 on the activated microglia. Damaged neurons also express calreticulin on their surface, which is sensed by activated microglia and induces phagocytosis of both damaged and healthy neurons (mechanism b). Irradiation increases the secretion of CCL2 by activated microglia and also upregulates CCR2 expression. CCL2 signaling is a chemoattractant for CCR2-expressing peripheral macrophages, which penetrate the blood–brain barrier (mechanism c). Radiation induces upregulation of adhesion markers [intercellular adhesion molecule 1 (ICAM-1), P-selectin] on brain microvascular endothelial cells. Peripheral lymphocytes and monocytes adhere to activated endothelial cells and transmigrate through the microvessel wall (mechanism d). Pro-inflammatory signals and HMGB1 emitted by damaged neurons and activated microglia activate brain-residing dendritic cells, which migrate to regional lymph nodes and induce immune activation (mechanism e).

Review

05 May 2017

Ionizing Radiation-Induced Immune and Inflammatory Reactions in the Brain

Katalin Lumniczky

, 1 more and

Géza Sáfrány

26,358 views

189 citations

Stimulation of tumor cell proliferation by bystander dying cells, the “feeder cells” effect. The upper panel shows viable cell counts of cocultures [closed circles in panels (A–C)] and viable cells alone in D10 medium [open circles in panels (A–C)]. Cocultures were composed of viable (200 cells/well) and lethally ultraviolet light type B-irradiated (10,000 cells/well) B16F10 melanoma cells (A). Dead/viable ratio titration of cocultures (B). Transwell cocultures with 10,000 apoptotic cells (C). The lower panel shows cell counts of independent wells containing fibroblasts in R10 medium [open circles in panels (D–F)] or in supernatants (SN) from apoptotic cells [closed circles in panels (D–F)]. Mouse NIH/3T3 fibroblast (1,000 cells/well) cultures with SNs of 0.2 million cells/ml apoptotic homologous cells (D). Human fibroblast-like synoviocytes (FLS, 1,000 cells/well) from two rheumatoid arthritis patients RA315 (E) and RA314 (F) cocultured with SNs from apoptotic neutrophils (0.2 million cells/ml).

Original Research

27 April 2017

Inosine Released from Dying or Dead Cells Stimulates Cell Proliferation via Adenosine Receptors

Jin Chen

, 11 more and

Luis E. Muñoz

7,755 views

21 citations

Review

03 May 2017

Basics of Radiation Biology When Treating Hyperproliferative Benign Diseases

Franz Rödel

, 8 more and

Stephanie Hehlgans

6,808 views

27 citations

Effects of ionizing radiation on the functional properties of primary mouse thymic epithelial cell (TEC) subpopulations. (A) mRNA expression levels of TEC functional factors in total primary mouse thymic stroma. All values were normalized against Gapdh and expressed relative to the untreated sample. Graphs show the average of four biological replicates. *p < 0.05, multiple t-tests with Holm–Sidak posttest correction. (B) Gating strategy for the sorting of mouse primary cTEC, mTEC Low, mTEC High CD86-, and mTEC High CD86+ subpopulations. (C) mRNA expression levels of TEC functional factors in mouse primary sorted TEC subpopulations. Data were normalized against Gapdh and expressed as fold change relative to the untreated sample. All values correspond to the average of three technical replicates and one biological sample corresponding to 20 thymi per group pooled together prior to the analysis. Error bars represent the SEM. *p < 0.05, multiple t-tests with Holm–Sidak posttest correction.

Original Research

13 April 2017

Differential Response of Mouse Thymic Epithelial Cell Types to Ionizing Radiation-Induced DNA Damage

Irene Calvo-Asensio

, 3 more and

Rhodri Ceredig

3,761 views

18 citations

Radiotherapy–immunotherapy (IT) combination trials currently open.a

Review

11 April 2017

A Century of Radiation Therapy and Adaptive Immunity

Dörthe Schaue

8,450 views

51 citations

Original Research

10 April 2017

Radiotherapy-Associated Long-term Modification of Expression of the Inflammatory Biomarker Genes ARG1, BCL2L1, and MYC

Grainne Manning

, 2 more and

Christophe Badie

3,261 views

26 citations

Review

13 March 2017

Barriers to Radiation-Induced In Situ Tumor Vaccination

Erik Wennerberg

, 6 more and

Sandra Demaria

Immunosuppressive pathways enhanced by RT in the TME that limit RT-induced in situ vaccination. (A) DCs are recruited to the tumor and activated following RT-mediated induction of ICD and subsequent release of DAMPs in the TME [including ATP, depicted in (E)]. After uptake of TAAs that are released from dying tumor cells DCs become activated and migrate to tumor-draining lymph nodes where they cross-present the antigens to naïve T cells. The activated TAA-specific CD8+ T cells proliferate, acquire effector function, and infiltrate the irradiated tumor and abscopal sites where they eliminate tumor cells. However, RT promotes not only immune stimulation but also contributes to a suppressive TME that counteracts the newly initiated immune response. (B) Hypoxic regions within tumors have reduced sensitivity to RT and a suppressive TME that can be exacerbated following RT. RT upregulates transcription of HIF-1α resulting in expression of a series of genes that promote immunosuppression, by inducing Treg proliferation, M2 polarization of TAMs, and MDSC activation. (C) C–C chemokine receptor type 2 (CCR2)-expressing monocytes are recruited to the tumor due to increased CCL2 levels following RT. In the tumor, monocytes then differentiate to TAMs. RT can also directly modulate TAMs through induction of CSF1 causing mobilization, proliferation, and polarization of TAMs to an M2 phenotype. (D) RT activates latent TGFβ within the tumor that causes conversion of CD4+ T cells to Tregs, and polarization of TAMs and TANs to an M2 and N2 phenotype, respectively. (E) Tumor cells undergoing radiation-induced ICD release ATP, which is rapidly catabolized into adenosine in the TME by ectoenzymes CD39 and CD73 expressed on tumor cells, stromal cells, and immune cells. Local accumulation of extracellular adenosine suppresses DCs and effector T cells while promoting proliferation of Tregs and a more suppressive phenotype in TAMs. DC, dendritic cell; ICD, immunogenic cell death; RT, radiation therapy; DAMPs, danger-associated molecular patterns; TAA, tumor-associated antigens; TME, tumor microenvironment; pMHC-1, peptide-loaded major histocompatibility class I complex; TCR, T cell receptor; HIF-1α, hypoxia-inducible factor-1α; VEGFA, vascular endothelial growth factor A; CTLA-4, cytotoxic T lymphocyte-associated protein 4; PD-1, programmed cell death protein-1; TIM-3, T-cell immunoglobulin and mucin-domain containing-3; LAG-3, lymphocyte-activation gene 3; Treg, regulatory T cell; TGFβ, transforming growth factor β; TAM, tumor-associated macrophage; MDSC, myeloid-derived suppressor cell; CSF1, colony-stimulating factor 1; TAN, tumor-associated neutrophil; ATP, adenosine triphosphate.

The immunostimulatory properties of radiation therapy (RT) have recently generated widespread interest due to preclinical and clinical evidence that tumor-localized RT can sometimes induce antitumor immune responses mediating regression of non-irradiated metastases (abscopal effect). The ability of RT to activate antitumor T cells explains the synergy of RT with immune checkpoint inhibitors, which has been well documented in mouse tumor models and is supported by observations of more frequent abscopal responses in patients refractory to immunotherapy who receive RT during immunotherapy. However, abscopal responses following RT remain relatively rare in the clinic, and antitumor immune responses are not effectively induced by RT against poorly immunogenic mouse tumors. This suggests that in order to improve the pro-immunogenic effects of RT, it is necessary to identify and overcome the barriers that pre-exist and/or are induced by RT in the tumor microenvironment. On the one hand, RT induces an immunogenic death of cancer cells associated with release of powerful danger signals that are essential to recruit and activate dendritic cells (DCs) and initiate antitumor immune responses. On the other hand, RT can promote the generation of immunosuppressive mediators that hinder DCs activation and impair the function of effector T cells. In this review, we discuss current evidence that several inhibitory pathways are induced and modulated in irradiated tumors. In particular, we will focus on factors that regulate and limit radiation-induced immunogenicity and emphasize current research on actionable targets that could increase the effectiveness of radiation-induced in situ tumor vaccination.

8,688 views

169 citations

A hypothetical network of KEGG pathways predicted to be altered by mRNAs targeted by the microRNAs (miRNAs) differentially expressed in the EVs in both 0.1 and 2 Gy samples. (A) Black circles represent differentially expressed miRNA, yellow boxes are their predicted target genes and colored boxes represent the pathways including these genes. (B) The full name and annotation of target mRNAs.

Original Research

27 March 2017

Extracellular Vesicles Mediate Radiation-Induced Systemic Bystander Signals in the Bone Marrow and Spleen

Tünde Szatmári

, 11 more and

Katalin Lumniczky

6,360 views

62 citations

$Hypofractionated radiotherapy (RT) results in local control of CT26 colon cancer tumors in BALB/c mice. The planning of the irradiation was conducted using a computer tomography image of the irradiation box and tumor-bearing mice with Philips pinnacle software to obtain an optimal target volume. Afterward, the dosimetry of the irradiation was performed manually with a calibrated ionization chamber. To further protect the normal tissue, the gantry of the 6-MV linear accelerator was rotated to 340°. Tumors of three anesthetized mice can be irradiated locally at once and the dose distribution (colored areas) shows that only the tumor and not the rest of the mouse is exposed to radiation (A). The tumor volumes were determined daily. Up to day 4 after the first irradiation with 5 Gy, the infiltration of immune cells in the tumors was monitored in tumors of three mice from each group (B). Hypofractionated irradiation with 2 × 5 Gy resulted in good tumor control (C); *p < 0.05, **p < 0.01; n: variable: at the starting point n = 40, with three mice less each following day per treatment group.$