Gasotransmitter Research Articles

Disrupted Nitric Oxide Homeostasis Impacts Fertility through Multiple Processes Including Protein Quality Control

Abstract Plant fertility is fundamental to plant survival and requires the coordinated interaction of developmental pathways and signaling molecules. Nitric oxide (NO) is a small, gaseous signaling molecule that plays crucial roles in plant fertility as well as other developmental processes and stress responses. NO influences biological processes through S-nitrosation, the posttranslational modification of protein cysteines to S-nitrosocysteine (R-SNO). NO homeostasis is controlled by S-nitrosoglutathione reductase (GSNOR), which reduces S-nitrosoglutathione (GSNO), the major form of NO in cells. GSNOR mutants (hot5-2/gsnor1) have defects in female gametophyte development along with elevated levels of reactive nitrogen species and R-SNOs. To better understand the fertility defects in hot5-2, we investigated the in vivo nitrosoproteome of Arabidopsis (Arabidopsis thaliana) floral tissues coupled with quantitative proteomics of pistils. To identify protein-SNOs, we used an organomercury-based method that involves direct reaction with S-nitrosocysteine, enabling specific identification of S-nitrosocysteine–containing peptides and S-nitrosated proteins. We identified 1102 endogenously S-nitrosated proteins in floral tissues, of which 1049 were unique to hot5-2. Among the identified proteins, 728 were novel S-nitrosation targets. Notably, specific UDP-glycosyltransferases and argonaute proteins are S-nitrosated in floral tissues and differentially regulated in pistils. We also discovered S-nitrosation of subunits of the 26S proteasome together with increased abundance of proteasomal components and enhanced trypsin-like proteasomal activity in hot5-2 pistils. Our data establish a method for nitrosoprotein detection in plants, expand knowledge of the plant S-nitrosoproteome, and suggest that nitro-oxidative modification and NO homeostasis are critical to protein quality control in reproductive tissues.

Experimental Insights into the Formation, Reactivity, and Crosstalk of Thionitrite (SNO−) and Perthionitrite (SSNO−)

AbstractHydrogen sulfide (H2S) and nitric oxide (NO) are important gaseous biological signaling molecules that are involved in complex cellular pathways. A number of physiological processes require both H2S and NO, which has led to the proposal that different H2S/NO⋅ crosstalk species, including thionitrite (SNO−) and perthionitrite (SSNO−), are responsible for this observed codependence. Despite the importance of these S/N hybrid species, the reported properties and characterization, as well as the fundamental pathways of formation and subsequent reactivity, remain poorly understood. Herein we report new experimental insights into the fundamental reaction chemistry of pathways to form SNO− and SSNO−, including mechanisms for proton‐mediated interconversion. In addition, we demonstrate new modes of reactivity with other sulfur‐containing potential crosstalk species, including carbonyl sulfide (COS).

Ore sulfur of Golovnin Volcano, Kunashir Island

Research subject. Hydrothermal deposits of Golovnin Caldera. Aim. To study the epithermal volcanogenic ore formation. Key points. Until now, there has been a consensus on the exogenous sedimentary (colloidal) genesis of sulfur in volcanic lakes. Our observations and microstructure studies indicate the presence of sulfur melt at the bottom of Kipyaschee Lake. Drops of this melt are carried to the surface of the lake as part of a light gray foam. The significant differences of sulfur spherules in the concentration of sulfide mineralization, in its composition, as well as in the presence or absence of numerous opal inclusions are most simply explained by the capture of droplets in various parts of the sulfur melt and their subsequent movement by a gas stream passing through the melt. Elemental sulfur condensate is formed in bottom sediments as a result of forced cooling of endogenous gas flows by lake water. The main condensation of sulfur occurs here (96% or more of the total potential of fluid sulfur). Residual condensation of sulfur occurs in the aquatic environment. Finely dispersed sulfur condensate in a mixture with water is unstable and breaks down over time with the release of hydrogen sulfide and the formation of sulfurous and sulfuric acids. The activity of bottom hydrotherms and coastal unrest prevents the formation of colloidal sulfur sediment at the bottom of lakes. In the crater depressions at the bottom of the lakes of the Golovnin Caldera, sulfidization of its melt occurs simultaneously with the condensation of sulfur itself. Gravitational deposition of sulfides in the sulfur melt leads to their enrichment of the root parts of crater depressions, where pyrite ore bodies are formed in real time. Terrestrial sulfur deposits, together with the modified rocks overlying them, demonstrate the full profile of endogenous apical oxidation under gas-hydrothermal action: sulfur and sulfur-opal rocks up the section are replaced by gypsum-jarosite rocks and, further, by an “iron hat” of limonite-cemented breccias of the dome mantle. Conclusions. Observations, microstructure studies and molecular chemical modeling indicate the endogenous condensate origin of ore sulfur in the Golovnin Caldera and exclude its exogenous sedimentary genesis.

Hydrogen Sulfide‐Triggered Artificial DNAzyme Switches for Precise Manipulation of Cellular Functions

AbstractThe development of synthetic molecular tools responsive to biological cues is crucial for advancing targeted cellular regulation. A significant challenge is the regulation of cellular processes in response to gaseous signaling molecules such as hydrogen sulfide (H2S). To address this, we present the design of Gas signaling molecule‐Responsive Artificial DNAzyme‐based Switches (GRAS) to manipulate cellular functions via H2S‐sensitive synthetic DNAzymes. By incorporating stimuli‐responsive moieties to the phosphorothioate backbone, DNAzymes are strategically designed with H2S‐responsive azide groups at cofactor binding locations within the catalytic core region. These modifications enable their activation through H2S‐reducing decaging, thereby initiating substrate cleavage activity. Our approach allows for the flexible customization of various DNAzymes to regulate distinct cellular processes in diverse scenarios. Intracellularly, the enzymatic activity of GRAS promotes H2S‐induced cleavage of specific mRNA sequences, enabling targeted gene silencing and inducing apoptosis in cancer cells. Moreover, integrating GRAS with dynamic DNA assembly allows for grafting these functional switches onto cell surface receptors, facilitating H2S‐triggered receptor dimerization. This extracellular activation transmits signals intracellularly to regulate cellular behaviors such as migration and proliferation. Collectively, synthetic switches are capable of rewiring cellular functions in response to gaseous cues, offering a promising avenue for advanced targeted cellular engineering.

The SlbHLH92 transcription factor enhances salt stress resilience by fine-tuning hydrogen sulfide biosynthesis in tomato

Ongoing soil salinization severely hampers plant growth and the sustainability of global crops production. Hydrogen sulfide (H2S), acting as a critical gaseous signaling molecule, plays a vital role in plant response to various environmental cues such as salt stress. Nonetheless, it is not well understood how the transcriptional network regulates H2S production in response to salt stress in tomato. Herein, we determine that the bHLH transcription factor SlbHLH92 functions as a transcriptional activator in tomato (Solanum lycopersicum L.), upregulating the expression of the L-CYSTEINE DESULFHYDRASE 1 (SlLCD1) gene involved in H2S biosynthesis, thereby enhancing the plants' tolerance to salt stress. When exposed to salt stress, overexpression of SlbHLH92 in tomato leads to enhanced salt tolerance compared to wild-type plants. In contrast, suppression of SlbHLH92 expression with RNAi silencing results in increased sensitivity to salt stress. Subsequent molecular and biochemical investigations confirm that the salt-induced SlbHLH92 upregulates the expression of SlLCD1, leading to an increase in H₂S levels, as well as other salt-responsive genes (SlCBL10 and SlVQ16), by directly binding to specific cis-elements in their promoter regions. Furthermore, the VQ-motif containing protein SlVQ16 physically interacts with SlbHLH92, thereby promoting an increase in its transcriptional activity. Taken together, our study reveals an emerging mechanism in which the SlbHLH92-SlVQ16-H2S signaling cascade contributes to enhancing salt tolerance in tomato, presenting potential genetic targets for breeding salt-tolerant tomato cultivars.

Potential Beneficial Role of Nitric Oxide in SARS-CoV-2 Infection: Beyond Spike-Binding Inhibition

SARS-CoV-2, the causative virus for the COVID-19 disease, uses its spike glycoprotein to bind to human ACE2 as a first step for viral entry into the cell. For this reason, great efforts have been made to find mechanisms that disrupt this interaction, avoiding the infection. Nitric oxide (NO) is a soluble endogenous gas with known antiviral and immunomodulatory properties. In this study, we aimed to test whether NO could inhibit the binding of the viral spike to ACE2 in human cells and its effects on ACE2 enzymatic activity. Our results show that ACE2 activity was decreased by the NO donors DETA-NONOate and GSNO and by the NO byproduct peroxynitrite. Furthermore, we found that DETA-NONOate could break the spike–ACE2 interaction using the spike from two different variants (Alpha and Gamma) and in two different human cell types. Moreover, the same result was obtained when using NO-producing murine macrophages, while no significant changes were observed in ACE2 expression or distribution within the cell. These results support that it is worth considering NO as a therapeutic agent for COVID-19, as previous reports have suggested.

Nitric Oxide-Photodelivering Materials with Multiple Functionalities: From Rational Design to Therapeutic Applications.

The achievement of materials that are able to release therapeutic agents under the control of light stimuli to improve therapeutic efficacy is a significant challenge in health care. Nitric oxide (NO) is one of the most studied molecules in the fascinating realm of biomedical sciences, not only for its crucial role as a gaseous signaling molecule in the human body but also for its great potential as an unconventional therapeutic in a variety of diseases including cancer, bacterial and viral infections, and neurodegeneration. Handling difficulties due to its gaseous nature, reduced region of action due to its short half-life, and strict dependence of the biological effects on its concentration and generation site are critical questions to be solved for appropriate therapeutic uses of NO. Light-activatable NO precursors, namely, NO photodonors (NOPDs), address the above issues since they are stable in the dark and permit in a noninvasive fashion the remote-controlled delivery of NO on demand with great spatiotemporal precision. Engineering biocompatible materials with NOPDs and their combination with additional imaging, therapeutic, and phototherapeutic components leads to intriguing light-responsive multifunctional constructs exhibiting promising potential for biomedical applications. This contribution illustrates the most significant progress made over the last five years in achieving engineered materials including nanoparticles, gels, and thin films, sharing the common feature to deliver NO under the exclusive control of the biocompatible visible/near infrared light inputs. We will highlight the logical design behind the fabrication of these systems, illustrating the potential therapeutic applications with particular emphasis on cancer and bacterial infections.

Green-Light-Triggered and Self-Calibrated Cascade Release of Nitric Oxide and Carbon Monoxide for Synergistic Glaucoma Therapy.

Glaucoma is an optic degenerative neuropathy that is driven by a vicious cycle of oxidative stress and mechanical stress. Current clinical treatments aim exclusively at alleviating mechanical stress by reducing the intraocular pressure (IOP). With the unattended oxidative stress, recurrence and deterioration of mechanical stress are inevitable. Nitric oxide (NO) and carbon monoxide (CO) are endogenous gaseous signaling molecules for vasodilation and anti-inflammation, respectively. Mounting evidence suggests an intricate interplay between NO and CO to mediate their biological roles, like how it takes two to dance a waltz. This leads to the concept of "gas waltz therapy" for glaucoma, in which NO is released to reduce IOP and stoichiometric CO is coreleased to suppress oxidative stress. CND570 is the first phototriggered cascade NO/CO donor, to the best of our knowledge. Notably, the release of NO/CO is accompanied by the concomitant release of a rhodamine dye whose bright fluorescence is harnessed as a convenient calibration mechanism of the gas release profile. CND570 exhibits excellent transcorneal permeability and reaches the target aqueous humor outflow pathway. Further, green-light irradiation triggers release of CO and NO in the eye tissue of glaucoma mice. NO and CO could promote the upregulation of soluble guanylate cyclase (sGC) in both in vitro and in vivo models. Notably, CND570 treatment significantly reduces the oxidative stress associated with glaucoma. NO/CO-based gas waltz therapy is a promising new avenue for glaucoma treatment.

Characterization of the gibberellic oxidase gene SdGA20ox1 in Sophora davidii (Franch.) skeels and interaction protein screening.

Gibberellin 20-oxidases (GA20oxs) are multifunctional enzymes involved in regulating gibberellin (GA) biosynthesis and controlling plant growth. We identified and characterized the GA20ox1 gene in a plant height mutant of Sophora davidii, referred to as SdGA20ox1. This gene was expressed in root, stem, and leaf tissues of the adult S. davidii plant height mutant, with the highest expression observed in the stem. The expression of SdGA20ox1 was regulated by various exogenous hormones. Overexpression of SdGA20ox1 in Arabidopsis resulted in significant elongation of hypocotyl and root length in seedlings, earlier flowering, smaller leaves, reduced leaf chlorophyll content, lighter leaf color, a significant increase in adult plant height, and other phenotypes. Additionally, transgenic plants exhibited a substantial increase in biologically active endogenous GAs (GA1, GA3, and GA4) content, indicating that overexpression of SdGA20ox1 accelerates plant growth and development. Using a yeast two-hybrid (Y2H) screen, we identified two SdGA20ox1-interacting proteins: the ethylene receptor EIN4 (11430582) and the rbcS (11416005) protein. These interactions suggest a potential regulatory mechanism for S. davidii growth. Our findings provide new insights into the role of SdGA20ox1 and its interacting proteins in regulating the growth and development of S. davidii.

Sodium Hydrosulfide Protects Rats from Hypobaric-Hypoxia-Induced Acute Lung Injury

Hydrogen sulfide (H2S), as a key gas signaling molecule, plays an important role in regulating various diseases, with appropriate concentrations providing antioxidative, anti-inflammatory, and anti-apoptotic effects. The specific role of H2S in acute hypoxic injury remains to be clarified. This study focuses on the H2S donor sodium hydrosulfide (NaHS) and explores its protective effects and mechanisms against acute hypoxic lung injury. First, various mouse hypoxia models were established to evaluate H2S’s protection in hypoxia tolerance. Next, a rat model of acute lung injury (ALI) induced by hypoxia at 6500 m above sea level for 72 h was created to assess H2S’s protective effects and mechanisms. Evaluation metrics included blood gas analysis, blood routine indicators, lung water content, and lung tissue pathology. Additionally, LC-MS/MS and bioinformatic analyses were combined in performing quantitative proteomics on lung tissues from the normoxic control group, the hypoxia model group, and the hypoxia model group with NaHS treatment to preliminarily explore the protective mechanisms of H2S. Further, enzyme-linked immunosorbent assays (ELISA) were used to measure oxidative stress markers and inflammatory factors in rat lung tissues. Lastly, Western blot analysis was performed to detect Nrf2, HO-1, P-NF-κB, NF-κB, HIF-1α, Bcl-2, and Bax proteins in lung tissues. Results showed that H2S exhibited significant anti-hypoxic effects in various hypoxia models, effectively modulating blood gas and blood routine indicators in ALI rats, reducing pulmonary edema, improving lung tissue pathology, and alleviating oxidative stress, inflammatory responses, and apoptosis levels.

Experimental Insights into the Formation, Reactivity, and Crosstalk of Thionitrite (SNO-) and Perthionitrite (SSNO-).

Hydrogen sulfide (H2S) and nitric oxide (NO) are important gaseous biological signaling molecules that are involved in complex cellular pathways. A number of physiological processes require both H2S and NO, which has led to the proposal that different H2S/NO• crosstalk species, including thionitrite (SNO-) and perthionitrite (SSNO-), are responsible for this observed codependence. Despite the importance of these S/N hybrid species, the reported properties and characterization, as well as the fundamental pathways of formation and subsequent reactivity, remain poorly understood. Herein we report new experimental insights into the fundamental reaction chemistry of pathways to form SNO- and SSNO-, including mechanisms for proton-mediated interconversion. In addition, we demonstrate new modes of reactivity with other sulfur-containing potential crosstalk species, including carbonyl sulfide (COS).

H2S protects rat cerebral ischemia-reperfusion injury by inhibiting expression and activation of hippocampal ROCK2 at the Thr436 and Ser575 sites

BackgroundH2S is an endogenous gas signal molecule, which protects cerebral ischemia/reperfusion (I/R) injury by phosphorylating rho-associated coiled coil-containing protein kinase 2 (ROCK2) at Tyr722, and inhibiting ROCK2 protein expression and activities. We previously reported that H2S protected rat neurons from hypoxia/reoxygenation injury in vitro through inhibiting phosphorylation of ROCK2 at Thr436 and Ser575, but it is unclear whether these two sites are involved in protection of H2S against cerebral I/R injury. MethodRats transfected with wild-type and mutant eukaryotic plasmids of ROCK2 in hippocampus were used to establish I/R model by ligating bilateral common carotid artery. Rat behavioral deficit was detected by water maze assay, and ROCK2, lactate dehydrogenase (LDH), nerve-specific enolase (NSE) and reactive oxygen species (ROS) were determined by ELISA. ROCK2 expressions was examined by western-blot assay, and bcl-2 and Bax mRNAs were examined by RT-qPCR. ResultsNaHS (4.8mg/kg) significantly inhibited the I/R-increased serum LDH, NSE and ROS in the ROCK2wild-pEGFP-N1-transfected rats, but had no obvious effect in the ROCK2T436A-pEGFP-N1- or the ROCK2S575F-pEGFP-N1-transfected rats; inhibitions of NaHS on the I/R-increased escape latency and the I/R-decreased percentage of target quadrant distance to total distance were markedly attenuated or abolished in the ROCK2T436A-pEGFP-N1- or the ROCK2S575F-pEGFP-N1-transfected rats compared with those in the ROCK2wild-pEGFP-N1-transfected rats; NaHS obviously inhibited the I/R-increased hippocampal ROCK2 and GFP-ROCK2 proteins, Bax mRNA, and ROCK2 activity, as well as the I/R-decreased hippocampal bcl-2 mRNA in the hippocampus of the ROCK2wild-pEGFP-N1-transfected rats, but had no significant effect in the ROCK2T436A-pEGFP-N1- or the ROCK2S575F-pEGFP-N1-transfected rats. ConclusionH2S protects cerebral I/R injury in rats by inhibiting expression and activation of hippocampal ROCK2 via the Thr436 and Ser575 sites.

Poly(L-lactide-co-ɛ-caprolactone)/gelatin-based small-diameter vascular grafts: Salutatory effect of the BVLD and EGCG-Cu to promote hemocompatibility and nitric oxide production for in situ blood vessel regeneration

Polymeric small-diameter vascular grafts (SDVGs, inner diameter, < 6 mm) with characteristics, such as thrombo-protection and adequate short-term as well as long-term patency are still in the development and exploration stage. In this study, based on the gas signaling molecule release strategy, SDVGs were prepared by electrospinning using poly(L-lactide-co-ɛ-caprolactone) (PLCL) and gelatin (Gel). Bivalirudin (BVLD) and epigallocatechin gallate-copper (EGCG-Cu) complex were loaded into SDVGs to improve hemocompatibility and nitric oxide (NO) release, respectively. Vascular grafts manifested drug release for up to 40 days in vitro; BVLD effectively inhibited thrombosis while the EGCG-Cu complex catalyzed the NO production from endogenous donors (S-nitroso glutathione (GSNO) and glutathione (GSH)), thereby conferring vascular grafts with functions similar to that of the natural vascular endothelium layer. Both in vitro and in vivo tests demonstrated that SDVGs co-loaded with BVLD and EGCG-Cu (PG-EB) could effectively inhibit thrombosis, alleviate inflammation, and suppress the proliferation of smooth muscle cells (SMCs) while promoting the proliferation of endothelial cells (ECs), and finally regenerate vascular tissues. In vivo animal experiments demonstrated that vascular grafts could promote endothelialization and vascular remodeling. In summary, our simultaneous utilization of BVLD and EGCG-Cu may offer a promising avenue for the fabrication of in situ regenerable SDVGs.

A coumarin-based fluorescent probe for imaging H2S and distinguishing breast cancer cells from normal ones

Hydrogen sulfide (H2S) is a crucial endogenous gas signal molecule involved in several physiological functions. Elevation of H2S concentrations is considered a cancer biomarker because it may be connected to the growth of tumors. A thorough comprehension of measuring H2S in living cells and differentiating between malignant and normal cells is crucial. Herein, a multi-responsive probe (C-DNP) was constructed to detect H2S and observe the intramolecular charge transfer “turn-off” sensing mechanism caused by the intervention of the irradiative intramolecular charge transfer between C and DNP. Given that DNP recognizes H2S, a reaction between H2S and the probe-attached DNP could eliminate DNP via ether bond breakage and increased emission. Moreover, 1H NMR titrations, HR-MS, and density-functional theory (DFT) calculations confirmed the proposed sensing mechanism. The probe effectively monitored H2S in different water samples, food samples, paper sensor trips, and living cells. Surprisingly, the probe distinguished tumor-bearing cells from normal cells by expressing the variations in H2S both exogenously and endogenously in normal and breast cancer cells. Therefore, it is anticipated to be an efficient method for monitoring H2S in real samples and biosystems.

Disrupting the activity of endogenous gas neurotransmitters: a therapeutic strategy using engineered metal-organic frameworks for cancer.

Disrupting the activity of endogenous gas neurotransmitters: a therapeutic strategy using engineered metal-organic frameworks for cancer.

Endoplasmic reticulum-targeting fluorescence turn-on probe for nitric oxide detection in living cells and serum samples

Nitric oxide (NO) is an important gas signaling molecule, and endoplasmic reticulum (ER) stress induced by NO may be related to the pathogenesis of many diseases. Therefore, the development of ER-targeted fluorescent probes for NO is of great significance to investigate the relationship between ER stress and NO concentration changes in related diseases. Herein, an ER-targeted fluorescent probe (ER-Np) for sensing NO was constructed. ER-Np was served as an excellent tool for detection NO with high selectivity, sensitivity and ER-targetable ability. Moreover, fluorescence imaging experiments indicated that ER-Np is capable of imaging NO in living cells. Impressively, visualization of endogenous NO production during dithiothreitol (DTT)-induced ER stress in living cells was successfully observed. In addition, we found that serum NO levels were upregulated in epilepsy children, which opens up a new avenue for further understanding the relationship between the diagnostic of epilepsy.

On-demand release of CO in dual-responsive nanocomposite hydrogels for wound dressing

Gaseous signaling molecules, especially carbon monoxide (CO), hold promising potential for disease management. The therapeutic efficacy of CO is closely tied to its concentration, however, maintaining it at optimal levels for both efficacy and safety is highly challenging. To address this, we designed a dual-responsive (pH/red light) nanocomposite hydrogel for on-demand CO release. We first synthesized a hybrid nanocomposite (CaCO3@AgCCN) comprising a CO2 donor (CaCO3) and a photocatalyst (Ag3PO4-decorated carbon dot g-C3N4, AgCCN) capable of converting CO2 to CO. The size of CaCO3 particles was approximately 40 nm, while that of AgCCN was around 150 nm in this nanocomposite. CaCO3@AgCCN was then incorporated into chitosan (CS) to form a nanocomposite hydrogel. This nanocomposite hydrogel could respond to a mildly acidic environment due to bacterial growth, generating CO2 exactly where it is needed (the wound site), which would be subsequently catalytically converted to CO by AgCCN under 630-nm red light illumination to facilitate wound healing. The generated CO, readily controlled by adjusting the CaCO3@AgCCN content in the nanocomposite hydrogel and the red-light illumination time (the CO concentration reaching 4.7 μM after 10-min illumination), has demonstrated strong bactericidal and anti-inflammatory effects, both essential in facilitating wound healing as shown in both in vitro and in vivo studies. Coupled with satisfactory biocompatibility, this dual-responsive nanocomposite hydrogel appears to hold great promise for safe and effective applications of CO in biomedical fields.

Hydrogen sulfide ameliorates non-alcoholic fatty liver disease in mice

Non-alcoholic fatty liver disease (NAFLD) is a clinicopathological syndrome characterized by excessive accumulation of intrahepatic fat and elevated hepatic metabolic enzyme levels, leading to hepatocellular vesicular steatosis. The global prevalence of this liver disease has been steadily increasing, closely associated with lifestyle factors such as obesity, hypertension, and hyperlipidemia. Notably, there is currently no approved pharmaceutical treatment for NAFLD. Hydrogen sulfide (H2S) is considered a vital gaseous signaling molecule in mammalian cells, playing a crucial role in various physiological and pathological processes. Numerous recent studies have demonstrated that H2S is involved in modulating a diverse array of biological functions. In vitro and in vivo research often utilizes various readily soluble organic or inorganic compounds H2S donors, such as sodium hydrosulfide, sodium sulfide, and GYY4137, which allow for controlled release and concentration adjustment of H2S, thereby facilitating the exploration of its biological effects and underlying mechanisms. Our findings indicate that H2S holds significant potential in reducing the accumulation of cellular lipid droplets and multiple lipid deposits, as evidenced by cellular and tissue staining, as well as triglyceride and total cholesterol assays. Subsequent transcriptomic analysis revealed a potential association between the degradation of lipid droplets by H2S and the activation of cellular autophagy. Validation through Western blotting in both cellular and animal models demonstrated that H2S effectively triggers autophagy through the AMP-activated protein kinase and mechanistic target of rapamycin pathway. This activation results in enhanced degradation of intracellular lipid content and decreased lipid accumulation in hepatocytes, ultimately ameliorating NAFLD in mice.

Hydrogen sulfide mitigates mitochondrial dysfunction and cellular senescence in diabetic patients: Potential therapeutic applications.

Diabetes induces a pro-aging state characterized by an increased abundance of senescent cells in various tissues, heightened chronic inflammation, reduced substance and energy metabolism, and a significant increase in intracellular reactive oxygen species (ROS) levels. This condition leads to mitochondrial dysfunction, including elevated oxidative stress, the accumulation of mitochondrial DNA (mtDNA) damage, mitophagy defects, dysregulation of mitochondrial dynamics, and abnormal energy metabolism. These dysfunctions result in intracellular calcium ion (Ca2+) homeostasis disorders, telomere shortening, immune cell damage, and exacerbated inflammation, accelerating the aging of diabetic cells or tissues. Hydrogen sulfide (H2S), a novel gaseous signaling molecule, plays a crucial role in maintaining mitochondrial function and mitigating the aging process in diabetic cells. This article systematically explores the specific mechanisms by which H2S regulates diabetes-induced mitochondrial dysfunction to delay cellular senescence, offering a promising new strategy for improving diabetes and its complications.

Visible light-triggered NIR ratiometric fluorescent metal-free CO-releasing molecule for self-monitoring of CO delivery and effective cancer therapy

Cancer is a serious global health issue, and exploring effective treatment methods is of great significance for cancer prevention and control. Carbon monoxide (CO), as an important gas signaling molecule in the life system, has been proven to have good anti-cancer effects. However, how to controllably, safely, and effectively deliver CO to the tumor site for clinical treatment remains a challenge. Herein, a new metal-free CO-releasing molecule COR-XAC was developed for controlling CO release and cancer therapy. COR-XAC is based on the hybrid of 3-hydroxyl flavone and oxanthracene fluorophores, showing visible light-controlled CO-releasing properties and near-infrared (NIR) ratiometric fluorescence changes at 690 and 760 nm. COR-XAC shows low cytotoxicity and can be successfully applied to release CO in cells and tumors, and the CO-releasing and delivery process could be monitored by its own NIR ratiometric fluorescence changes. More importantly, the anti-cancer performance of COR-XAC was evaluated in 4T1 tumor mice, and it was found that COR-XAC plus light illumination showed excellent tumor inhibition effect, which provided a promising new effective method for cancer treatment.