Rutin alleviates ventilator-induced lung injury by inhibiting NLRP3 inflammasome activation

Taxus chinensis (Pilg.) Rehder fruit attenuates aging behaviors and neuroinflammation by inhibiting microglia activation via TLR4/NF-κB/NLRP3 pathway

ETHNOPHARMACOLOGICAL RELEVANCE

As one of the important by-products of Taxus chinensis (Pilg.) Rehder, its fruit (TCF) has a sweet taste, which is commonly used in folklore to make health care wine reputed for enhancing immune function and promoting anti-aging effects, especially popular in the longevity villages of China for a long history. Evidences had showed that Taxus chinensis fruit contained polysaccharides, flavonoids, amino acids and terpenoids, which all were free of toxic compounds, but its medicinal value has not been fully recognized. Our previous studies have found that TCF extract may reverse many biological events, including oxidative stress, inflammatory response, neuronal apoptosis, etc. by in silico methods, suggesting potential avenues for future pharmaceutical exploration in aging and age-related diseases.

AIM OF THE STUDY

Yet, the anti-aging properties of TCF have not been specifically studied, this study aims to fill this gap by investigating the effects of TCF extract (TCFE) in an aging mouse model, particularly focusing on its role in inhibiting microglial activation and elucidating its underlying anti-aging mechanisms.

MATERIALS AND METHODS

An aging mouse model was induced using D-galactose, with interventions involving high, medium, and low doses of TCFE compared to a positive control (2 mg/kg rapamycin combined with 100 mg/kg metformin). The methodology involved evaluating behavioral changes, serum oxidative and antioxidative markers, hypothalamic β-galactosidase activity, expression of the aging-related protein P63, serum inflammatory factors, and the TLR4/NF-κB/NLRP3 inflammatory pathway in hypothalamic tissues. Additionally, to strengthen our in vivo findings, we conducted in vitro experiments on LPS-stimulated BV2 microglial cells. Finally, UPLC-MS/MS for precise component analysis using compound standards, coupled with molecular docking analyses, were employed to discern and elucidate the anti-inflammatory mechanisms of TCF.

RESULTS

In vivo results revealed TCFE significantly ameliorated behavioral deficits, reduced oxidative stress markers (MDA) and pro-inflammatory cytokines (IL1-β, IL-6, IFNg, TNFα, IL-17), and increased in antioxidants (SOD, T-AOC) and anti-inflammatory factors (IL-10). TCFE also reduced hypothalamic senescence, improved cellular integrity, lowered p63, and inhibited microglia activation and inflammatory pathways (TLR4, NFKB, NLRP3). The overall effect of TCFE was better than that of the positive drug group (rapamycin combined with metformin). In vitro results further revealed that TCFE markedly decreased IL1-β, NFKB, and TLR4 levels in BV2 microglial cells, showing comparable efficacy to a TLR4 classic positive inhibitor C34, supporting its anti-inflammatory role. Through UPLC-MS/MS analysis coupled with compound standards, we identified ten bioactive compounds, including gallocatechin, epigallocatechin, catechin, procyanidin B2, kaempferol, quercetin, rutin, naringin, apigenin, ginkgetin. All these compounds showed strong binding affinity to TLR4, notably procyanidin B2 and rutin, potentially through hydrogen bonds, aromatic cation-π interactions, and hydrophobic interactions, suggesting a molecular basis for their anti-inflammatory action.

CONCLUSION

TCFE showed strong anti-aging effects by inhibiting microglia activation and lessening oxidative stress and modulating inflammatory pathways. This research supports TCF's use in anti-aging and sets a base for future drug development in the realms of neuroinflammation and aging.

Injectable bioresponsive bone adhesive hydrogels inhibit NLRP3 inflammasome on demand to accelerate diabetic fracture healing

Diabetes is associated with excessive inflammation, which negatively impacts the fracture healing process and delays bone repair. Previously, growing evidence indicated that activation of the nod-like receptor (NLR) family, such as nod-like receptor thermal protein domain-associated protein 3 (NLRP3) inflammasome induces a vicious cycle of chronic low-grade inflammatory responses in diabetic fracture. Here, we describe the synthesis of a bone adhesive hydrogel that can be locally injected into the fracture site and releases a natural inhibitor of NLRP3 (rutin) in response to pathological cue reactive oxygen species activity (ROS). The hydrogel (denoted as RPO) was facilely formed by the cross-linking of rutin-functionalized gelatin, poly(vinyl alcohol), and oxidized starch based on the dynamic schiff base and boronate ester bond. Specifically, rutin is conjugated in the RPO hydrogel via a ROS linker and is released as the linker is cleaved by active ROS. In vitro studies demonstrate that RPO hydrogel effectively mitigates oxidative stress, alleviates mitochondrial dysfunction, and limits the overactivation of NLRP3 inflammasome in bone marrow derived macrophages, thereby promoting osteogenic differentiation of bone marrow mesenchymal stem cells. In a diabetic rat fracture model, RPO hydrogel significantly accelerates bone repair by modulating the inflammatory microenvironment. Our results demonstrate that local, on-demand NLRP3 inhibition for the treatment of diabetic fracture is achievable by using an injectable bioresponsive adhesive RPO hydrogel.

The role of quercetin in NLRP3-associated inflammation

Quercetin is a natural flavonoid that is widely found in fruits and vegetables. As an important flavonoid, it exhibits a wide range of biological activities, including antioxidant, anti-inflammatory, antiviral, immunomodulatory, and analgesic activities. Quercetin exerts powerful antioxidant activity by regulating glutathione, enzyme activity, and the production of reactive oxygen species (ROS). Quercetin exerts powerful anti-inflammatory effects by acting on the Nod-like receptor protein 3 (NLRP3) inflammasome. In diabetes, quercetin has been shown to improve insulin sensitivity and reduce high blood sugar level, while, in neurological diseases, it potentially prevents neuronal degeneration and cognitive decline by regulating neuroinflammation. In addition, in liver diseases, quercetin may improve liver inflammation and fibrosis by regulating the NLRP3 activity. In addition, quercetin may improve inflammation in other diseases based on the NLRP3 inflammasome. With this background, in this review, we have discussed the progress in the study on the mechanism of quercetin toward improving inflammation via NLRP3 inflammasome in the past decade. In addition, from the perspective of quercetin glycoside derivatives, the anti-inflammatory mechanism of hyperoside, rutin, and isoquercetin based on NLRP3 inflammasome has been discussed. Moreover, we have discussed the pharmacokinetics of quercetin and its nanoformulation application, with the aim to provide new ideas for further research on the anti-inflammatory effect of quercetin and its glycoside derivatives based on NLRP3 inflammasome, as well as in drug development and application.

Inhibition of lncEPS by TLR4/NF-κB pathway induces ventilator-induced lung injury by decreasing its binding to and upregulating Hspa5

Whether LincRNA erythroid prosurvival (LncEPS) reduces VILI remains unclear. A GSE200932 microarray was used to screen differentially expressed genes (DEGs). A VILI mouse model was constructed by mechanical ventilation (MV), with or without TAK242 or SN50 pretreatment. Airway transfection with adeno-associated virus (AAV) was used to overexpress lncEPS in alveolar macrophages (AMs). Lung tissues were collected to assess pathological injury and macrophage polarization. NLRP3 inflammasome, TLR4/NF-κB pathway activation and heat shock protein family A member 5 (Hspa5) in lung tissue and AMs wre evaluated. LncEPS localization and regulatory changes were assessed using in situ hybridization and RT-PCR. Lung tissues after lncEPS overexpression were subjected to transcriptomics. Chromatin isolation and mass spectrometry (MS) were performed to identify proteins interacting with lncEPS. GSE200932 microarray showed that the DEGs were related to NF-κB pathway, Toll-like receptor pathway and NOD-like receptor pathway. TAK242 or SN50 treatment increased polarization of M2 macrophages and decreased NLRP3 inflammasome activation by inhibiting TLR4/NF-κB pathway in VILI. Inhibition of TLR4/NF-κB pathway upregulated lncEPS expression in AMs. Overexpression of lncEPS increased polarization of M2 macrophages and decreased NLRP3 inflammasome activation, eventually alleviating VILI in mice. Mechanistically, lncEPS bound to Hspa5 and downregulated its expression to inhibit inflammatory response.

Discovery of Active Ingredient of Yinchenhao Decoction Targeting TLR4 for Hepatic Inflammatory Diseases Based on Deep Learning Approach

Yinchenhao Decoction (YCHD), a classic formula in traditional Chinese medicine, is believed to have the potential to treat liver diseases by modulating the Toll-like receptor 4 (TLR4) target. Therefore, a thorough exploration of the effective components and therapeutic mechanisms targeting TLR4 in YCHD is a promising strategy for liver diseases. In this study, the AIGO-DTI deep learning framework was proposed to predict the targeting probability of major components in YCHD for TLR4. Comparative evaluations with four machine learning models (RF, SVM, KNN, XGBoost) and two deep learning models (GCN, GAT) demonstrated that the AIGO-DTI framework exhibited the best overall performance, with Recall and AUC reaching 0.968 and 0.991, respectively.This study further utilized the AIGO-DTI model to identify the potential impact of Isoscopoletin, a major component of YCHD, on TLR4. Subsequent wet experiments revealed that Isoscopoletin could influence the maturation of Dendritic Cells (DCs) induced by Lipopolysaccharide (LPS) through TLR4, suggesting its therapeutic potential for liver diseases, especially hepatitis. Additionally, based on the AIGO-DTI framework, this study established an online platform named TLR4-Predict to facilitate domain experts in discovering more compounds related to TLR4. Overall, the proposed AIGO-DTI framework accurately predicts unique compounds in YCHD that interact with TLR4, providing new insights for identifying and screening lead compounds targeting TLR4.

The Profile of Phenolic Compounds Identified in Pitaya Fruits, Health Effects, and Food Applications: An Integrative Review

OBJECTIVE

This integrative review aimed to identify the phenolic compounds present in pitayas (dragon fruit).

METHODS

We employed a comprehensive search strategy, encompassing full-text articles published between 2013 and 2023 in Portuguese, English, and Spanish from databases indexed in ScienceDirect, Capes Periodics, Scielo, and PubMed. The study's selection was guided by the question, "What are the main phenolic compounds found in pitaya fruits?".

RESULTS

After screening 601 papers, 57 met the inclusion criteria. The identified phytochemicals have been associated with a range of health benefits, including antioxidant, anti-inflammatory, and anxiolytic properties. Additionally, they exhibit promising applications in the management of cancer, diabetes, and obesity. These 57 studies encompassed various genera, including Hylocereus, Selenicereus, and Stenocereus. Notably, Hylocereus undatus and Hylocereus polyrhizus emerged as the most extensively characterized species regarding polyphenol content. Analysis revealed that flavonoids, particularly kaempferol and rutin, were the predominant phenolic class within the pulp and peel of these fruits. Additionally, hydroxycinnamic and benzoic acid derivatives, especially chlorogenic acid, caffeic, protocatechuic, synaptic, and ellagic acid, were frequently reported. Furthermore, betalains, specifically betacyanins, were identified, contributing to the characteristic purplish-red color of the pitaya peel and pulp. These betalains hold significant potential as natural colorants in the food industry.

CONCLUSION

Therefore, the different pitayas have promising sources for the extraction of pigments for incorporation in the food industry. We recommend further studies investigate their potential as nutraceuticals.

Exploring the therapeutic potential of rutin through investigating its inhibitory mechanism on lactate dehydrogenase: Multi-spectral methods and computer simulation

Lactate dehydrogenase (LDH), a crucial enzyme in anaerobic glycolysis, plays a pivotal role in the energy metabolism of tumor cells, positioning it as a promising target for tumor treatment. Rutin, a plant-based flavonoid, offers benefits like antioxidant, antiapoptotic, and antineoplastic effects. This study employed diverse experiments to investigate the inhibitory mechanism of rutin on LDH through a binding perspective. The outcomes revealed that rutin underwent spontaneous binding within the coenzyme binding site of LDH, leading to the formation of a stable binary complex driven by hydrophobic forces, with hydrogen bonds also contributing significantly to sustaining the stability of the LDH-rutin complex. The binding constant (Ka) for the LDH-rutin system was 2.692 ± 0.015 × 104 M-1 at 298 K. Furthermore, rutin induced the alterations in the secondary structure conformation of LDH, characterized by a decrease in α-helix and an increase in antiparallel and parallel β-sheet, and β-turn. Rutin augmented the stability of coenzyme binding to LDH, which could potentially hinder the conversion process among coenzymes. Specifically, Arg98 in the active site loop of LDH provided essential binding energy contribution in the binding process. These outcomes might explain the dose-dependent inhibition of the catalytic activity of LDH by rutin. Interestingly, both the food additives ascorbic acid and tetrahydrocurcumin could reduce the binding stability of LDH and rutin. Meanwhile, these food additives did not produce positive synergism or antagonism on the rutin binding to LDH. Overall, this research could offer a unique insight into the therapeutic potential and medicinal worth of rutin.

Rutin targets AKT to inhibit ferroptosis in ventilator-induced lung injury

Our previous research confirmed that rutin reduced ventilator-induced lung injury (VILI) in mice. Ferroptosis has been reported to participate in the pathogenic process of VILI. We will explore whether rutin inhibits ferroptosis to alleviate VILI. A mouse model of VILI was constructed with or without rutin pretreatment to perform a multiomics analysis. Hematoxylin-eosin (HE) staining and transmission electron microscopy were used to evaluate lung injury in VILI mice. Dihydroethidium (DHE) staining and the malondialdehyde (MDA) and superoxide dismutase (SOD) levels were detected. Molecular docking was performed to determine the binding affinity between rutin and ferroptosis-related proteins. Western blot analysis, real-time PCR (RT-PCR) and immunohistochemical (IHC) staining were conducted to detect the expression levels of GPX4, XCT, ACSL4, FTH1, AKT and p-AKT in lung tissues. Microscale thermophoresis (MST) was used to evaluate the binding between rutin and AKT1. Transcriptomic and proteomic analyses showed that ferroptosis may play a key role in VILI mice. Metabolomic analysis demonstrated that rutin may affect ferroptosis via the AKT pathway. Molecular docking analysis indicated that rutin may regulate the expression of ferroptosis-related proteins. Moreover, rutin upregulated GPX4 expression and downregulated the expression of XCT, ACSL4 and FTH1 in the lung tissues. Rutin also increased the ratio of p-AKT/AKT and p-AKT expression. MST analysis showed that rutin binds to AKT1. Rutin binds to AKT to activate the AKT signaling pathway, contributing to inhibit ferroptosis, thus preventing VILI in mice. Our study elucidated a possible novel strategy of involving the use of rutin for preventing VILI.

Discovery of the Active Compounds of the Ethyl Acetate Extract Site of Ardisia japonica (Thunb.) Blume for the Treatment of Acute Lung Injury

The objective of this study was to identify and evaluate the pharmacodynamic constituents of Ardisiae Japonicae Herba (AJH) for the treatment of acute lung injury (ALI). To fully analyze the chemical contents of various extraction solvents (petroleum ether site (PE), ethyl acetate site (EA), n-butanol site (NB), and water site (WS)) of AJH, the UPLC-Orbitrap Fusion-MS technique was employed. Subsequently, the anti-inflammatory properties of the four extracted components of AJH were assessed using the lipopolysaccharide (LPS)-induced MH-S cellular inflammation model. The parts that exhibited anti-inflammatory activity were identified. Additionally, a technique was developed to measure the levels of specific chemical constituents in the anti-inflammatory components of AJH. The correlation between the "anti-inflammatory activity" and the constituents was analyzed, enabling the identification of a group of pharmacodynamic components with anti-inflammatory properties. ALI model rats were created using the tracheal drip LPS technique. The pharmacodynamic indices were evaluated for the anti-inflammatory active portions of AJH. The research revealed that the PE, EA, NB, and WS extracts of AJH included 215, 289, 128, and 69 unique chemical components, respectively. Additionally, 528 chemical components were discovered after removing duplicate values from the data. The EA exhibited significant anti-inflammatory activity in the cellular assay. A further analysis was conducted to determine the correlation between anti-inflammatory activity and components. Seventeen components, such as caryophyllene oxide, bergenin, and gallic acid, were identified as potential pharmacodynamic components with anti-inflammatory activity. The pharmacodynamic findings demonstrated that the intermediate and high doses of the EA extract from AJH exhibited a more pronounced effect in enhancing lung function, blood counts, and lung histology in a way that depended on the dosage. To summarize, when considering the findings from the previous study on the chemical properties of AJH, it was determined that the EA contained a group of 13 constituents that primarily contributed to its pharmacodynamic effects against ALI. The constituents include bergenin, quercetin, epigallocatechingallate, and others.