Exposing primary rat retina cell cultures to γ-rays: An in vitro model for evaluating radiation responses.

Retinal tissue can receive incidental γ-rays exposure during radiotherapy either of tumors of the eye and optic nerve or of head-and-neck tumors, and during medical diagnostic procedures. Healthy retina is therefore at risk of suffering radiation-related side effects and the knowledge of pathophysiological response of retinal cells to ionizing radiations could be useful to design possible strategies of prevention and management of radiotoxicity. In this study, we have exploited an in vitro model (primary rat retinal cell culture) to study an array of biological effects induced on retinal neurons by γ-rays. Most of the different cell types present in retinal tissue - either of the neuronal or glial lineages - are preserved in primary rat retinal cultures. Similar to the retina in situ, neuronal cells undergo in vitro a maturational development shown by the formation of polarized neuritic trees and operating synapses. Since 2 Gy is the incidental dose received by the healthy retina per fraction when the standard treatment is delivered to the brain, retina cell cultures have been exposed to 1 or 2 Gy of γ-rays at different level of neuronal differentiation in vitro: days in vitro (DIV)2 or DIV8. At DIV9, retinal cultures were analyzed in terms of viability, apoptosis and characterized by immunocytochemistry to identify alterations in neuronal differentiation. After irradiation at DIV2, MTT assay revealed an evident loss of cell viability and ßIII-tubulin immunostaining highlighted a marked neuritic damage, indicating that survived neurons showed an impaired differentiation. Differentiated cultures (DIV8) appeared to be more resistant with respect to undifferentiated, DIV2 cultures, both in terms of cell viability and differentiation. Apoptosis evaluated with TUNEL assay showed that irradiation at both DIV2 and DIV8 induced a significant increase in the apoptotic rate. To further investigate the effects of γ-rays on retinal neurons, we evaluated the expression of synaptic proteins, such as SNAP25 and synaptophysin. WB and immunofluorescence analysis showed an altered expression of these proteins in particular when cultures were irradiated at DIV2. To evaluate the effect of γ-rays on photoreceptors, we studied the expression of rhodopsin in WB analysis and immunofluorescence. Our results confirm data from the literature that differentiated photoreceptors appear to be more resistant to irradiation respect to other retinal cell types present in cultures. The results obtained suggest that γ-rays exposure of primary retinal cultures may contribute to shed further light on the mechanisms involved in γ-radiation-induced neurodegeneration.

The complex interactions between radiation induced non-targeted effects and cancer.

Radiation induced non-targeted effects have been widely investigated in the last two decades for their potential impact on low dose radiation risk. In this paper we will give an overview of the most relevant aspects related to these effects, starting from the definition of the low dose scenarios. We will underline the role of radiation quality, both in terms of mechanisms of interaction with the biological matter and for the importance of charged particles as powerful tools for low dose effects investigation. We will focus on cell communication, representing a common feature of non-targeted effects, giving also an overview of cancer models that have explicitly considered such effects.

Environmental fine particulate matter (PM 2.5) activates the RAW 264.7 macrophage cell line even at very low concentrations as revealed by 1H NMR.

Because of the association between inhalation of airborne particulate matter (PM) and human respiratory and cardiovascular disease, it is necessary to understand the tissue damage induced by these particles. One of the cell types principally involved in the body's reaction to PM are macrophages, which remove particles in the airway passages and the lungs through phagocytosis. In fact, when macrophages are exposed to a toxic agent such as PM, they undergo a series of changes (including variations in morphology, an increase in glycolysis, and consequent lactate production and the release of cytokines such as interleukin-6 and tumor necrosis factor-alpha) necessary to transform them from "resting" to "activated" macrophages. Because (1)H NMR is extremely useful in monitoring, noninvasively, macrophage metabolism and because this technique has never been utilized to examine macrophage activation after exposure to PM, it was the purpose of the present study to investigate the effects of PM exposure on the RAW 264.7 stabilized macrophage cell line using (1)H NMR spectroscopy. PM with a diameter <2.5 microm (PM 2.5) was utilized because a closer association to mortality and adverse respiratory health effects has been found with this fraction than with particles of a larger size. Measurements were conducted on whole cells at both 500 and 700 MHz as well as on perchloric acid extracts at 700 MHz. Significant variations in numerous metabolites were seen at very low concentrations of PM 2.5. Many of these changes point to activation of RAW 264.7 macrophages even at doses of PM 2.5 much lower than those commonly employed in cell studies. These results are particularly significant since the same concentrations of PM did not induce changes in morphology and release of cytokines in these cells. Therefore, (1)H NMR spectroscopy is an extremely sensitive probe in observing subtle variations in macrophages after exposure to PM 2.5.

Modulation of PGE(2) and TNFalpha by nitric oxide and LPS-activated RAW 264.7 cells.

Prostaglandins (PGs), the arachidonic acid (AA) metabolites of the cyclooxygenase (COX) pathway, and the cytokine TNFalpha play major roles in inflammation and they are synthesised mainly by macrophages. Their syntheses have been shown to be regulated by several factors, including nitric oxide, a further important macrophage product. Since both positive and negative regulations of PGs and TNFalpha synthesis by NO have been reported, we sought to understand the mechanisms underlying these opposite NO effects by using a recent class of NO releasing compounds, the NONOates, which have been shown to release NO in a controlled fashion. To this aim, we analysed the effect of NO released from PAPA/NO (t1/2 15 min) and DETA/NO (t1/2 20 h) in RAW 264.7 cells. Both NONOates were used at the same concentrations allowing the cell cultures to be exposed either at high levels of NO for brief time (PAPA/NO) or at low levels of NO for long time (DETA/NO). We found that the two NONOates had opposite effect on basal TNFalpha release, being increased by PAPA/NO and decreased by DETA/NO, while they did not affect the release stimulated by LPS. At variance, both NONOates increased the basal PGE(2) production, while the LPS-stimulated production was slightly increased only by PAPA/NO. The modulation of PGE(2) synthesis was the result of the distinct effects of the two NO-donors on either arachidonic acid (AA) release or cyclooxygense-2 (COX-2) expression, the precursor and synthetic enzyme of PGs, respectively. Indeed, in resting cultures AA release was enhanced only by PAPA/NO whereas COX-2 expression was moderately upregulated by both donors. In LPS activated cells, both NONOates induced AA release, although with different kinetics and potencies, but only DETA/NO significantly increased COX-2 expression. In conclusion, by comparing the activities of these two NONOates, our observations indicate that level and time of exposure to NO are both crucial in determining the molecular target and the final result of the interactions between NO and inflammatory molecules.