X-rays enhance Fe2+-mediated oxidative membrane damage in OUMS-36T-1 fibroblasts, supported by the liposome model
Shinya Kato

TL;DR
X-rays increase Fe2+-caused oxidative damage to cell membranes in fibroblasts, suggesting a link to ferroptosis and tissue repair.
Contribution
Demonstrates that X-rays enhance Fe2+-mediated oxidative membrane damage, supported by a liposome model.
Findings
Fe2+ at 40 µM caused sublethal oxidative stress without membrane rupture in fibroblasts.
X-ray irradiation increased Fe2+-induced membrane damage and lipid peroxidation.
Citric acid and glutathione reduced the observed effects, indicating redox-dependent processes.
Abstract
Ferroptosis is a regulated form of cell death driven by iron-dependent membrane lipid peroxidation, with ferrous ions (Fe2+) and reactive oxygen species playing central roles. Although X-rays are known to generate free radicals via water radiolysis, their role in ferroptosis-related oxidative membrane injury remains unclear. The present study investigated the effects of Fe2+ on membrane damage in OUMS-36T-1 human fibroblasts under X-ray irradiation. DOPC/DOPS (8:2 mol/mol) liposomes were employed as a simplified membrane model to explore the underlying mechanisms. In vitro, Fe2+ at 1-40 µM promoted cell proliferation up to 10 µM, whereas higher concentrations of Fe2+ reduced cell viability. At 40 µM Fe2+, intracellular reactive oxygen species and lipid peroxidation levels were elevated; however, lactate dehydrogenase leakage was not observed, suggesting sublethal oxidative stress…
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TopicsElectron Spin Resonance Studies · Metal-Catalyzed Oxygenation Mechanisms · Lipid Membrane Structure and Behavior
Introduction
Regulated cell death pathways play critical roles in maintaining physiological homeostasis and contributing to disease progression. Among these pathways, ferroptosis has attracted considerable attention due to its distinctive mechanisms and pathological relevance. In addition to canonical ferroptotic cell death, iron-dependent lipid peroxidation can also cause sublethal oxidative membrane injury that affects cellular function without necessarily inducing ferroptosis. First identified by Dixon et al (1) in 2012, ferroptosis is a form of regulated cell death characterized by iron-dependent lipid peroxidation, primarily driven by reactive oxygen species via the Fenton reaction. This process is initiated by ferrous ions (Fe^2+^), a key factor in ferroptosis. Ferroptosis is a promising strategy for cancer therapy, and efforts have been made to explore mechanisms that activate key regulatory pathways to induce ferroptosis. Elastin, an elastic protein in the dermis, has been shown to induce ferroptosis by inhibiting cystine transporters, reducing glutathione (GSH) synthesis, and promoting the generation of reactive oxygen species (2). As previously demonstrated., under X-ray irradiation, the administration of elastin decreases GSH levels and glutathione peroxidase 4 (GPX4) expression, thereby enhancing cell death in HeLa and adenocarcinoma cell lines and a tumor xenograft model (3). Previous studies have indicated that oxygen levels and iron modulation, including nanoform iron or iron chelators, influence ferroptosis in cancer cells under X-ray irradiation. Hyperbaric oxygen could sensitize radioresistant oral squamous cell carcinoma cells to X-rays by promoting ferroptosis and reducing tumor growth in xenograft mice (4). On the other hand, deferoxamine weakly binds free iron and inhibits ferroptosis in bone marrow nucleated cells of X-ray-irradiated mice, thereby facilitating hematopoiesis in bone marrow (5). A nanocarrier composed of a hyperbranched copolymer with ^1^O_2_-sensitive linkers and a RAS-selective lethal agent triggers ^1^O_2_-mediated GSH depletion and GPX4 inactivation, leading to ferroptotic cell death in breast cancer-bearing mice (6).
Fibroblasts are cells found in connective tissue and become activated by inflammatory cytokines when tissue damage occurs due to radiation (7). As fibroblasts play a central role in radiation-induced fibrosis, wound healing and long-term normal tissue responses, understanding oxidative membrane injury in these cells is particularly relevant in radiobiology. Activated fibroblasts produce components such as collagen and fibronectin, which serve as scaffolds for cells in the damaged tissue, thereby promoting tissue regeneration (8). As previously demonstrated, when human fibroblasts were irradiated with 20 Gy X-rays, mitochondria-dependent energy metabolism increased, and the cells underwent cell-cycle arrest (9). Therapeutic levels of radiation have cytotoxic effects on most cancer cells, inhibiting proliferation and inducing apoptosis (10). Irradiation with X-rays causes DNA damage, triggers mitochondrial signaling and AMP-activated protein kinase activity, suppresses mitochondrial metabolism and increases reactive oxygen species production in lung fibroblasts cultured under 5 and 20% O_2_ (11). Moreover, fibroblasts treated with a low dose of 550 µGy X-rays have been shown to exhibit increased cell proliferation and protein production (12).
Liposomes containing phosphatidylcholine hydroperoxide induce ferroptosis by targeting divalent metal transporter 1, which promotes lysosomal Fe^2+^ efflux in breast cancer cells and xenografts (13). Prussian blue (Fe^3+^-CN^-^-Fe^2+^) and hyaluronic acid-based nanoparticles have been shown to induce ferroptosis, enhancing therapeutic efficacy under 6 Gy X-rays in human lung carcinoma and melanoma cells (14). Liposomes have been used to induce ferroptosis under radiation exposure; however, their interactions with Fe^2+^ under X-rays remain poorly understood, and fundamental insights are lacking. In this context, simplified liposome systems provide a reductionist approach to isolate Fe^2+^-driven lipid peroxidation at membrane surfaces, rather than to recapitulate full cellular ferroptosis pathways.
The author has recently investigated cell growth inhibition in glioblastoma and neuroblastoma cells using lithium carbonate or platinum nano colloids under X-rays (15-17). While X-rays generate free radicals from water radiolysis (18), the role of Fe^2+^ in promoting the oxidation of lipid membranes and ferroptosis-related oxidative membrane damage is yet to be clarified. Alternatively, liposomes serve as a lipid membrane model reflecting membrane lipid peroxidation in ferroptosis research. The present study employed liposomes composed of the unsaturated lipids, L-α-dioleoylphosphatidylcholine (DOPC) and L-α-dioleoylphosphatidylserine (DOPS), at an 8:2 molar ratio as a lipid membrane model, without cholesterol, proteins, or antioxidant enzymes. The present study focused on early oxidative membrane damage and lipid peroxidation as mechanistic events associated with ferroptosis, rather than on establishing definitive ferroptotic cell death. The present study investigated the impact of Fe^2+^ on cell membrane damage in human fibroblast OUMS-36T-1 cells treated with X-rays, complemented by model experiments on membrane lipid peroxidation and Fe^2+^ oxidation using DOPC/DOPS (8:2 mol/mol) liposomes.
Materials and methods
Cells and cell culture
The OUMS-36T-1 cell line, an hTERT gene-transfected normal human embryo fibroblast, was obtained from the JCRB cell bank (cat. no. JCRB1006.1). The OUMS-36T-1 cells were cultured in Dulbecco's modified Eagle's (DMEM) medium with L-glutamine (FUJIFILM Wako Pure Chemical Corp.) supplemented with 10% fetal bovine serum (S-FBS-NL-015; Serana Europe GmbH) and penicillin-streptomycin-amphotericin B suspension (FUJIFILM Wako Pure Chemical Corp.) at 37˚C with 5% CO_2_.
Cell proliferation assay using WST-8
Cell proliferation was evaluated using the WST-8 assay, which utilises a water-soluble tetrazolium salt (19). The OUMS-36T-1 cells were seeded at 2,000 cells/well in a 96-well culture plate (Sumitomo Bakelite Co., Ltd.) with n=5 wells and incubated for 24 h at 37˚C with 5% CO_2_. Ferrous chloride tetrahydrate (Fe^2+^; FUJIFILM Wako Pure Chemical Corp.) or ferric chloride hexahydrate (Fe^3+^; FUJIFILM Wako Pure Chemical Corp.) were administered at 0-40 µM. Fresh Fe^2+^ solutions were prepared immediately prior to each experiment to minimize spontaneous oxidation to Fe^3+^ under culture conditions. The cells were exposed to 4 Gy X-rays (CAX-150-20; Chubu Medical Co., Ltd.; 150 kV-20 mA, 1 mm Al + 0.1 mm Cu filters, 0.60 Gy/min) and incubated for 3 days at 37˚C with 5% CO_2_. A single dose of 4 Gy was selected as a representative moderate-to-high dose commonly used in in vitro radiobiological studies to reliably induce oxidative stress (15), while maintaining sufficient cell viability for early mechanistic analyses. The medium was replaced with 5% of 2-(2-methoxy-4-nitrophenyl)-3-(4-nitrophenyl)-5-(2,4-disulfophenyl)-2H-tetrazolium (WST-8; Dojindo Laboratories) diluted with DMEM medium and incubated for 1.5 h at 37˚C with 5% CO_2_. The absorbance at 450 nm, corresponding to the formation of yellowish-orange formazan resulting from the reduction of WST-8 by intracellular mitochondrial dehydrogenase, was measured using a multi-spectrophotometer (Viento; Dainippon Sumitomo Pharma Co., Ltd.). The cells were then stained with Hoechst 33342 (Dojindo Laboratories) at room temperature for 15 min and observed using a fluorescence microscope (BZ-X710; KEYENCE Corporation) at x200 magnification with Ex/Em: 350/461 nm.
Analysis of intracellular reactive oxygen species using dichlorodihydrofluorescein diacetate (DCFH-DA)
Ferrous ion (Fe^2+^) concentrations (0-40 µM) were selected based on preliminary concentration-response experiments (data not shown) assessing cell proliferation and oxidative stress. A concentration of 40 µM was used as a threshold condition that induces intracellular oxidative stress and lipid peroxidation without causing overt membrane rupture in the absence of X-ray irradiation. Intracellular reactive oxygen species levels were evaluated using DCFH-DA (20). The OUMS-36T-1 cells were seeded at 3,500 cells/well in a 96-well culture plate with n=5 wells and incubated as described above. The DCFH-DA solution (ROS Assay Kit-Highly Sensitive DCFH-DA; Dojindo Laboratories) was added to each well and incubated for 30 min at 37˚C with 5% CO_2_. After aspirating the medium, Fe^2+^ was administered at 40 µM, either alone or combined with trisodium citrate dihydrate (FUJIFILM Wako Pure Chemical Corp.) or reduced glutathione (GSH; FUJIFILM Wako Pure Chemical Corp.) at 40-120 µM. Following incubation for 0.2 h at 37˚C with 5% CO_2_, the cells were exposed to 4 Gy X-rays. The early time point (0.2 h) was selected to capture immediate oxidative responses at the membrane level, prior to the onset of secondary transcriptional or cell-death-related processes. To prevent light-induced auto-oxidation of the probe, all experiments using DCFH-DA were performed on black plates with room lights turned off and under dark conditions. The fluorescence intensity was measured at 0.2 h following X-ray irradiation using a multimode microplate reader (TriStar LB941; Berthold Technologies GmbH & Co. KG) at Ex/Em: 485/535 nm. Fluorescence intensity indicates intracellular reactive oxygen species levels, since DCFH-DA is enzymatically converted to DCFH, which is rapidly oxidized by reactive oxygen species into the fluorescent products.
Membrane lipid peroxidation detection and lactate dehydrogenase leakage
The disruption of the cell membrane was assessed by membrane lipid peroxidation and lactate dehydrogenase leakage. The OUMS-36T-1 cells were seeded at 3,500 cells/well and incubated as mentioned in 2.2. Fe^2+^ was administered at 40 µM, either alone or combined with trisodium citrate dihydrate or reduced glutathione at 40-120 µM. N-(4-Diphenylphosphinophenyl)-N'-(3,6,9,12-tetraoxatridecyl) perylene-3,4,9,10-tetracarboxydiimide (Liperfluo, Dojindo Laboratories) was added to each well at 7.5 µmol/l for the detection of lipid hydroperoxides (21). Following 0.2 h of incubation at 37˚C with 5% CO_2_, the cells were exposed to 4 Gy of X-rays. After 0.2 h, fluorescence intensity, which is proportional to lipid peroxide in membrane lipids, was measured at Ex/Em=485/535 nm with the multimode microplate reader TriStar LB941. This early measurement was intended to assess primary membrane lipid peroxidation induced by Fe^2+^ and X-rays.
On the other hand, following irradiation with 4 Gy X-rays, the cells were incubated for 21 h at 37˚C with 5% CO_2_. The cell culture medium was then replaced with DMEM containing the cytotoxicity LDH assay kit (Dojindo Laboratories), and the mixture was incubated for 0.5 h at room temperature in the dark. The absorbance at 490 nm, which is proportional to lactate dehydrogenase leakage (22), was measured with the multi-spectrophotometer Viento (Dainippon Sumitomo Pharma, Co. Ltd.).
Preparation of liposomes
Liposomes composed of DOPC and DOPS at an 8:2 molar ratio were prepared by mixing 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC; NOF Corp.) and 1,2-dioleoyl-sn-glycero-3-phospho-L-serine (DOPS; NOF Corp.). A phospholipid thin film was formed by evaporating the chloroform solution of DOPC/DOPS (8:2) under reduced pressure using a custom apparatus developed by Dr Yoshimura [image of the device is shown in a previous study by the author (23)]. The resulting film was rehydrated in phosphate-buffered saline at pH 7.2 (PBS (-), FUJIFILM Wako Pure Chemical Corp.). The average particle diameter and zeta potential were 134 nm and -15.3 mV, respectively, as measured using a zeta potential and particle size analyzer (ELSZ-2; Otsuka Electronics Co. Ltd.).
Analysis of membrane lipid peroxidation using Liperfluo
The DOPC/DOPS (8:2) liposomes were added at 100 µM in a 96-well culture plate with n=5 wells. Fe^2+^ or Fe^3+^ was added at 0-50 µM, and Liperfluo was added to each well at 7.5 µmol/l. The plate was left to stand for 0.5 h, and then exposed to 4 Gy of X-rays. After 0.2 h, the fluorescence intensity was measured as described above.
Oxidation of ferrous ion using the Nitroso-PSAP method
The DOPC/DOPS (8:2) liposomes were added at 100 µM in a 1/2 area 96-well plate (UV-STAR; Greiner Bio-One International GmbH) with n=5 wells. Assays were performed under conditions containing or lacking the DOPC/DOPS (8:2) liposomes. Fe^2+^ or Fe^3+^ was added at 50 µM, and nitroso-N, N-dimethyl-p-phenylenediamine (Nitroso-PSAP; Dojindo Laboratories) was added to each well at 0.004 w/v% for the detection of ferrous ions (Fe^2+^) (24). The plate was left to stand for 0.2 h, and then exposed to 4 Gy X-rays. After 0.2 h, the absorbance at 750 nm, corresponding to the residual ferrous ions (Fe^2+^), was measured using the multi-spectrophotometer Viento (Dainippon Sumitomo Pharma, Co. Ltd.).
Statistical analysis
Data are presented as the mean ± standard deviation (SD), n=5 wells. Statistical analyses were performed using one-way analysis of variance (ANOVA) followed by Tukey's honestly significant difference (HSD) test for comparisons with the corresponding control group. For two-group comparisons, the Student's t-test was used. A value of P<0.05 was considered to indicate a statistically significant difference.
Results
The present study investigated the effects of X-rays on iron-dependent oxidative membrane damage relevant to ferroptosis by assessing intracellular levels of reactive oxygen species, membrane lipid peroxidation and lactate dehydrogenase leakage from human fibroblasts treated with ferrous ion (Fe^2+^) and X-rays.
Effects of Fe2+ and Fe3+on cell proliferation
Cell proliferation increased to 145.8% as the concentration of Fe^2+^ rose from 0 to 10 µM (Fig. 1), but decreased at higher concentrations, reaching 90.9% at 40 µM. Exposure to 4 Gy X-rays alone reduced cell proliferation to 85.6%. Combined treatment with Fe^2+^ and X-rays resulted in a concentration-dependent decline in cell proliferation, reaching a minimum of 26.5% at 40 µM. These trends were confirmed through fluorescence microscopy (Fig. 1). By contrast, ferric ion (Fe^3+^) had a minimal effect on cell viability. Cell proliferation remained at 107.5% at 40 µM Fe^3+^ and decreased to 65.6% following X-ray irradiation, which was comparable to the untreated control (Fig. 1). This indicates that Fe^3+^ alone did not impair cell proliferation.
Effects of Fe2+ on the generation of intracellular reactive oxygen species, membrane lipid peroxidation and lactate dehydrogenase leakage
The present study then examined the effects of 40 µM Fe^2+^ on the generation of intracellular reactive oxygen species, membrane lipid peroxidation and lactate dehydrogenase leakage. Fe^2+^ was added extracellularly; however, based on the observed increases in intracellular reactive oxygen species and lipid peroxidation, it was hypothesized that Fe^2+^ may have contributed, directly or indirectly, to intracellular oxidative processes.
The levels of intracellular reactive oxygen species increased to 113.1% with Fe^2+^ alone and to 109.0% following X-ray irradiation (Fig. 2). The combination of Fe^2+^ and X-rays further elevated reactive oxygen species to 118.9%, suggesting a synergistic effect (Fig. 2). When trisodium citrate, a chelator of Fe^2+^, was added at molar ratios of 1:1 to 1:3 (Fe^2+^: citrate), intracellular reactive oxygen species decreased from 116.9 to 110.3%. Similarly, treatment with reduced GSH lowered intracellular reactive oxygen species from 109.4% to near baseline (Fig. 2).
A similar trend was observed in membrane lipid peroxidation. Treatment with 40 µM Fe^2+^ increased lipid peroxidation to 108.7%, and X-ray irradiation alone elevated it to 105.1% (Fig. 2). Combined treatment further increased it to 113.5%. Trisodium citrate and reduced GSH were more effective in suppressing lipid peroxidation than intracellular reactive oxygen species, reducing membrane lipid peroxidation to 102.9 and 98.5%, respectively (Fig. 2). These results indicate that Fe^2+^-induced oxidative stress is especially significant near membrane surfaces or within lipid-rich microenvironments.
The leakage of lactate dehydrogenase, a marker for loss of membrane integrity, increased with rising concentrations of Fe^2+^, reaching 1.9-fold at 40 µM (Fig. 3). When combined with X-rays, the lactate dehydrogenase leakage increased to 3.2-fold compared to the control, indicating exacerbated membrane disruption. Fe^3+^ at the same concentration did not increase lactate dehydrogenase leakage, further highlighting the distinct effects of Fe^2+^ (Fig. 3).
DOPC and DOPS model membranes
Subsequently, model membranes composed of DOPC and DOPS in an 8:2 molar ratio were prepared to investigate membrane-specific oxidative stress further. The resulting liposomes had an average diameter of 134 nm and a zeta potential of -15.3 mV (Fig. 4). The presence of anionic lipids such as DOPS likely facilitates electrostatic interactions with Fe^2+^, while the unsaturated acyl chains of DOPC contribute to high membrane fluidity, rendering the system more susceptible to lipid peroxidation. While lipid droplets have been proposed to buffer ferroptotic stress by sequestering iron or storing lipophilic antioxidants, our study focused on phospholipid bilayer liposomes as a model of membrane lipids. Thus, the observed effects mainly reflect direct Fe^2+^/X-ray interactions with phospholipid membranes rather than lipid droplet-mediated mechanisms.
Effects of Fe2+ on lipid peroxidation
Lipid peroxidation in 100 µM liposomes, measured using Liperfluo, increased with Fe^2+^ treatment, reaching 261.1% at a concentration of 50 µM (Fig. 5). X-ray exposure alone increased peroxidation to 133.6%, and the combination of Fe^2+^ and X-rays further elevated it to 330.4%. Fe^2+^ induced a more modest increase and exhibited less synergy with X-rays, indicating that Fe^2+^ has greater redox activity under X-ray exposure.
To investigate the oxidation of Fe^2+^, its residual concentration was measured using the Nitroso-PSAP method. A calibration curve was confirmed to be linear in the range of 0-80 µM we measured Fe^2+^ before measurements (Fig. 5). Upon adding 100 µM liposomes to 50 µM Fe^2+^, the detectable amount of Fe^2+^ was 3.65 µM. X-ray exposure alone reduced Fe^2+^ to 2.95 µM, and the combination of liposomes and X-rays further reduced it to 1.80 µM (Fig. 6). Scatter plot data were fitted with linear trendlines, and the calibration curve shown in Fig. 6 was obtained using the linear regression (least-squares) function in Microsoft Excel.
Discussion
The results of the present study demonstrated that Fe^2+^ at low concentrations promoted fibroblast proliferation; however, at higher concentrations, it induced oxidative stress and membrane damage, with X-ray exposure amplifying these effects. By contrast, Fe^3+^ had a minimal effect, underscoring the distinct redox activity of Fe^2+^. While the present study did not directly assess canonical ferroptosis markers, such as GPX4 or acyl-CoA synthetase long-chain family member 4 (ACSL4), the observed iron-dependent lipid peroxidation and membrane damage are consistent with early ferroptosis-related oxidative processes.
It is known that Fe^2+^ rapidly binds to intracellular proteins, such as ferritin and transferrin, thereby modulating its redox activity (25). These mechanisms may help explain the oxidative stress observed herein, although further experiments are required for direct validation. In addition, lysosomal iron release under oxidative stress has been reported as a potential contributor to cytosolic Fe^2+^ accumulation and lipid peroxidation (26,27). The results of the present study suggest that Fe^2+^ plays a central role in oxidative stress generation, likely via Fenton-type reactions (1,28). Although the present study did not verify lysosomal escape, future studies using lysosomal markers or inhibitors may clarify this mechanism.
Previous studies have reported that lipophilic antioxidants, such as ferrostatin-1 and liproxstatin-1 inhibit the Fe^2+^-driven peroxidation of polyunsaturated phospholipids during ferroptosis (29). Although reduced GSH is a hydrophilic and non-lipid-permeable antioxidant, it significantly suppressed lipid peroxidation in the present study. It was noted that physiological intracellular reduced GSH concentrations are generally in the millimolar range (30), whereas the supplementation in the present study was at the micromolar level. The observed protective effect may therefore reflect localized antioxidant enhancement or the stabilization of extracellular Fe^2+^, rather than a direct mimic of intracellular reduced GSH levels. This effect is likely attributable to the antioxidant properties of extracellular reduced GSH, which may scavenge reactive oxygen species generated under X-ray irradiation and Fe^2+^ exposure, thereby suppressing lipid peroxidation at the plasma membrane. Therefore, the GSH effects observed herein should be interpreted within the context of an in vitro model, rather than as a direct representation of intracellular antioxidant regulation.
Cell membranes, rich in polyunsaturated fatty acids, are highly susceptible to lipid peroxidation, a key trigger of ferroptosis following irradiation (31). It has been shown that 8 Gy X-rays induce significant membrane lipid peroxidation in human skin fibroblasts, as evidenced by the accumulation of malondialdehyde (32). Furthermore, X-ray exposure affects the utilization of reduced GSH and increases mitochondrial reactive oxygen species, ultimately disrupting cellular redox balance (33). Previous research using ultraviolet A has also demonstrated close associations among reactive oxygen species production, lipid peroxidation and lactate dehydrogenase leakage in fibroblasts (34). The findings of the present study are consistent with these reports, confirming that oxidative stress plays a central role in radiation-induced membrane damage. Notably, while Fe^2+^ alone induced oxidative stress and inhibited cell proliferation, significant membrane lipid peroxidation was only observed when Fe^2+^ was combined with X-ray irradiation, suggesting a synergistic cytotoxic effect.
The present study used DOPC/DOPS (8:2) liposomes as a model system to evaluate membrane-specific oxidative stress. These anionic, highly fluid membranes are expected to interact electrostatically with Fe^2+^. They are prone to lipid peroxidation (23), allowing the focus on direct Fe^2+^/X-ray effects on phospholipid bilayers, rather than lipid droplet-mediated mechanisms.
Consistent with this expectation, both Fe^2+^ and X-ray exposure enhanced lipid peroxidation, and their combination had a synergistic effect, whereas Fe^3+^ induced only modest changes. This indicates that Fe^2+^ possesses higher redox activity under X-rays and is a more potent driver of membrane damage. Notably, Fe^2+^ concentration measurements revealed accelerated oxidation to Fe^3+^ in the presence of membranes and X-rays, supporting the notion that phospholipid bilayers facilitate iron redox cycling. This behavior qualitatively resembles the mechanism of the Fricke dosimeter, in which irradiation drives the Fe^2+^ → Fe^3+^ conversion. These findings highlight that membrane environments are not passive targets, but active modulators of iron redox chemistry. Notably, previous research has shown that the Fenton reaction at air-water interfaces proceeds over 1,000 times faster than in bulk solution, producing high-valent iron-oxo species (Fe(IV)=O) without generating hydroxyl radicals (35). This is likely due to partial solvation and to increased accessibility of oxidants, such as hydrogen peroxide, to the iron center at the interface. In a related study, lactoferrin enhanced the Fenton reaction and increased hydroxyl radical production under X-ray exposure (15), suggesting that iron-binding proteins may influence oxidative reactions in biological systems. In the present study, it was observed that X-ray exposure promoted Fe^2+^ oxidation in the presence of DOPC/DOPS (8:2) liposomes, supporting the hypothesis that cellular or membrane-like environments modulate redox reactions involving Fe^2+^.
In cancer settings, such as clear cell renal cell carcinoma (ccRCC), the composition of lipid droplets (e.g., the enrichment of polyunsaturated fatty acids vs. monounsaturated fatty acids) and the accumulation of droplets have been reported to influence ferroptosis sensitivity (36,37). While the fibroblast and liposome system used herein does not directly address this mechanism, these findings highlight how membrane lipid composition can broadly shape susceptibility to ferroptosis. Furthermore, long non-coding RNAs (lncRNAs), such as LINC00336 and MALAT1 have been shown to regulate ferroptosis by sponging miRNAs in cancer models (38). In ccRCC, ferroptosis-related genes, such as ACSL4 have been identified as potential regulatory targets (39). Key effectors of ferroptosis, including GPX4 and ACSL4, may be regulated by lncRNA-miRNA networks in specific cancer contexts. Although these regulatory pathways were not addressed in the present fibroblast-based model, they illustrate how membrane lipid oxidation may intersect with broader ferroptosis regulatory networks in cancer contexts.
In summary, in the present study, Fe^2+^ promoted cell proliferation at low concentrations, whereas it induced oxidative stress and membrane damage at higher concentrations, effects that were amplified by X-ray exposure. Antioxidants suppressed these effects, and a liposome model confirmed that the membrane is involved in Fe^2+^ oxidation. These findings provide insight into ferroptosis mechanisms and highlight the therapeutic potential and environmental risks associated with iron and ionizing radiation.
In conclusion, the present study reveals a synergistic effect of Fe^2+^ and X-rays in promoting oxidative membrane damage in a fibroblast complemented by a liposome model. Fe^2+^ induces lipid peroxidation through membrane interactions, impairing cell proliferation, while X-rays amplify this oxidative stress. Given the essential role of fibroblasts in tissue regeneration, these findings underscore the biological importance of Fe^2+^-mediated damage exacerbated by radiation. This insight contributes to a more in-depth understanding of iron-dependent oxidative mechanisms relevant to ferroptosis and may inform future strategies exploring ferroptosis-targeted cancer therapies under radiation exposure. Further in vivo studies and antioxidant evaluations are required to advance therapeutic and environmental applications.
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