Abstract
Radiation-induced lung injury is a highly complex combination of pathological alterations that develop over time and severity of disease development is dose-dependent. Following exposures to lethal doses of irradiation, morbidity and mortality can occur due to a combination of edema, pneumonitis and fibrosis. Protein glycosylation has essential roles in a plethora of biological and immunological processes. Alterations in glycosylation profiles have been detected in diseases ranging from infection, inflammation and cancer. We utilized mass spectrometry imaging to spatially map N-glycans to distinct pathological alterations during the clinically latent period and at 180 days post-exposure to irradiation. Results identified alterations in a number of high mannose, hybrid and complex N-glycans that were localized to regions of mucus and alveolar-bronchiolar hyperplasia, proliferations of type 2 epithelial cells, accumulations of macrophages, edema and fibrosis. The glycosylation profiles indicate most alterations occur prior to the onset of clinical symptoms as a result of pathological manifestations. Alterations in five N-glycans were identified as a function of time post-exposure. Understanding the functional roles N-glycans play in the development of these pathologies, particularly in the accumulation of macrophages and their phenotype, may lead to new therapeutic avenues for the treatment of radiation-induced lung injury.
Highlights
Radiation-induced lung injury is a highly complex combination of pathological alterations that develop over time and severity of disease development is dose-dependent
Radiation-induced lung injury (RILI) is a complex combination of pathologies that include vascular damage, epithelial cell death followed by hyper-proliferation, edema, and mixed immune infiltrations resulting in pneumonitis and an aberrant wound-healing processes that lead to the development of pulmonary fibrosis[1,2,3,4]
Alveolar macrophage accumulation and interstitial thickening can be observed in the middle box and a mixture of alveolar macrophage accumulation and proliferations of type 2 alveolar epithelial cells (AEC2) is shown in the bottom box
Summary
Radiation-induced lung injury is a highly complex combination of pathological alterations that develop over time and severity of disease development is dose-dependent. Results identified alterations in a number of high mannose, hybrid and complex N-glycans that were localized to regions of mucus and alveolar-bronchiolar hyperplasia, proliferations of type 2 epithelial cells, accumulations of macrophages, edema and fibrosis. Radiation-induced lung injury (RILI) is a complex combination of pathologies that include vascular damage, epithelial cell death followed by hyper-proliferation, edema, and mixed immune infiltrations resulting in pneumonitis and an aberrant wound-healing processes that lead to the development of pulmonary fibrosis[1,2,3,4]. Matrix-assisted laser desorption ionization mass spectrometry imaging (MALDI-MSI) is a novel tool that can be used to probe molecular alterations (proteins, lipids, metabolites and glycans) and spatially map the alterations to regions within the pulmonary m icroenvironment[25,26,27,28].
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