Mitochondrial Protection Research Articles

Exploring DMT: Endogenous Role and Therapeutic Potential.

N,N-Dimethyltryptamine (DMT) is a naturally occurring amine and psychedelic compound, found in plants, animals, and humans. While initial studies reported only trace amounts of DMT in mammalian brains, recent findings have identified alternative methylation pathways and DMT levels comparable to classical neurotransmitters in rodent brains, calling for a re-evaluation of its biological role and exploration of this inconsistency. This study evaluated DMT's biosynthetic pathways, focusing on indolethylamine N-methyltransferase (INMT) and its isoforms, and possible regulatory mechanisms, including alternative routes of synthesis and how physiological conditions, such as stress and hypoxia influence DMT levels. This review considers the impact of endogenous regulatory factors on DMT synthesis and degradation, particularly under conditions affecting monoamine oxidase (MAO) efficiency and activity. We also examined DMT's potential roles in various physiological processes, including neuroplasticity and neurogenesis, mitochondrial homeostasis, immunomodulation, and protection against hypoxia and oxidative stress. DMT's lipophilic properties allow it to cross cell membranes and activate intracellular 5-HT2A receptors, contributing to its role in neuroplasticity. This suggests DMT may act as an endogenous ligand for intracellular receptors, highlighting its broader biological significance beyond traditional receptor pathways. The widespread evolutionary presence of DMT's biosynthetic pathways across diverse species suggests it may play essential roles in various developmental stages and cellular adaptation to environmental challenges, highlighting the neurobiological significance of DMT and its potential clinical applications. We propose further research to explore the role of endogenous DMT, particularly as a potential neurotransmitter.

Calycosin‑7‑O‑β‑D‑glucoside downregulates mitophagy by mitigating mitochondrial fission to protect HT22 cells from oxygen‑glucose deprivation/reperfusion‑induced injury.

Calycosin‑7‑O‑β‑D‑glucoside (CG), a major active ingredient of Astragali Radix, exerts neuroprotective effects against cerebral ischemia; however, whether the effects of CG are associated with mitochondrial protection remains unclear. The present study explored the role of CG in improving mitochondrial function in a HT22 cell model of oxygen‑glucose deprivation/reperfusion (OGD/R). The Cell Counting Kit‑8 assay, flow cytometry, immunofluorescence and western blotting were performed to investigate the effects of CG on mitochondrial function. The results demonstrated that mitochondrial function was restored after treatment with CG, as indicated by reduced mitochondrial reactive oxygen species levels, increased mitochondrial membrane potential and improved mitochondrial morphology. Overactivated mitophagy was revealed to be inhibited by the regulation of proteins involved in fission [phosphorylated‑dynamin‑related protein 1 (Drp1) and Drp1] and mitophagy (LC3, p62 and translocase of outer mitochondrial membrane 20), and mitochondrial biogenesis was demonstrated to be enhanced by increased levels of sirtuin 1 (SIRT1) and peroxisome proliferator‑activated receptor γ coactivator‑1α (PGC‑1α). In addition, neuronal apoptosis was ameliorated by CG, as determined by a decreased rate of apoptosis, and levels of caspase‑3 and Bcl‑2/Bax. In conclusion, the present study demonstrated that CG may alleviate OGD/R‑induced injury by upregulating SIRT1 and PGC‑1α protein expression, and reducing excessive mitochondrial fission and overactivation of mitophagy.

The total extract of Abelmoschus manihot (L.) medic flowers (TEA) mediated Nrf2-TFAM signalling to regulate mitochondrial antioxidant mechanism

Skin, as the first line of defence of the human body, is exposed to dangers such as overheating substances, ultraviolet rays, and environmental pollutants, and the incidence of skin diseases is increasing annually. Oxidative stress plays a dominant role in most skin diseases. Abelmoschus manihot (L.) medic flower (TEA) is a traditional Chinese medicine widely used to treat injuries to the skin such as water and fire scalds. It has been reported that TEA has excellent antioxidant effects. In this study, we aimed to explore the antioxidant and mitochondrial protection effects of TEA in H2O2-mediated HaCaT cell damage. HaCaT cells were incubated with H2O2 to simulate oxidative stress in the skin. The effect of TEA on HaCaT cells was also evaluated. Cell morphology was observed via inverted microscopy, and cell viability was measured via the MTT reagent. The cells were stained with Hoechst 33,324 solution. Reactive oxygen species (ROS), superoxide dismutase (SOD), malondialdehyde (MDA) and ATP detection kits were used to detect the corresponding indicators. The mitochondrial membrane potential was detected by JC-1. RT-PCR was used to detect mRNA and mtDNA expression. The expression of the target protein was detected by Western blotting and immunofluorescence. H2O2 triggered oxidative damage in HaCaT cells, which manifested as apoptosis, increased ROS and MDA contents, and decreased SOD activity. H2O2 activates the KEAP1/Nrf2/NQO1 signalling pathway, which decreases the expression of the intracellular KEAP1 protein and slightly increases the expression of the Nrf2 and NQO1 proteins, further causing mitochondrial oxidative stress, resulting in changes in the mitochondrial membrane potential, a reduction in the mtDNA copy number, and decreased expression of the PGC-1α and TFAM proteins. In addition the expression of mitochondrial respiratory chain genes and proteins decreased. TEA promoted the expression of Nrf2 in HaCaT cells, activated the downstream antioxidant response, and alleviated the oxidative stress and mitochondrial damage caused by H2O2. ML385 is an Nrf2 inhibitor, under which the antioxidant and mitochondrial protective effects of TEA are inhibited. When TFAM was knocked down, the protective effect of TEA on mitochondria was also inhibited. TEA protects HaCaT cells from H2O2-induced oxidative damage and mitochondrial oxidative damage through the KEAP1/Nrf2/NQO1/PGC-1α/TFAM pathway.

Biosynthesis of Lysosomally Escaped Apoptotic Bodies Inhibits Inflammasome Synthesis in Macrophages.

Hyperglycemia and bacterial colonization in diabetic wounds aberrantly activate Nod-like receptor protein 3 (NLRP3) in macrophages, resulting in extensive inflammatory infiltration and impaired wound healing. Targeted suppression of the NLRP3 inflammasome shows promise in reducing macrophage inflammatory disruptions. However, challenges such as drug off-target effects and degradation via lysosomal capture remain during treatment. In this study, engineered apoptotic bodies (BHB-dABs) derived from adipose stem cells loaded with β-hydroxybutyric acid (BHB) were synthesized via biosynthesis. These vesicles target M1-type macrophages, which highly express the folic acid receptor in the inflammatory microenvironment, and facilitate lysosomal escape through 1,2-distearoyl-sn-propyltriyl-3-phosphatidylethanolamine-polyethylene glycol functionalization, which may enhance the efficacy of NLRP3 inhibition for managing diabetic wounds. Invitro studies demonstrated the biocompatibility of BHB-dABs, their selective targeting of M1-type macrophages, and their ability to release BHB within the inflammatory microenvironment via folic acid and folic acid receptor signaling. These nanovesicles exhibited lysosomal escape, anti-inflammatory, mitochondrial protection, and endothelial cell vascularization properties. Invivo experiments demonstrated that BHB-dABs enhance the recovery of diabetic wound inflammation and angiogenesis, accelerating wound healing. These functionalized apoptotic bodies efficiently deliver NLRP3 inflammasome inhibitors using a dual strategy of targeting macrophages and promoting lysosomal escape. This approach represents a novel therapeutic strategy for effectively treating chronic diabetic wounds.

The potential of melatonin in sepsis-associated acute kidney injury: Mitochondrial protection and cGAS-STING signaling pathway.

Melatonin (Mel) is known for various biological function, such as antioxidant and anti-inflammatory capabilities, as well as its ability to modulate immune responses, which can protect mitochondria and improve the prognosis of sepsis-associated acute kidney injury (SA-AKI). However, there is a multitude of theories regarding how Mel exerts its immune-modulating functions, with no consensus reached as of yet. We propose the protective effects of Mel on mitochondria are closely related to the cyclic GMP-AMP synthase (cGAS)-stimulator of interferon genes (STING) signaling pathway in the immune-inflammatory response. We intraperitoneally injected H151 and Mel into SA-AKI mouse models to interfere the cGAS-STING signaling pathway. By comparing behavioral, pathological, and molecular biology results, we discovered that Mel could reduce cGAS-STING signaling pathway while greatly relieving kidney damage and function. In addition, Mel-treated mice showed a significant increase in autophagosome formations, which might be linked to the cGAS-STING signaling pathway. Our findings suggest that Mel protection on kidney injury in SA-AKI mice is partially attributed to the inhibition of the cGAS-STING signaling pathway.

Astaxanthin ameliorates dexamethasone-induced skeletal muscle atrophy and disorders of glucolipid metabolism

Long-term use of glucocorticoids, such as dexamethasone, can lead to skeletal muscle atrophy and disturbances in glucolipid metabolism. Astaxanthin, a ketocarotenoid, has a variety of physiological activities. In this study, we investigated the effects of astaxanthin on dexamethasone-induced skeletal muscle atrophy and disorders of glycolipid metabolism. Male C57Bl/6J mice were administered dexamethasone alone or supplemented with different doses of astaxanthin (30mg/kg/d, 60mg/kg/d, 120mg/kg/d) for 4 weeks. The results showed that astaxanthin improved locomotor performance and attenuated dexamethasone-induced reductions in skeletal muscle mass and cross-sectional area in mice. Further exploration of the mechanism revealed that astaxanthin was able to balance the catabolism and synthesis of skeletal muscle proteins and protect mitochondria by reducing the expression of the mitochondrial autophagy-associated proteins Lc3B and BNIP3. In addition, astaxanthin reduced the accumulation of fatty acid metabolites and visceral fat and improved the ability of skeletal muscle to utilize sugars, suggesting that astaxanthin may alleviate dexamethasone-induced disturbances in glycolipid metabolism. This study illustrates that astaxanthin can alleviate skeletal muscle atrophy and metabolic disturbances induced by long-term dexamethasone treatment. This suggests that astaxanthin may be a functional dietary supplement to reduce the side effects of glucocorticoid therapy.

Fumarprotocetraric acid and geraniin were identified as novel inhibitors of human respiratory syncytial virus infection in vitro.

Respiratory syncytial virus (RSV) remains a major international public health concern. However, disease treatment is limited to preventive care with monoclonal antibodies and supportive care. In this study, natural products were screened to identify novel anti-RSV inhibitors. The antiviral effect of 320 compounds on RSV in HEp-2 cells was tested using a Cytopathic effect (CPE) inhibition assay. The antiviral effect of fumarprotocetraric acid (FUM) and geraniin (GE) were confirmed by Real-time reverse transcription quantitative PCR (Real-time RT-PCR), plaque reduction test, immunofluorescence assay, and Western blot analysis. Real-time PCR was used to detect inflammatory factor expression. ATP assay and JC-1 stain were used to evaluate mitochondrial protection function. The experiment of administration time was used to determine the stages in the RSV life cycle inhibited by FUM and GE. Human metapneumovirus (HMPV) and human rhinovirus (HRV) were used to evaluate the antiviral activities of other respiratory viruses of FUM and GE. Finally, Air-liquid interface human airway epithelium (ALI-HAE) cells were used to evaluate the antiviral effect and mechanism of FUM and GE to RSV. The results showed that FUM and GE can inhibit the replication of RSV in multiple-cell models. Both compounds could dose-dependent inhibit the viral load, RSV nucleic acids level, and RSV-F protein level. Besides, FUM and GE showed good anti-inflammatory activity, mitochondrial protection, and antiviral activity to HMPV and HRV. Meanwhile, our result indicated that FUM and GE can inhibit RSV replication in ALI-HAE cells. FUM and GE were identified as new inhibitors of RSV infection. At the same time, FUM and GE have anti-inflammatory activity, mitochondrial protection function, and broad-spectrum antiviral activity. These results provide evidence that FUM and GE are potential candidates for the development of novel anti-RSV drugs.

Nrf2/NRF1 signaling activation and crosstalk amplify mitochondrial biogenesis in the treatment of triptolide-induced cardiotoxicity using calycosin

Nuclear factor erythroid 2-related factor 2 (Nrf2) regulates both oxidative stress and mitochondrial biogenesis. Our previous study reported the cardioprotection of calycosin against triptolide toxicity through promoting mitochondrial biogenesis by activating nuclear respiratory factor 1 (NRF1), a coregulatory effect contributed by Nrf2 was not fully elucidated. This work aimed at investigating the involvement of Nrf2 in mitochondrial protection and elucidating Nrf2/NRF1 signaling crosstalk on amplifying the detoxification of calycosin. Results indicated that calycosin inhibited cardiomyocytes apoptosis and F-actin depolymerization following triptolide exposure. Cardiac contraction was improved by calycosin through increasing both fractional shortening (FS%) and ejection fraction (EF%). This enhanced contractile capacity of heart was benefited from mitochondrial protection reflected by ultrastructure improvement, augment in mitochondrial mass and ATP production. NRF1 overexpression in cardiomyocytes increased mitochondrial mass and DNA copy number, whereas NRF1 knockdown mitigated calycosin-mediated enhancement in mitochondrial mass. For nuclear Nrf2, it was upregulated by calycosin in a way of disrupting Nrf2-Keap1 (Kelch-like ECH associated protein 1) interaction, followed by inhibiting ubiquitination and degradation. The involvement of Nrf2 in mitochondrial protection was validated by the results that both Nrf2 knockdown and Nrf2 inhibitor blocked the calycosin effects on mitochondrial biogenesis and respiration. In the case of calycosin treatment, its effect on NRF1 and Nrf2 upregulations were respectively blocked by PGCα/Nrf2 and NRF1 knockdown, indicative of the mutual regulation between Nrf2 and NRF1. Accordingly, calycosin activated Nrf2/NRF1 and the signaling crosstalk, leading to mitochondrial biogenesis amplification, which would become a novel mechanism of calycosin against triptolide-induced cardiotoxicity.

Effect of sodium butyrate on kidney and liver mitochondrial dysfunction in a lipopolysaccharide mousemodel.

Sodium butyrate can reduce inflammation, but it is not known if butyrate can improve mitochondrial dysfunction during sepsis. We tested butyrate to prevent or reverse lipopolysaccharide (LPS)-induced mitochondrial dysfunction in murine kidney and liver. C57BL/6 mice were grouped as control (n = 9), intraperitoneal (IP) LPS (n = 8), pretreatment with IP butyrate 600 (n = 3) or 1200 mg/kg (n = 8) followed 2 h later by LPS, posttreatment with IP butyrate 600 (n = 3) or 1200 mg/kg (n = 7) 1 h after LPS, or butyrate 1200 mg/kg only (n = 8). Kidney and liver tissue were collected at 24 h to measure mitochondrial respiration, electron transport system (ETS) complex activity and subunit expression, and content (citrate synthase [CS] activity and mtDNA/nDNA). Kidney mitochondrial respiration was decreased after LPS compared to controls. Pretreatment with butyrate 1200 mg/kg increased kidney OXPHOSCI+II, ETSCI+II, ETSCII, and CIV respiration compared to LPS; posttreatment did not achieve significant increases except for OXPHOSCI. Liver mitochondrial respiration exhibited a similar pattern as in kidney, but differences were not significant. ETS complex and CS activity did not differ between groups, but CI and CII subunit expression trended higher with butyrate in kidney. Changes in mtDNA/nDNA followed a similar pattern as respiration in kidney and liver with a decrease after LPS that was not present with butyrate pretreatment. These data show that butyrate can prevent-but not significantly reverse-the LPS-induced decrease in kidney mitochondrial respiration without a clear effect in liver. Mitochondrial protection was not attributable to changes in ETS complex activity but may reflect maintenance of ETS subunit expression.

Low-energy extracorporeal shockwave therapy improves locomotor functions, tissue regeneration, and modulating the inflammation induced FGF1 and FGF2 signaling to protect damaged tissue in spinal cord injury of rat model: an experimental animal study.

Spinal cord injury (SCI) is a debilitating condition that results in severe motor function impairments. Current therapeutic options remain limited, underscoring the need for novel treatments. Extracorporeal shockwave therapy (ESWT) has emerged as a promising noninvasive approach for treating musculoskeletal disorders and nerve regeneration. This study explored the effects of low-energy ESWT on locomotor function, tissue regeneration, inflammation, and mitochondrial function in a rat SCI model. Experiments were performed using locomotor function assays, CatWalk gait analysis, histopathological examination, immunohistochemical, and immunofluorescence staining. The findings demonstrated that low-energy ESWT had a dose-dependent effect, with three treatment sessions (ESWT3) showing superior outcomes compared to a single session. ESWT3 significantly improved motor functions [run patterns, run average speed, and maximum variation, as well as the Basso, Beattie, and Bresnahan score] and promoted tissue regeneration while reducing inflammation. ESWT3 significantly decreased levels of IL-1β, IL6, and macrophages (CD68) while increasing leukocyte (CD45) infiltration. Additionally, ESWT3 upregulated NueN and mitofusin 2 (MFN2), suggesting enhanced neuronal health and mitochondrial function. Moreover, ESWT3 modulated the expression of fibroblast growth factor 1 (FGF1), FGF2, their receptor FGFR1 and phosphorylation of ERK, aiding tissue repair, and regeneration in SCI. This study highlights the potential of low-energy ESWT as an effective noninvasive treatment for SCI, demonstrating significant improvements in motor recovery, tissue regeneration, anti-inflammatory effects, and mitochondrial protection. These findings provide valuable insights into the mechanisms of ESWT and its therapeutic application for SCI recovery.

Dendrobium nobile Lindl. alkaloids protect CCl4-induced acute liver injury via upregulating LAMP1 expression and activating autophagy flux.

Dendrobium nobile Lindl. alkaloids (DNLA) are considered important active ingredients of Dendrobium, which have a variety of pharmacological functions. Recent studies indicate that DNLA has beneficial activity in acute liver injury. However, the specific mechanism by which DNLA produces liver protective effects is stills unclear. This study was designed to determine whether regulation of autophagy is involved in the mode of action of DNLA in liver protection. Using CCl4-induced acute liver injury (ALI) and cell culture models, the molecular mechanism of DNLA-mediated autophagy regulation was studied. The results showed that DNLA significantly improved CCl4-induced liver damage and oxidative stress, which was confirmed in AML-12 cells. DNLA promoted autophagy in cells treated with CCl4, manifested by reduced protein expressions of p62 and LC3-II. Fluorescence imaging showed a decrease in the number of autophagosomes in AML-12 cells transfected with mCherry-GFP-LC3B. In addition, DNLA inhibited lysosomal membrane permeabilization by upregulating lysosomal associated membrane protein-1 (LAMP1), thereby promoting autophagy, preventing CCl4-induced mitochondrial dysfunction, and reducing the production of mitochondrial reactive oxygen species (ROS). While pretreatment of cells with lysosomal inhibitor chloroquine weakened mitochondrial protection elicited by DNLA, overexpression of mitochondrial-targeted SOD2 in AML-12 cells significantly blocked CCl4 induced downregulation of LAMP1, thereby improving lysosome integrity and promoting lysosome dependent autophagy, suggesting that there may exist a bidirectional regulation between mitochondrial ROS and lysosome-autophagy activation. Collectively, these results demonstrated that DNLA can protect the liver injury mediated by dysregulation of lysosome-autophagy process through promoting ROS-lysosome-autophagy axis and improving mitochondrial damage.

Mitochondrial respiratory pathways in immature rat heart tissue using different cardioplegic solutions.

Minor defects in the mitochondrial ATP-generating system and post-cardioplegia oxidative phosphorylation can negatively impact cardiac function in immature hearts. This study aimed to examine the mitochondrial respiratory pathway using three different cardioplegic solutions (Custodiol HTK, St. Thomas, and Del Nido) during moderate (1h) and long (3h) ischemic periods. A total of 41 male Wistar albino rats were utilized in this study. Five experiments were conducted without the use of any cardioplegic solution (CP0 group). To assess both moderate and prolonged ischemic periods, six experiments were carried out in each of the following groups: CP1 group (St. Thomas solution), CP2 group (Custodiol HTK solution), and CP3 group (Del Nido solution). After 1h, the highest mitochondrial respiration rate was observed in the CP3 group and the lowest in the CP1 group (p = 0.006). After adding ADP substrate, the highest mitochondrial ATP-production-coupled respiration was recorded in the CP3 group, which was similar to the control group CP0. After 3h, while evaluating the ratio between mitochondrial respiration ATP-production coupled and basal respiration, significant differences were found between CP1 group and CP3 group (p = 0.035), as well as between the CP1 and CP0 groups (p = 0.045). Additionally, by assessing the condition of the outer mitochondrial membrane using the Cyt C effect (Cyt/Phos [ADP]), significant differences were observed between the CP1 and CP3 group (p = 0.004), as well as between CP1 and CP0 groups (p = 0.003). Del Nido cardioplegic solution provided optimal mitochondrial protection under moderate and long myocardial ischemia conditions.

TFAM and Mitochondrial Protection in Diabetic Kidney Disease.

Diabetic kidney disease (DKD) is a significant complication of diabetes and a major cause of end-stage renal disease. Affecting around 40% of diabetic patients, DKD poses substantial economic burdens due to its prevalence worldwide. The primary clinical features of DKD include the leakage of proteins into the urine, altered glomerular filtration, and an increased risk of cardiovascular diseases. Current treatments focus on managing hypertension and hyperglycemia to slow the progression of DKD. These include the use of SGLT2 inhibitors to control blood sugar and ACE inhibitors to reduce blood pressure. Despite these measures, current treatments do not cure DKD and fail to address its underlying causes. Emerging research highlights mitochondrial dysfunction as a pivotal factor in DKD progression. The kidneys' high energy requirements make them particularly susceptible to disturbances in mitochondrial function. In DKD, mitochondrial damage leads to reduced energy production and increased oxidative stress, exacerbating tissue damage. Mitochondrial DNA (mtDNA) damage is a key aspect of this dysfunction, with studies suggesting that changes in mtDNA copy number can serve as biomarkers for the progression of the disease. Efforts to target mitochondrial dysfunction are gaining traction as a potential therapeutic strategy. This includes promoting mitochondrial health through pharmacological and lifestyle interventions aimed at enhancing mitochondrial function and reducing oxidative stress. Such approaches could lead to more effective treatments that directly address the DKD.

New Chalcone-Derived Molecule for the Topical Regulation of Hyperpigmentation and Skin Aging.

Background/Objectives: Skin hyperpigmentation is a biological process that results in an excessive production of melanin and is highly regulated by several mechanisms, tyrosinase being one of the key enzymes involved. Current reported inhibitors lack clinical efficacy, show toxic side effects, have poor bioavailability, or low formulation compatibility. The aim of this study was to design a new effective tyrosinase inhibitor for topical hyperpigmentation and anti-aging treatments. Methods: Homology modeling was used to build the tridimensional structure of human tyrosinase, and virtual docking was used to predict molecule-enzyme binding modes. The tyrosinase activity of the designed and synthesized compounds was assessed and water solubility was determined by HPLC. Cell assays were performed to determine melanin content, cytotoxicity, wound healing, anti-glycation, antioxidation, and autophagy efficacy. Gene expression and miRNA levels were quantified by qPCR and chromatin accessibility by ATAC-Seq. Human reconstructed epidermis was used to test the depigmenting efficacy as well as the skin irritation potential. Results: The 3D structure of human tyrosinase was designed and validated. The new molecule could effectively inhibit human tyrosinase and melanin synthesis in 2D monocultures and a 3D epidermis model. Two melanogenesis-related miRNAs were increased in treated cells. Anti-glycation, antioxidant, mitochondria protection, autophagy activation, and wound healing properties were also observed, with special emphasis on epigenetics. Conclusions: The designed molecule is a potential candidate to be used as a depigmenting and anti-aging agent, with suitable properties to be introduced in final product formulations for dermatology or cosmetics treatments.

Cardioprotective effects of nicorandil on mitochondrial apoptosis signaling in the failing heart of cardiac-specific Bcl-2-associated athanogene (BAG) 3 knockout mice

Abstract Background Bcl-2-associated athanogene (BAG) 3 is a known regulator of mitochondrial apoptotic cell death and autophagic protein degradation in the heart. Disruption of the BAG3 gene in a cardiac-specific manner can lead to cardiac failure in mice. However, therapeutic approaches for cardiac failure induced by BAG3 gene disruption remain poorly understood. Method and results We characterized mice with the ablated BAG3 gene using the Cre-recombinase-loxp site system in a cardiac-specific manner (BAG3f/f crossbred with cardiac specific Cre transgenic mice; BAG3 cKO) and examined the therapeutic effect of nicorandil, an antianginal drug, in BAG3 cKO mice. Cardiac BAG3 levels were markedly reduced in the cytoplasmic and mitochondrial fractions from the hearts of BAG3 cKO mice compared to BAG3f/f mice. BAG3cKO mice exhibited cardiac disease such as a reduction in fractional shortening detected by echocardiography, cardiac fibrosis at 6 months of age, and approximately 40% premature death by 6 months of age. Electron microscopy analysis confirmed cardiomyocyte loss and mitochondrial abnormalities in some areas of the heart section from BAG3cKO mice at 4.5 months of age. A marked decrease in the level of cytochrome C in the mitochondrial fraction and a slight increase in the cytoplasmic fraction, along with apoptotic cell death, were observed in hearts from BAG3 cKO mice at 4.5 months. Mitochondrial levels of anti-apoptotic factors, such as Bcl-2 and Bcl-xl, were reduced, while there was a marked increase in Bak1, an apoptotic inducible factor, in hearts from BAG3 cKO mice at 4.5 months of age. These results suggest that cardiac mitochondrial impairment and subsequent apoptotic cell death occurred in BAG3cKO mice. Nicorandil treatment (81 mg/L drinking water) initiated at 2 months of age prevented the reduction of fractional shortening, cardiac fibrosis, ultrastructural cardiac abnormalities, and premature death. Furthermore, nicorandil treatment prevented the decrease in mitochondrial cytochrome C and the increase in cytoplasmic cytochrome C in hearts from BAG3 cKO mice at 4.5 months of age. Nicorandil treatment also inhibited the elevation of mitochondrial Bak1 levels, reduction in Bcl-2 levels, and occurrence of apoptotic cell death in hearts from BAG3 cKO mice at 4.5 months of age. Conclusion Long-term treatment with nicorandil can inhibit cardiac disease induced by cardiac- specific BAG3 ablation through mitochondrial protection via the prevention of activation of mitochondrial apoptosis signaling.

Mitochondrial Dysfunction and Ion Imbalance in a Rat Model of Hemodialysis-Induced Myocardial Stunning.

Background/Objectives: Hemodialysis-induced myocardial stunning (HIMS) is a frequent complication in patients undergoing maintenance hemodialysis, characterized by transient left ventricular dysfunction due to ischemic episodes. Mitochondrial dysfunction and fluctuations in key ions such as potassium (K+) and calcium (Ca2+) are implicated in the pathogenesis of HIMS. This study aims to investigate the role of mitochondrial dysfunction and the protective potential of mitochondrial ATP-sensitive potassium channels (mitoKATP) in mitigating HIMS. Methods: A 5/6 nephrectomy rat model was established to mimic chronic kidney disease and the subsequent HIMS. The effects of mitoKATP channel modulators were evaluated by administering diazoxide (DZX), a mitoKATP opener, and 5-hydroxydecanoate (5-HD), a mitoKATP blocker, before hemodialysis. Mitochondrial function was assessed by measuring membrane potential, ATP synthase activity, and intramitochondrial Ca2+ levels. Myocardial function was evaluated using speckle tracking echocardiography. Results: Rats undergoing hemodialysis exhibited significant reductions in left ventricular strain and synchrony. DZX administration significantly improved mitochondrial function and reduced myocardial strain compared to controls. Conversely, 5-HD worsened mitochondrial swelling and disrupted myocardial function. Higher K+ and Ca2+ concentrations in the dialysate were associated with improved mitochondrial energy metabolism and myocardial strain. Conclusions: Mitochondrial dysfunction and ion imbalances during hemodialysis are key contributors to HIMS. The activation of mitoKATP channels provides mitochondrial protection and may serve as a potential therapeutic strategy to mitigate HIMS.

Attenuating mitochondrial dysfunction-derived reactive oxygen species and reducing inflammation: the potential of Daphnetin in the viral pneumonia crisis.

Amidst the global burden of viral pneumonia, mitigating the excessive inflammatory response induced by viral pneumonia has emerged as a significant challenge. Pneumovirus infections can lead to the persistent activation of M1 macrophages, culminating in cytokine storms that exacerbate pulmonary inflammation and contribute to the development of pulmonary fibrosis. Mitochondria, beyond their role as cellular powerhouses, are pivotal in integrating inflammatory signals and regulating macrophage polarization. Mitochondrial damage in alveolar macrophages is postulated to trigger excessive release of reactive oxygen species (ROS), thereby amplifying macrophage-mediated inflammatory pathways. Recent investigations have highlighted the anti-inflammatory potential of Daphnetin, particularly in the context of cardiovascular and renal disorders. This review elucidates the mechanisms by which viral infection-induced mitochondrial damage promotes ROS generation, leading to the phenotypic shift of alveolar macrophages towards a pro-inflammatory state. Furthermore, we propose a mechanism whereby Daphnetin attenuates inflammatory signaling by inhibiting excessive release of mitochondrial ROS, thus offering mitochondrial protection. Daphnetin may represent a promising pharmacological intervention for viral pneumonia and could play a crucial role in addressing future pandemics.

Dihydrolipoamide S-acetyltransferase activation alleviates diabetic kidney disease via AMPK-autophagy axis and mitochondrial protection

Diabetic kidney disease (DKD), a severe complication of diabetes marked by deregulated glucose metabolism, remains enigmatic in its pathogenesis. Herein, we delved into the functional role of Dihydrolipoamide S-acetyltransferase (DLAT), a pivotal E2 component of the pyruvate dehydrogenase complex (PDC), in the context of DKD. Our findings revealed a downregulation of DLAT in the kidneys of diabetic patients, correlating inversely with kidney function. Parallel downregulation was observed in both high-fat diet/streptozotocin (HFD/STZ) and db/db mouse models, as well as in human proximal tubular epithelial cells (HK-2) cultured under hyperglycemic conditions. To further elucidate the role of endogenous DLAT in DKD, we employed genetic ablation of Dlat in mouse models. Dlat haploinsufficient mice exhibited exacerbated renal dysfunction, structural damage, fibrosis, and mitochondrial dysfunction under DKD conditions. Consistent with these findings, modulation of DLAT expression in HK-2 cells highlighted its influence on fibrosis, with overexpression attenuating Fibronectin and Collagen I levels, while downregulation exacerbated fibrosis. Mechanistically, we discovered that DLAT activates mitochondria autophagy through the Adenosine 5′-monophosphate (AMP)-activated protein kinase (AMPK) signaling pathway, thereby mitigating mitochondrial dysfunction associated with DKD progression. Inhibition of AMPK abrogated the protective effects of DLAT against mitochondrial dysfunction and DKD. Notably, we identified Hyperforin (HPF), a phytochemical, as a potential therapeutic agent. HPF activates DLAT and AMPK, subsequently ameliorating renal dysfunction, injuries, and fibrosis in both in vivo and in vitro models. In summary, our study underscores the pivotal role of DLAT and AMPK in kidney health and highlights the therapeutic potential of HPF in treating DKD.

Xiaoyin-anshen formula alleviates psoriasis complicated by sleep disturbances by regulating melatonin, antioxidant enzymes, and pro-inflammatory cytokines in mice.

Psoriasis is a common autoimmune and chronic inflammatory dermatological disease that is mainly associated with aberrant immune response and oxidative stress (OS). OS, a crucial pathogenic factor in psoriasis, contributes to psoriasis-like inflammation mediated by the IL-23/IL-17 inflammatory axis. Sleep disturbances (SDs), highly prevalent in patients with psoriasis, exacerbate the condition by disrupting circadian rhythms and reducing melatonin levels, thus promoting OS and inflammation. Xiaoyin-Anshen formula (XYAS), a traditional Chinese medicine (TCM) formula, is composed of the Liangxue-Jiedu (LXJD) and Qingxin-Anshen (QXAS) TCM compounds and has been demonstrated to be effective in treating psoriasis complicated by SDs. However, its exact pharmacological mechanism remains uncertain. Thus, this study used animal experiments to verify whether XYAS can exert therapeutic effects on the disease by regulating melatonin (MLT) levels, protecting against OS, and inhibiting psoriasis-like skin inflammation. A mouse model for psoriasis combined with SDs was established by smearing 62.5mg of 5% imiquimod (IMQ) cream for seven consecutive days, along with a daily injection of p-chlorophenyl alanine (PCPA) solution at a dosage of 300mg/kg at days 6-7. The IMQ cream was continued to be used for maintaining the model at days 8-14. Mice were randomly divided into groups: control, model, MLT, XYAS, LXJD, QXAS. Each group was treated according to its designation at days 8-14, receiving either an oral gavage of XYAS/LXJD/QXAS solution at a dosage of 2mL/100g per day, or a daily injection of MLT solution at a concentration of 0.25mg/mL, with a dosage of 5mg/kg. Immunohistological analysis, pentobarbital-induced sleep test, Western blotting, and enzyme-linked immunosorbent assay (ELISA) were performed to assess and compare pathological features, sleep conditions, localization and/or levels of manganese-dependent superoxide dismutase (mnSOD), mitochondrial cytochrome c (Cyt-C), MLT, retinoid-related orphan nuclear receptor-α (RORα), and pro-inflammatory cytokines interleukin (IL)-6, IL-17A, and tumor necrosis factor-alpha (TNF-α) among groups. MLT, XYAS, LXJD, and QXAS exhibited varying therapeutic effects on RORα regulation, OS inhibition, mitochondrial protection, and anti-inflammation. Compared to the model, the lesion severity/thickness and serum IL-6, IL-17A, and TNF-α levels were gradually reduced in the MLT, QXAS, LXJD, and XYAS. However, no statistical difference in TNF-α levels was identified between the MLT and the model groups. Additionally, skin MLT levels gradually increased in the MLT, QXAS, and XYAS groups, while RORα levels gradually increased in the MLT, QXAS, LXJD, and XYAS groups. All treatments increased mnSOD levels and reduced Cyt-C levels in skin lesions, with XYAS showing the most significant changes. XYAS may treat psoriasis complicated by SDs through two main mechanisms: (1) Improving melatonin-RORα axis in the skin can lead to an increase in mnSOD and a reduction in Cyt-C levels, which provide protection against oxidative stress, mitochondrial damage, and psoriatic inflammation. (2) Reducing IL-6, IL-17A, and TNF-α production to suppress IL-23/Th17 pro-inflammatory signaling axis and epidermal hyperplasia in psoriasis.

New Application of an Old Drug: Anti-Diabetic Properties of Phloroglucinol.

Phloroglucinol (PHG), an analgesic and spasmolytic drug, shows promise in preventing high-fat-diet (HFD)-induced non-alcoholic fatty liver disease (NAFLD) and insulin resistance. In Wistar rats, 10 weeks of PHG treatment did not prevent HFD-induced weight gain but significantly mitigated fasting hyperglycemia, impaired insulin responses, and liver steatosis. This protective effect was not linked to hepatic lipogenesis or AMP-activated protein kinase (AMPK) activation. Instead, PHG improved mitochondrial function by reducing oxidative stress, enhancing ATP production, and increasing anti-oxidant enzyme activity. PHG also relaxed gastric smooth muscles via potassium channel activation and nitric oxide (NO) signaling, potentially delaying gastric emptying. A pilot intervention in pre-diabetic men confirmed PHG's efficacy in improving postprandial glycemic control and altering lipid metabolism. These findings suggest PHG as a potential therapeutic for NAFLD and insulin resistance, acting through mechanisms involving mitochondrial protection, anti-oxidant activity, and gastric motility modulation. Further clinical evaluation is warranted to explore PHG's full therapeutic potential.