L-citrulline prevents heat-induced mitochondrial dysfunction and cell injury through nitric oxide-mediated Drp1 inhibition in mouse C2C12 myoblasts.

Severe heat exposure causes mitochondrial fragmentation and dysfunction, which contribute to the pathogenesis of heat-related illness. L-citrulline is a naturally occurring amino acid and has been suggested to influence heat shock responses. This study aimed to test whether L-citrulline supplementation would preserve mitochondrial integrity and attenuate heat-induced skeletal muscle injury, and elucidate the underlying mechanisms. At 37°C, L-citrulline (2 mM) increased mitochondrial elongation in mouse C2C12 myoblasts, a process associated with a reduction in mitochondrial fission protein Drp1 levels. Mechanistic studies revealed that L-citrulline increased cellular nitric oxide (NO) levels, but not S-nitrosylation of Drp1. L-citrulline caused a decrease in phosphorylation of Drp1 at Ser 616 and an increase in phosphorylation of Drp1 at Ser 637, which resulted in a reduced mitochondrial localization of Drp1. L-NAME, a non-selective NO synthase inhibitor, abolished the increase in L-citrulline-induced NO levels and inhibited Drp1 phosphorylation changes and mitochondrial elongation, which indicates involvement of a NO-dependent pathway. Under 43°C heat stress conditions, L-citrulline prevented translocation of Drp1 to mitochondria, mitochondrial fragmentation and decreased membrane potential. Finally, L-citrulline pretreatment inhibited heat-induced reactive oxygen species (ROS) overproduction, caspase 3/7 activation, apoptotic cell death, and improved cell viability. NO inhibitor L-NAME abolished all the above protective effects of L-citrulline under heat stress. Our results suggest that L-citrulline prevents heat-induced mitochondrial dysfunction and cell injury through NO-mediated Drp1 inhibition in C2C12 myoblasts. L-citrulline may be an effective treatment for heat-related illnesses and other mitochondrial diseases.

Skeletal muscle mitochondrial fragmentation and impaired bioenergetics from nutrient overload are prevented by carbon monoxide.

Nutrient excess increases skeletal muscle oxidant production and mitochondrial fragmentation that may result in impaired mitochondrial function, a hallmark of skeletal muscle insulin resistance. This led us to explore whether an endogenous gas molecule, carbon monoxide (CO), which is thought to prevent weight gain and metabolic dysfunction in mice consuming high-fat diets, alters mitochondrial morphology and respiration in C2C12 myoblasts exposed to high glucose (15.6 mM) and high fat (250 µM BSA-palmitate) (HGHF). Also, skeletal muscle mitochondrial morphology, distribution, respiration, and energy expenditure were examined in obese resistant (OR) and obese prone (OP) rats that consumed a high-fat and high-sucrose diet for 10 wk with or without intermittent low-dose inhaled CO and/or exercise training. In cells exposed to HGHF, superoxide production, mitochondrial membrane potential (ΔΨm), mitochondrial fission regulatory protein dynamin-related protein 1 (Drp1) and mitochondrial fragmentation increased, while mitochondrial respiratory capacity was reduced. CO decreased HGHF-induced superoxide production, Drp1 protein levels and mitochondrial fragmentation, maintained ΔΨm, and increased mitochondrial respiratory capacity. In comparison with lean OR rats, OP rats had smaller skeletal muscle mitochondria that contained disorganized cristae, a normal mitochondrial distribution, but reduced citrate synthase protein expression, normal respiratory responses, and a lower energy expenditure. The combination of inhaled CO and exercise produced the greatest effect on mitochondrial morphology, increasing ADP-stimulated respiration in the presence of pyruvate, and preventing a decline in resting energy expenditure. These data support a therapeutic role for CO and exercise in preserving mitochondrial morphology and respiration during metabolic overload.

Curcumin Ameliorates Heat-Induced Injury through NADPH Oxidase-Dependent Redox Signaling and Mitochondrial Preservation in C2C12 Myoblasts and Mouse Skeletal Muscle.

BACKGROUND: Nicotinamide adenine dinucleotide phosphate (NADPH) oxidase and the mitochondrial electron transport chain are the primary sources of reactive oxygen species (ROS). Previous studies have shown that severe heat exposure damages mitochondria and causes excessive mitochondrial ROS production that contributes to the pathogenesis of heat-related illnesses. OBJECTIVES: We tested whether the antioxidant curcumin could protect against heat-induced mitochondrial dysfunction and skeletal muscle injury, and characterized the possible mechanism. METHODS: Mouse C2C12 myoblasts and rat flexor digitorum brevis (FDB) myofibers were treated with 5 µM curcumin; adult male C57BL/6J mice received daily curcumin (15, 50, or 100 mg/kg body weight) by gavage for 10 consecutive days. We compared ROS levels and mitochondrial morphology and function between treatment and nontreatment groups under unheated or heat conditions, and investigated the upstream mechanism and the downstream effect of curcumin-regulated ROS production. RESULTS: In C2C12 myoblasts, curcumin prevented heat-induced mitochondrial fragmentation, ROS overproduction, and apoptosis (all P < 0.05). Curcumin treatment for 2 and 4 h at 37°C induced increases in ROS levels by 42% and 59% (dihydroethidium-derived fluorescence), accompanied by increases in NADPH oxidase protein expression by 24% and 32%, respectively (all P < 0.01). In curcumin-treated cells, chemical inhibition and genetic knockdown of NADPH oxidase restored ROS to levels similar to those of controls, indicating NADPH oxidase mediates curcumin-stimulated ROS production. Moreover, curcumin induced ROS-dependent shifting of the mitochondrial fission-fusion balance toward fusion, and increases in mitochondrial mass by 143% and membrane potential by 30% (both P < 0.01). In rat FDB myofibers and mouse gastrocnemius muscles, curcumin preserved mitochondrial morphology and function during heat stress, and prevented heat-induced mitochondrial ROS overproduction and tissue injury (all P < 0.05). CONCLUSIONS: Curcumin regulates ROS hormesis favoring mitochondrial fusion/elongation, biogenesis, and improved function in rodent skeletal muscle. Curcumin may be an effective therapeutic target for heat-related illness and other mitochondrial diseases.

Astaxanthin but not quercetin preserves mitochondrial integrity and function, ameliorates oxidative stress, and reduces heat-induced skeletal muscle injury.

Heat stress causes mitochondrial dysfunction and increases mitochondrial production of reactive oxygen species (ROS), both of which contribute to heat-induced skeletal muscle injury. In this study, we tested whether either astaxanthin or quercetin, two dietary antioxidants, could ameliorate heat-induced skeletal muscle oxidative injury. In mouse C2C12 myoblasts exposed to 43°C heat stress, astaxanthin inhibited heat-induced ROS production in a concentration-dependent manner (1-20 µM), whereas the ROS levels remained high in cells treated with quercetin over a range of concentrations (2-100 µM). Because mitochondria are both the main source and a primary target of heat-induced ROS, we then tested the effects of astaxanthin and quercetin on mitochondrial integrity and function, under both normal temperature (37°C) and heat stress conditions. Quercetin treatment at 37°C induced mitochondrial fragmentation and decreased membrane potential (ΔΨ m ), accompanied by reduced protein expression of the master regulator of mitochondrial biogenesis peroxisome proliferator-activated receptor-γ coactivator-1α (PGC-1α). It also induced cleavage of mitochondrial inner-membrane fusion protein OPA1. In contrast, astaxanthin at 37°C increased protein expression of PGC-1α and mitochondrial transcription factor A (TFAM), and maintained tubular structure and normal ΔΨm . Under 43°C heat stress conditions, whereas quercetin failed to rescue C2C12 cells from injury, astaxanthin treatment prevented heat-induced mitochondrial fragmentation and depolarization, and apoptotic cell death. We also isolated rat flexor digitorum brevis myofibers and confirmed the data from C2C12 myoblasts that astaxanthin but not quercetin preserves mitochondrial integrity and function and ameliorates heat-induced skeletal muscle injury. These results confirm that mitochondria may be a potential therapeutic target for heat-related illness and suggest that astaxanthin may potentially be an effective preventive strategy.

Curcumin induces concentration-dependent alterations in mitochondrial function through ROS in C2C12 mouse myoblasts.

Curcumin exhibits antioxidant properties in normal cells where the uptake is low, unlike in tumor cells where uptake is high and curcumin increases reactive oxygen species (ROS) production and cell death. Mitochondria are the main source and primary target of cellular ROS. We hypothesized that curcumin would regulate cellular redox status and mitochondrial function, depending on cell sensitivity and/or curcumin concentration in normal cells. We examined the differences between low and high concentrations of curcumin, with specific attention focused on ROS levels, mitochondrial function, and cell viability in mouse C2C12 myoblast under normal and simulated conditions of diabetes. Cells incubated with high concentrations of curcumin (10-50 µM) resulted in decreased cell viability and sustained robust increases in ROS levels. Mechanistic studies showed that increased ROS levels in cells incubated with 20 µM curcumin induced opening of mitochondrial permeability transition pores and subsequent release of cytochrome c, activation of caspases 9 and 3/7, and apoptotic cell death. Low concentrations of curcumin (1-5 µM) did not affect cell viability, but induced a mild increase in ROS levels, which peaked at 2 hr after the treatment. Incubation with 5 µM curcumin also induced ROS-dependent increases in mitochondrial mass and membrane potential. Finally, pretreatment with 5 µM curcumin prevented high glucose-induced oxidative cell injury. Our study suggests that mitochondria respond differentially depending on curcumin concentration-dependent induction of ROS. The end result is either cell protection or death. Curcumin may be an effective therapeutic target for diabetes and other mitochondrial diseases when used in low concentrations.

Role of dynamin-related protein 1-mediated mitochondrial fission in resistance of mouse C2C12 myoblasts to heat injury.

KEY POINTS: Understanding how skeletal muscles respond to high temperatures may help develop strategies for improving exercise tolerance and preventing heat injury. Mitochondria regulate cell survival by constantly changing their morphology through fusion and fission in response to environmental stimuli. Little is known about the involvement of mitochondrial dynamics in tolerance of skeletal muscle against heat stress. Mild heat acclimation and moderate heat shock appear to have different effects on the mitochondrial morphology and fission protein Drp1 in skeletal muscle cells. Mitochondrial integrity plays a key role in cell survival under heat stress. ABSTRACT: The regulation of mitochondrial morphology is closely coupled to cell survival during stress. We examined changes in the mitochondrial morphology of mouse C2C12 skeletal muscle cells in response to heat acclimation and heat shock exposure. Acclimated cells showed a greater survival rate during heat shock exposure than non-acclimated cells, and were characterized by long interconnected mitochondria and reduced expression of dynamin-related protein 1 (Drp1) for their mitochondrial fractions. Exposure of C2C12 muscle cells to heat shock led to apoptotic death featuring activation of caspase 3/7, release of cytochrome c and loss of cell membrane integrity. Heat shock also caused excessive mitochondrial fragmentation, loss of mitochondrial membrane potential and production of reactive oxygen species in C2C12 cells. Western blot and immunofluorescence image analysis revealed translocation of Drp1 to mitochondria from the cytosol in C2C12 cells exposed to heat shock. Mitochondrial division inhibitor 1 or Drp1 gene silencer reduced mitochondrial fragmentation and increased cell viability during exposure to heat shock. These results suggest that Drp1-dependent mitochondrial fission may regulate susceptibility to heat-induced apoptosis in muscle cells and that Drp1 may serve as a target for the prevention of heat-related injury.

Decreasing mitochondrial fission prevents cholestatic liver injury.

Mitochondria frequently change their shape through fission and fusion in response to physiological stimuli as well as pathological insults. Disrupted mitochondrial morphology has been observed in cholestatic liver disease. However, the role of mitochondrial shape change in cholestasis is not defined. In this study, using in vitro and in vivo models of bile acid-induced liver injury, we investigated the contribution of mitochondrial morphology to the pathogenesis of cholestatic liver disease. We found that the toxic bile salt glycochenodeoxycholate (GCDC) rapidly fragmented mitochondria, both in primary mouse hepatocytes and in the bile transporter-expressing hepatic cell line McNtcp.24, leading to a significant increase in cell death. GCDC-induced mitochondrial fragmentation was associated with an increase in reactive oxygen species (ROS) levels. We found that preventing mitochondrial fragmentation in GCDC by inhibiting mitochondrial fission significantly decreased not only ROS levels but also cell death. We also induced cholestasis in mouse livers via common bile duct ligation. Using a transgenic mouse model inducibly expressing a dominant-negative fission mutant specifically in the liver, we demonstrated that decreasing mitochondrial fission substantially diminished ROS levels, liver injury, and fibrosis under cholestatic conditions. Taken together, our results provide new evidence that controlling mitochondrial fission is an effective strategy for ameliorating cholestatic liver injury.

Maintaining mitochondrial NAD+ homeostasis is key for heat-induced skeletal muscle injury prevention despite presence of intracellular cation alterations.

Mitochondrial dysfunction is implicated in heat-induced skeletal muscle injury and its underlying mechanisms remain unclear. Evidence suggests that cellular ions and molecules, including divalent cations and adenine nucleotides, are involved in the regulation of mitochondrial function. In this study, we examined Ca2+, Mg2+, and NAD+ levels in mouse C2C12 myoblasts and skeletal muscle in response to heat exposure. During heat exposure, mitochondrial Ca2+ levels increased significantly, whereas cytosolic C2+ levels remained unaltered. The mitochondrial Ca2+ levels in the skeletal muscle of heat-exposed mice were 28% higher, compared to control mice. No changes in cytosolic Ca2+ were detected between the two groups. Following heat exposure, cytosolic and mitochondrial Mg2+ levels were reduced by 47% and 23% in C2C12 myoblasts, and by 51% and 44% in mouse skeletal muscles, respectively. In addition, heat exposure decreased mitochondrial NAD+ levels by 32% and 26% in C2C12 myoblasts and mouse skeletal muscles, respectively. Treatment with the NAD+ precursor nicotinamide riboside (NR) partially prevented heat-induced depletion of NAD+. Additionally, NR significantly reduced heat-increased mitochondrial fission, mitochondrial depolarization, and apoptosis in C2C12 myoblasts and mouse skeletal muscles. No effects of NR on heat-induced changes in intracellular Ca2+ and Mg2+ levels were observed. This study provides the in vitro and in vivo evidence that acute heat stress causes alterations in mitochondrial Ca2+, Mg2+, and NAD+ homeostasis. Our results suggest mitochondrial NAD+> homeostasis as a therapeutic target for the prevention of heat-induced skeletal muscle injury.

Mitochondrial Fission as a Therapeutic Target for Metabolic Diseases: Insights into Antioxidant Strategies.

Mitochondrial fission is a crucial process in maintaining metabolic homeostasis in normal physiology and under conditions of stress. Its dysregulation has been associated with several metabolic diseases, including, but not limited to, obesity, type 2 diabetes (T2DM), and cardiovascular diseases. Reactive oxygen species (ROS) serve a vital role in the genesis of these conditions, and mitochondria are both the main sites of ROS production and the primary targets of ROS. In this review, we explore the physiological and pathological roles of mitochondrial fission, its regulation by dynamin-related protein 1 (Drp1), and the interplay between ROS and mitochondria in health and metabolic diseases. We also discuss the potential therapeutic strategies of targeting mitochondrial fission through antioxidant treatments for ROS-induced conditions, including the effects of lifestyle interventions, dietary supplements, and chemicals, such as mitochondrial division inhibitor-1 (Mdivi-1) and other mitochondrial fission inhibitors, as well as certain commonly used drugs for metabolic diseases. This review highlights the importance of understanding the role of mitochondrial fission in health and metabolic diseases, and the potential of targeting mitochondrial fission as a therapeutic approach to protecting against these conditions.

Dose-Dependent Effects of Radiation on Mitochondrial Morphology and Clonogenic Cell Survival in Human Microvascular Endothelial Cells.

To better understand radiation-induced organ dysfunction at both high and low doses, it is critical to understand how endothelial cells (ECs) respond to radiation. The impact of irradiation (IR) on ECs varies depending on the dose administered. High doses can directly damage ECs, leading to EC impairment. In contrast, the effects of low doses on ECs are subtle but more complex. Low doses in this study refer to radiation exposure levels that are below those that cause immediate and necrotic damage. Mitochondria are the primary cellular components affected by IR, and this study explored their role in determining the effect of radiation on microvascular endothelial cells. Human dermal microvascular ECs (HMEC-1) were exposed to varying IR doses ranging from 0.1 Gy to 8 Gy (~0.4 Gy/min) in the AFRRI 60-Cobalt facility. Results indicated that high doses led to a dose-dependent reduction in cell survival, which can be attributed to factors such as DNA damage, oxidative stress, cell senescence, and mitochondrial dysfunction. However, low doses induced a small but significant increase in cell survival, and this was achieved without detectable DNA damage, oxidative stress, cell senescence, or mitochondrial dysfunction in HMEC-1. Moreover, the mitochondrial morphology was assessed, revealing that all doses increased the percentage of elongated mitochondria, with low doses (0.25 Gy and 0.5 Gy) having a greater effect than high doses. However, only high doses caused an increase in mitochondrial fragmentation/swelling. The study further revealed that low doses induced mitochondrial elongation, likely via an increase in mitochondrial fusion protein 1 (Mfn1), while high doses caused mitochondrial fragmentation via a decrease in optic atrophy protein 1 (Opa1). In conclusion, the study suggests, for the first time, that changes in mitochondrial morphology are likely involved in the mechanism for the radiation dose-dependent effect on the survival of microvascular endothelial cells. This research, by delineating the specific mechanisms through which radiation affects endothelial cells, offers invaluable insights into the potential impact of radiation exposure on cardiovascular health.

5-Hydroxymethylfurfural reduces skeletal muscle superoxide production and modifies force production in rats exposed to hypobaric hypoxia.

Decreased blood-tissue oxygenation at high altitude (HA) increases mitochondrial oxidant production and reduces exercise capacity. 5-Hydroxymethylfurfural (5-HMF) is an antioxidant that increases hemoglobin's binding affinity for oxygen. For these reasons, we hypothesized that 5-HMF would improve muscle performance in rats exposed to a simulated HA of ~5500 m. A secondary objective was to measure mitochondrial activity and dynamic regulation of fission and fusion because they are linked processes impacted by HA. Fisher 344 rats received 5-HMF (40 mg/kg/day) or vehicle during exposure to sea level or HA for 72 h. Right ankle plantarflexor muscle function was measured pre- and post-exposure. Post-exposure measurements included arterial blood gas and complete blood count, flexor digitorum brevis myofiber superoxide production and mitochondrial membrane potential (ΔΨm), and mitochondrial dynamic regulation in the soleus muscle. HA reduced blood oxygenation, increased superoxide levels and lowered ΔΨm, responses that were accompanied by decreased peak isometric torque and force production at frequencies >75 Hz. 5-HMF increased isometric force production and lowered oxidant production at sea level. In HA exposed animals, 5-HMF prevented a decline in isometric force production at 75-125 Hz, prevented an increase in superoxide levels, further decreased ΔΨm, and increased mitochondrial fusion 2 protein expression. These results suggest that 5-HMF may prevent a decrease in hypoxic force production during submaximal isometric contractions by an antioxidant mechanism.

Effect of statins therapy prior to percutaneous coronary intervention.

BACKGROUND: Many previous studies have demonstrated that statins pre-treatment before percutaneous coronary intervention (PCI) reduced myocardial infarction (MI) in statin-naive patients with both stable angina and acute coronary syndrome. However, clinical benefit of statins is controversial as some studies have shown different results. METHODS: A search of MEDLINE, EMBASE using the term statins AND PCI, statins AND percutaneous coronary intervention. The review was limited to articles published in English between January 1990 and July 2011. RESULTS: Most trials noted that statins pretreatment before PCI in patients are associated with risk reduction of periprocedural myocardial infarction (PMI) and major adverse cardiovascular events (MACE). The mechanisms underlying this protective action of statins possibly attribute to the pleiotropic effects. However, controversial results were also reported in some trials that early use of statins before PCI did not influence occurrence of PMI or long-term clinical outcomes. CONCLUSION: Statins therapy among PCI patients seems to be associated with a significant mortality advantage at early and long-term follow-up. However, currently early statins use before intervention still cannot serve as a routine strategy of treatment. Further large-scale randomized studies are critically required to demonstrate the importance of early treatment with statins in pre-PCI.

Acute heat stress-indued apoptosis in mouse skeletal muscle is not associated with alteration of glutamine homeostasis.

We previously demonstrated that exposing mice to heat causes functional and ultrastructural mitochondrial alterations and apoptosis in skeletal muscle. Emerging evidence indicates that glutamine (Gln) deprivation may increase cell susceptibility to apoptosis whereas Gln supplementation may protect cells against heat stress. In this study, we investigated the effect of short-term Gln treatment on heat-induced changes in mouse skeletal muscle. Male mice received vehicle, low-dose Gln (100 mg/kg/d) or high-dose Gln (300 mg/kg/d) through daily gavage for 10 days before a heat exposure test. During heat exposure, mice displayed a hyperthermic response and no significant differences in peak core body temperature were noted across the three groups. Neither heat exposure nor pretreatment with low-dose or high-dose Gln significantly affected Gln concentrations in plasma and gastrocnemius muscles. Heat-exposed mice had significantly higher caspase 3/7 levels in gastrocnemius muscle compared to unexposed controls. Heat exposure significantly increased ROS production and mitochondrial fragmentation and decreased mitochondrial membrane potential in flexor digitorum brevis muscle. These changes were not affected by low- or high-dose Gln pretreatment. Together, acute heat stress did not disrupt Gln homeostasis in mouse skeletal muscle and Gln supplementation did not protect mouse skeletal muscle against heat-induced injury. The results of this study do not support a role of Gln in heat-induced skeletal muscle apoptosis.

Protective effects of dietary curcumin and astaxanthin against heat-induced ROS production and skeletal muscle injury in male and female C57BL/6J mice.

AIMS: This study aimed to: 1) investigate sex differences in heat-induced mitochondrial dysfunction, ROS production, and skeletal muscle injury in mice; 2) evaluate whether curcumin and astaxanthin, alone or together, would prevent those heat-induced changes. MAIN METHODS: Male and female C57BL/6J mice were treated with curcumin and astaxanthin for 10 days, then exposed to 39.5 °C heat for up to 3 h. Heat-induced hyperthermia, changes in mitochondrial morphology and function, and oxidative damage to skeletal muscle were evaluated. KEY FINDINGS: Although female mice had a slightly higher basal core body temperature (Tc) than male mice, peak Tc during heat exposure was significantly lower in females than in males. Heat increased ROS levels in skeletal muscle in both sexes; interestingly, the increases in ROS were greater in females than in males. Despite the above-mentioned differences, heat induced similar levels of mitochondrial fragmentation and membrane potential depolarization, caspase 3/7 activation, and injury in male and female skeletal muscle. Individual treatment of curcumin or astaxanthin did not affect basal and peak Tc but prevented heat-induced mitochondrial dysfunction, ROS increases, and apoptosis in a dose-dependent manner. Moreover, a low-dose combination of curcumin and astaxanthin, which individually showed no effect, reduced the heat-induced oxidative damage to skeletal muscle. SIGNIFICANCE: Both male and female mice can develop mitochondrial dysfunction and oxidative stress in skeletal muscle when exposed to heat stress. High doses of either curcumin or astaxanthin limit heat-induced skeletal muscle injury, but a low-dose combination of these ingredients may increase their efficacy.

Regulation of mitochondrial fission by intracellular Ca2+ in rat ventricular myocytes.

Mitochondria are dynamic organelles that constantly undergo fission, fusion, and movement. Increasing evidence indicates that these dynamic changes are intricately related to mitochondrial function, suggesting that mitochondrial form and function are linked. Calcium (Ca2+) is one signal that has been shown to both regulate mitochondrial fission in various cell types and stimulate mitochondrial enzymes involved in ATP generation. However, although Ca2+ plays an important role in adult cardiac muscle cells for excitation-metabolism coupling, little is known about whether Ca2+ can regulate their mitochondrial morphology. Therefore, we tested the role of Ca2+ in regulating cardiac mitochondrial fission. We found that neonatal and adult cardiomyocyte mitochondria undergo rapid and transient fragmentation upon a thapsigargin (TG)- or KCl-induced cytosolic Ca2+ increase. The mitochondrial fission protein, DLP1, participates in this mitochondrial fragmentation, suggesting that cardiac mitochondrial fission machinery may be regulated by intracellular Ca2+ signaling. Moreover, the TG-induced fragmentation was also associated with an increase in reactive oxygen species (ROS) formation, suggesting that activation of mitochondrial fission machinery is an early event for Ca2+-mediated ROS generation in cardiac myocytes. These results suggest that Ca2+, an important regulator of muscle contraction and energy generation, also dynamically regulates mitochondrial morphology and ROS generation in cardiac myocytes.

Mouse liver is more resistant than skeletal muscle to heat-induced apoptosis.

During passive heat stress, shifting of blood flow from the hepato-splanchnic to peripheral regions produces less favorable physiological conditions in the liver than in the skeletal muscle. We were wondering if the two organs differ in susceptibility to heat injury and thus examined the effects of heat shock exposure on apoptotic and heat stress-related markers in the gastrocnemius muscle and liver of mice. During heat exposure, mice had a peak core body temperature of 41.1 ± 0.7 °C. Heat-exposed mice showed higher levels of reactive oxygen species (ROS), cleaved caspases, fragmented DNA, and Drp1 protein expression in the gastrocnemius muscles than control mice. These changes were not observed in the livers of heat-exposed mice. Furthermore, the levels of glucocorticoid receptor, HSP70, and HSF1 proteins were significantly elevated in the gastrocnemius muscles of heat-exposed mice compared with that of control mice. The livers of heat-exposed mice also revealed increased expression of HSP70 but no changes in the other proteins. These results demonstrate that heat exposure induces significantly lower levels of the stress response and apoptosis in the liver than in the skeletal muscle of mice. The liver tissue resistance against heat stress is associated with low levels of heat-induced ROS production and mitochondrial fission protein expression.

Astaxanthin Protects Against Heat-induced Mitochondrial Alterations in Mouse Hypothalamus.

The hypothalamus plays an essential role in regulating whole-body energy and temperature homeostasis when adapting to environmental changes. We previously reported that heat exposure causes mitochondrial dysfunction and apoptosis in mouse skeletal muscle, and pretreatment with astaxanthin (AST), an antioxidant, prevents this effect. How the hypothalamus responds to heat stress remains largely unexplored. In this study, we investigated the effects of heat exposure on hypothalamic mitochondria in mice with and without AST pretreatment. During heat exposure, both vehicle and AST-treated mice had a hyperthermic response though no significant differences in peak core body temperature were noted between the two groups. Heat exposure induced mitochondrial fission in the hypothalamus, as manifested by increased mitochondrial fragmentation and expression of both total and phosphorylated dynamin-related protein 1. In addition, transmission electron microscopy revealed damaged and degraded mitochondria in the hypothalamus of heat-exposed mice. Heat induced apoptosis and mitophagy were further confirmed by increased formation of reactive oxygen species, activation of caspase 3/7 and expression of LC3 proteins. Moreover, heat exposure increased the expression of PINK1 and Parkin in mouse hypothalamus. In contrast, pretreatment with AST reduced these effects. These results demonstrate that heat stress-induced hypothalamic apoptosis is associated with altered mitochondrial dynamics favoring fission and mitophagy. AST protects the hypothalamus against heat-induced injury by preserving redox homeostasis and mitochondrial integrity.

Involvement of p53 in the Responses of Cardiac Muscle Cells to Heat Shock Exposure and Heat Acclimation.

Intense heat stress induces damage to the heart, whereas mild to moderate heat stress protects the heart against subsequent ischemic injury. The mechanisms underlying the detrimental and beneficial effects of heat stress remain unclear. In this study, we investigated the role of p53 in the responses of cardiac muscle cells to acute heat exposure and heat acclimation (HA). Heat exposure increased the levels of caspase and annexin, and levels of cytosolic, nuclear, and mitochondrial p53 protein in H9c2 cells. Pifithrin-α or pifithrin-µ reduced heat-induced apoptotic response in these cells. HA reduced localization of p53 in the mitochondria and improved cell viability during heat exposure. The effects of heat exposure and HA on p53 were further verified in vivo in mouse heart tissue. These results suggest that p53 plays a role in heat-induced apoptosis in cardiac muscle cells. The protective effect of HA against heat injury likely involves a p53-dependent mechanism.

IL-18 binding protein (IL-18BP) as a novel radiation countermeasure after radiation exposure in mice.

Recent studies suggested that radiation exposure causes local and systemic inflammatory responses and induces cell and tissue damage. We have reported that IL-18 plays an important role in radiation-induced injury. Here, we demonstrate that IL-18 binding protein (IL-18BP), a natural antagonist of IL-18, was significantly increased (1.7-63 fold) in mouse serum on day 1 after 0.5-10 Gy TBI. However, this high level of IL-18BP was not sufficient to neutralize the active IL-18 in irradiated mice, resulting in a radiation dose-dependent free IL-18 increase in these mice's serum which led to pathological alterations to the irradiated cells and tissues and finally caused animal death. Administration of recombinant human (rh) IL-18BP (1.5 mg/kg) with single (24, 48 or 72 h post-TBI) or double doses (48 h and 5 days post-TBI) subcutaneous (SC) injection increased 30-day survival of CD2F1 mice after 9 Gy TBI 12.5-25% compared with the vehicle control treated group, respectively. Furthermore, the mitigative effects of rhIL-18BP included balancing the ratio of IL-18/IL-18BP and decreasing the free IL-18 levels in irradiated mouse serum and significantly increasing blood cell counts, BM hematopoietic cellularity and stem and progenitor cell clonogenicity in mouse BM. Furthermore, IL-18BP treatment inhibited the IL-18 downstream target interferon (IFN)-γ expression in mouse BM, decreased reactive oxygen species (ROS) level in the irradiated mouse heart tissues, attenuated the stress responsive factor GDF-15 (growth differentiation factor-15) and increased the intestine protector citrulline level in total body irradiated mouse serum, implicating that IL-18BP may protect multiple organs from radiation-induced inflammation and oxidative stress. Our data suggest that IL-18 plays a key role in radiation-induced cell and tissue damage and dysfunction; and for the first time demonstrated that IL-18BP counters IL-18 activation and therefore may mitigate/treat radiation-induced multiple organ injuries and increase animal survival with a wider therapeutic window from 24 h and beyond after lethal doses of radiation exposure.

Glutamine depletion disrupts mitochondrial integrity and impairs C2C12 myoblast proliferation, differentiation, and the heat-shock response.

Glutamine and glucose are both oxidized in the mitochondria to supply the majority of usable energy for processes of cellular function. Low levels of plasma and skeletal muscle glutamine are associated with severe illness. We hypothesized that glutamine deficiency would disrupt mitochondrial integrity and impair cell function. C2C12 mouse myoblasts were cultured in control media supplemented with 5.6 mmol/L glucose and 2 mmol/L glutamine, glutamine depletion (Gln-) or glucose depletion (Glc-) media. We compared mitochondrial morphology and function, as well as cell proliferation, myogenic differentiation, and heat-shock response in these cells. Glc- cells exhibited slightly elongated mitochondrial networks and increased mitochondrial mass, with normal membrane potential (ΔΨm). Mitochondria in Gln- cells became hyperfused and swollen, which were accompanied by severe disruption of cristae and decreases in ΔΨm, mitochondrial mass, the inner mitochondrial membrane remodeling protein OPA1, electron transport chain complex IV protein expression, and markers of mitochondrial biogenesis and bioenergetics. In addition, Gln- increased the autophagy marker LC3B-II on the mitochondrial membrane. Notably, basal mitochondrial respiration was increased in Glc- cells as compared to control cells, whereas maximal respiration remained unchanged. In contrast, basal respiration, maximal respiration and reserve capacity were all decreased in Gln- cells. Consistent with the aforementioned mitochondrial deficits, Gln- cells had lower growth rates and myogenic differentiation, as well as a higher rate of cell death under heat stress conditions than Glc- and control cells. We conclude that glutamine is essential for mitochondrial integrity and function; glutamine depletion impairs myoblast proliferation, differentiation, and the heat-shock response.