Heart irradiation reduces microvascular density and accumulation of HSPA1 in mice.

PURPOSE: Improvement of radiotherapy techniques reduces the exposure of normal tissues to ionizing radiation. However, the risk of radiation-related late effects remains elevated. In the present study, we investigated long-term effects of radiation on heart muscle morphology. MATERIALS AND METHODS: We established a mouse model to study microvascular density (MVD), deposition of collagen fibers, and changes in accumulation of heat shock 70 kDa protein 1 (HSPA1) in irradiated heart tissue. Hearts of C57BL/6 mice received a single dose of X­ray radiation in the range 0.2-16 Gy. Analyses were performed 20, 40, and 60 weeks after irradiation. RESULTS: Reduction in MD was revealed as a long-term effect observed 20-60 weeks after irradiation. Moreover, a significant and dose-dependent increase in accumulation of HSPA1, both cytoplasmic and nuclear, was observed in heart tissues collected 20 weeks after irradiation. We also noticed an increase in collagen deposition in hearts treated with higher doses. CONCLUSIONS: This study shows that some changes induced by radiation in the heart tissue, such as reduction in microvessel density, increase in collagen deposition, and accumulation of HSPA1, are observed as long-term effects which might be associated with late radiation cardiotoxicity.

Local hypoxia in oral mucosa (mouse) during daily fractionated irradiation - Effect of pentoxifylline.

PURPOSE: A significant reduction of radiation-induced oral mucositis by systemic application of pentoxifylline has been demonstrated in a mouse tongue model. However, the underlying mechanisms remain unclear. The present study focuses on the development of local hypoxia in mouse tongue during daily fractionated irradiation and a potential modulation by pentoxifylline. MATERIALS AND METHODS: Daily fractionated irradiation with 5×3Gy/week (days 0-4, 7-11) was given to the snouts of mice. Groups of 3 animals per day were sacrificed between day 0 and 14. Pentoxifylline (15mg/kg, s.c.) was administered daily from day -5 to the day before the mice were sacrificed. The expression of intrinsic hypoxia markers HIF-1α and GLUT1 in the epithelium of the lower tongue surface was analysed by immunohistochemistry in 3 animals per day; the percentage of positive epithelial cells and the staining intensity were analysed as endpoints. RESULTS: Compared to untreated control tissue, fractionated irradiation resulted in a progressive increase in the expression of both hypoxia markers. This effect was significantly reduced by pentoxifylline. CONCLUSION: An early onset of local hypoxia occurs during fractionated irradiation in mouse tongue epithelium. The effect is markedly reduced by the mucoprotective agent pentoxifylline, suggesting a mucositis-promoting role of hypoxia; this, however, deserves further investigation.

Modulation of radiation-induced oral mucositis by pentoxifylline: preclinical studies.

BACKGROUND AND PURPOSE: Oral mucositis is a frequent early side effect of radio(chemo)therapy of head-and-neck malignancies. The epithelial radiation response is accompanied by inflammatory reactions; their interaction with epithelial processes remains unclear. The aim of the present study was to investigate the effect of pentoxifylline (PTX) on the oral mucosal radiation response in the mouse tongue model. MATERIALS AND METHODS: Irradiation comprised fractionation (5 fractions of 3 Gy/week) over 1 (days 0-4) or 2 weeks (days 0-4, 7-11), followed by graded local top-up doses (day 7/14), in order to generate complete dose-effect curves. PTX (15 mg/kg subcutaneously) was applied once daily over varying time intervals. Ulceration of mouse tongue epithelium, corresponding to confluent mucositis, was analyzed as the clinically relevant endpoint. RESULTS: With fractionated irradiation over 1 week, PTX administration significantly reduced the incidence of mucosal reactions when initiated before (day-5) the onset of fractionation; a trend was observed for start of PTX treatment on day 0. Similarly, PTX treatment combined with 2 weeks of fractionation had a significant effect on ulcer incidence in all but one experiment. This clearly illustrates the potential of PTX to ameliorate oral mucositis during daily fractionated irradiation. CONCLUSION: PTX resulted in a significant reduction of oral mucositis during fractionated irradiation, which may be attributed to stimulation of mucosal repopulation processes. The biological basis of this effect, however, needs to be clarified in further, detailed mechanistic studies.

Epac contributes to cardiac hypertrophy and amyloidosis induced by radiotherapy but not fibrosis.

BACKGROUND: Cardiac toxicity is a side-effect of anti-cancer treatment including radiotherapy and this translational study was initiated to characterize radiation-induced cardiac side effects in a population of breast cancer patients and in experimental models in order to identify novel therapeutic target. METHODS: The size of the heart was evaluated in CO-HO-RT patients by measuring the Cardiac-Contact-Distance before and after radiotherapy (48months of follow-up). In parallel, fibrogenic signals were studied in a severe case of human radiation-induced pericarditis. Lastly, radiation-induced cardiac damage was studied in mice and in rat neonatal cardiac cardiomyocytes. RESULTS: In patients, time dependent enhancement of the CCD was measured suggesting occurrence of cardiac hypertrophy. In the case of human radiation-induced pericarditis, we measured the activation of fibrogenic (CTGF, RhoA) and remodeling (MMP2) signals. In irradiated mice, we documented decreased contractile function, enlargement of the ventricular cavity and long-term modification of the time constant of decay of Ca(2+) transients. Both hypertrophy and amyloid deposition were correlated with the induction of Epac-1; whereas radiation-induced fibrosis correlated with Rho/CTGF activation. Transactivation studies support Epac contribution in hypertrophy stimulation and showed that radiotherapy and Epac displayed specific and synergistic signals. CONCLUSION: Epac-1 has been identified as a novel regulator of radiation-induced hypertrophy and amyloidosis but not fibrosis in the heart.

Ionising radiation induces persistent alterations in the cardiac mitochondrial function of C57BL/6 mice 40 weeks after local heart exposure.

BACKGROUND AND PURPOSE: Radiotherapy of thoracic and chest-wall tumours increases the long-term risk of radiation-induced heart disease. The aim of this study was to investigate the long-term effect of local heart irradiation on cardiac mitochondria. METHODS: C57BL/6 and atherosclerosis-prone ApoE(-/-) mice received local heart irradiation with a single X-ray dose of 2 Gy. To investigate the low-dose effect, C57BL/6 mice also received a single heart dose of 0.2 Gy. Functional and proteomic alterations of cardiac mitochondria were evaluated after 40 weeks, compared to age-matched controls. RESULTS: The respiratory capacity of irradiated C57BL/6 cardiac mitochondria was significantly reduced at 40 weeks. In parallel, protein carbonylation was increased, suggesting enhanced oxidative stress. Considerable alterations were found in the levels of proteins of mitochondria-associated cytoskeleton, respiratory chain, ion transport and lipid metabolism. Radiation induced similar but less pronounced effects in the mitochondrial proteome of ApoE(-/-) mice. In ApoE(-/-), no significant change was observed in mitochondrial respiration or protein carbonylation. The dose of 0.2 Gy had no significant effects on cardiac mitochondria. CONCLUSION: This study suggests that ionising radiation causes non-transient alterations in cardiac mitochondria, resulting in oxidative stress that may ultimately lead to malfunctioning of the heart muscle.

Enhanced sensitivity to low dose irradiation of ApoE-/- mice mediated by early pro-inflammatory profile and delayed activation of the TGFß1 cascade involved in fibrogenesis.

AIM: Investigating long-term cardiac effects of low doses of ionizing radiation is highly relevant in the context of interventional cardiology and radiotherapy. Epidemiological data report that low doses of irradiation to the heart can result in significant increase in the cardiovascular mortality by yet unknown mechanisms. In addition co-morbidity factor such as hypertension or/and atherosclerosis can enhance cardiac complications. Therefore, we explored the mechanisms that lead to long-term cardiac remodelling and investigated the interaction of radiation-induced damage to heart and cardiovascular systems with atherosclerosis, using wild-type and ApoE-deficient mice. METHODS AND RESULTS: ApoE-/- and wild-type mice were locally irradiated to the heart at 0, 0.2 and 2 Gy (RX). Twenty, 40 and 60 weeks post-irradiation, echocardiography were performed and hearts were collected for cardiomyocyte isolation, histopathological analysis, study of inflammatory infiltration and fibrosis deposition. Common and strain-specific pathogenic pathways were found. Significant alteration of left ventricular function (eccentric hypertrophy) occurred in both strains of mice. Low dose irradiation (0.2 Gy) induced premature death in ApoE-/- mice (47% died at 20 weeks). Acute inflammatory infiltrate was observed in scarring areas with accumulation of M1-macrophages and secretion of IL-6. Increased expression of the fibrogenic factors (TGF-ß1 and PAI-1) was measured earlier in cardiomyocytes isolated from ApoE-/- than in wt animals. CONCLUSION: The present study shows that cardiac exposure to low dose of ionizing radiation induce significant physiological, histopathological, cellular and molecular alterations in irradiated heart with mild functional impairment. Atherosclerotic predisposition precipitated cardiac damage induced by low doses with an early pro-inflammatory polarization of macrophages.

Radiation-induced signaling results in mitochondrial impairment in mouse heart at 4 weeks after exposure to X-rays.

BACKGROUND: Radiation therapy treatment of breast cancer, Hodgkin's disease or childhood cancers expose the heart to high local radiation doses, causing an increased risk of cardiovascular disease in the survivors decades after the treatment. The mechanisms that underlie the radiation damage remain poorly understood so far. Previous data show that impairment of mitochondrial oxidative metabolism is directly linked to the development of cardiovascular disease. METHODOLOGY/PRINCIPAL FINDINGS: In this study, the radiation-induced in vivo effects on cardiac mitochondrial proteome and function were investigated. C57BL/6N mice were exposed to local irradiation of the heart with doses of 0.2 Gy or 2 Gy (X-ray, 200 kV) at the age of eight weeks, the control mice were sham-irradiated. After four weeks the cardiac mitochondria were isolated and tested for proteomic and functional alterations. Two complementary proteomics approaches using both peptide and protein quantification strategies showed radiation-induced deregulation of 25 proteins in total. Three main biological categories were affected: the oxidative phophorylation, the pyruvate metabolism, and the cytoskeletal structure. The mitochondria exposed to high-dose irradiation showed functional impairment reflected as partial deactivation of Complex I (32%) and Complex III (11%), decreased succinate-driven respiratory capacity (13%), increased level of reactive oxygen species and enhanced oxidation of mitochondrial proteins. The changes in the pyruvate metabolism and structural proteins were seen with both low and high radiation doses. CONCLUSION/SIGNIFICANCE: This is the first study showing the biological alterations in the murine heart mitochondria several weeks after the exposure to low- and high-dose of ionizing radiation. Our results show that doses, equivalent to a single dose in radiotherapy, cause long-lasting changes in mitochondrial oxidative metabolism and mitochondria-associated cytoskeleton. This prompts us to propose that these first pathological changes lead to an increased risk of cardiovascular disease after radiation exposure.

Effect of selective inhibitors of inflammation on oral mucositis: preclinical studies.

OBJECTIVE: Oral mucositis is a severe, dose-limiting side effect of radio(chemo)therapy for head and neck tumors. The epithelial radiation response (ulceration) is accompanied by inflammatory changes. Their interaction with the epithelial processes remains unclear. The present study was initiated to determine the effect of inhibition of TNF-alpha or COX-2 on the epithelial radiation response in the mouse tongue model. METHODS: Daily fractionated irradiation was given with 5 x 3 Gy/week over one (days 0-4) or two weeks (days 0-4, 7-11). Each protocol was terminated by graded test doses (5 dose groups, 10 animals each) to a defined area of the lower tongue surface to generate full dose-effect curves for mucosal ulceration. A TNF-alpha inhibiting antibody (Infliximab) or a COX-2 inhibitor (Celecoxib) was administered. RESULTS: No effect of Infliximab or Celecoxib was found in any of the protocols. Isoeffective doses for ulcer induction were unchanged. Also, the time course of the response was largely unaffected. CONCLUSIONS: Inhibition of TNF-alpha or COX-2, two dominating inflammatory pathways, did not result in modulation of the response of oral epithelium during fractionated irradiation. This suggests that the inflammatory changes mediated through TNF-alpha or COX-2 are not relevant for the epithelial radiation response of oral mucosa.