Abstract
BackgroundCranial radiotherapy is used to treat tumors of the central nervous system (CNS), as well as non-neoplastic conditions such as arterio-venous malformations; however, its use is limited by the tolerance of adjacent normal CNS tissue, which can lead to devastating long-term sequelae for patients. Despite decades of research, the underlying mechanisms by which radiation induces CNS tissue injury remain unclear. Neuroinflammation and immune cell infiltration are a recognized component of the CNS radiation response; however, the extent and mechanisms by which bone marrow-derived (BMD) immune cells participate in late radiation injury is unknown. Thus, we set out to better characterize the response and tested the hypothesis that C-C chemokine receptor type 2 (CCR2) signaling was required for myeloid cell recruitment following brain irradiation.MethodsWe used young adult C57BL/6 male bone marrow chimeric mice created with donor mice that constitutively express enhanced green fluorescent protein (eGFP). The head was shielded to avoid brain radiation exposure during chimera construction. Radiation dose and time response studies were conducted in wild-type chimeras, and additional experiments were performed with chimeras created using donor marrow from CCR2 deficient, eGFP-expressing mice. Infiltrating eGFP+ cells were identified and quantified using immunofluorescent microscopy.ResultsBrain irradiation resulted in a dose- and time-dependent infiltration of BMD immune cells (predominately myeloid) that began at 1 month and persisted until 6 months following ≥15 Gy brain irradiation. Infiltration was limited to areas that were directly exposed to radiation. CCR2 signaling loss resulted in decreased numbers of infiltrating cells at 6 months that appeared to be restricted to cells also expressing major histocompatibility complex class II molecules.ConclusionsThe potential roles played by infiltrating immune cells are of current importance due to increasing interest in immunotherapeutic approaches for cancer treatment and a growing clinical interest in survivorship and quality of life issues. Our findings demonstrate that injury from brain radiation facilitates a dose- and time-dependent recruitment of BMD cells that persists for at least 6 months and, in the case of myeloid cells, is dependent on CCR2 signaling.Electronic supplementary materialThe online version of this article (doi:10.1186/s12974-016-0496-8) contains supplementary material, which is available to authorized users.
Highlights
Cranial radiotherapy is used to treat tumors of the central nervous system (CNS), as well as nonneoplastic conditions such as arterio-venous malformations; its use is limited by the tolerance of adjacent normal CNS tissue, which can lead to devastating long-term sequelae for patients
Staining for MHCII, cluster of differentiation 3 (CD3), and cluster of differentiation 11c (CD11c) was conducted on control and 35-Gy-irradiated tissues at 6 months post-bone marrow transplant (Fig. 1)
Using an unpaired, two-tailed t test with Welch’s correction to compare the number of CD11c+ cells to CD11c+ cells showing co-localization with enhanced green fluorescent protein (eGFP) + (BMD/recruited) revealed a significant reduction in the number of recruited CD11c+ cells in the eGFP+ chemokine receptor type 2 (CCR2)-null chimeras (M = 284.0, SD = 48.6) compared to the eGFP+ CCR2+ chimeras (M = 773.5, SD = 164.4) (t(4) = 2.856, p = 0.0461) despite the overall total numbers of CD11c+ cells remaining the same. These findings strongly suggest that CCR2 signaling plays a role in the recruitment of myeloid CD11c+ cells to the brain following irradiation, but that, in the absence of CCR2 signaling, compensatory mechanisms allow for amplification of the resident microglial (CD11c+) population
Summary
Cranial radiotherapy is used to treat tumors of the central nervous system (CNS), as well as nonneoplastic conditions such as arterio-venous malformations; its use is limited by the tolerance of adjacent normal CNS tissue, which can lead to devastating long-term sequelae for patients. The use of curative doses of radiation is often limited due to the potential for damage in the adjacent and surrounding normal brain tissue. Both acute and late/delayed radiation-induced sequelae can result in significant morbidity and/or mortality for patients, and the pathogenesis of radiation injury in the normal central nervous system (CNS) tissue has been the subject of investigation for decades. The development of specific and targeted therapeutic approaches would require identification of the origin of these CD11c+ and MHC II+ cells, since both populations could originate either from endogenous microglia or from leukocytes that have infiltrated from the periphery
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