DSS-induced Colitis Model Research Articles

Gossypetin Alleviates DSS-induced Colitis by Regulating COX2 and ROS-JNK Signaling.

Inflammatory Bowel Disease (IBD) represents a chronic and recurrent inflammatory condition affecting the gastrointestinal tract, with a rising global incidence. Current treatment approaches include surgery and drugs. However, surgeries are invasive procedures, while drug treatments often present with various side effects. Gossypetin, a flavonoid found abundantly in plants such as hibiscus, exhibits anti-oxidant and anti-cancer properties. However, its potential impact on IBD remains unexplored. This study aimed to investigate the therapeutic potential of gossypetin on colitis. We employed the DSS-induced colitis model to evaluate the therapeutic potential of gossypetin on colitis. The efficacy of gossypetin was assessed within this model using the Disease Activity Index (DAI) score and histological analysis. Additionally, we utilized qRT-PCR to measure the levels of inflammatory cytokines and Superoxide Dismutase (SOD). Immunohistochemistry confirmed the expression of tight junction markers, COX-2, and phosphorylated JNK protein, normally associated with disease progression. Furthermore, Western blot analysis was conducted to examine the SOD levels and anti-apoptotic effects of gossypetin. In DSS-induced colitis mice, gossypetin treatment ameliorated weight loss and reduced colon length caused by DSS treatment. Additionally, gossypetin-treated groups exhibited DAI scores and reduced histological damage. Moreover, gossypetin treatment increased tight junction expression, decreased inflammatory responses, reduced ROS levels, attenuated JNK signaling, and decreased apoptosis. Gossypetin shows therapeutic potential for mitigating the symptoms and progression of colitis by targeting ROS-JNK signaling involved in inflammation and tissue damage. This highlights the potential of natural compounds such as gossypetin for targeted therapies with reduced side effects and improved efficacy.

Harnessing a Safe Novel Lipid Nanoparticle: Targeted Oral Delivery to Colonic Epithelial and Macrophage Cells in a Colitis Mouse Model.

A novel lipid nanoparticle (nLNP), formulated with three essential lipids to mimic ginger-derived exosomal particles, shows strong potential for delivering IL-22 mRNA specifically to the colon, presenting a unique oral drug delivery system for inflammatory bowel disease (IBD). However, its cellular targets and uptake behavior in healthy versus diseased colons remain unclear. Understanding these aspects is crucial for fully elucidating its targeting effectiveness in inflamed colon tissue. This study investigates the nLNP's cellular targets in healthy and diseased mouse colons. Flow cytometry compared nLNP uptake in healthy mice and a DSS-induced acute colitis model. The results revealed efficient internalization of nLNP by colonic epithelial cells in healthy and inflamed mice. In non-inflamed mice, the small number of colonic macrophages resulted in minimal uptake of nLNP by these cells. In inflamed mice, macrophages migrated to the damaged epithelium, where nLNP uptake was significantly increased, highlighting the nLNP's ability to target both epithelial and macrophage cells during inflammation. Additionally, safety assessments showed that the nLNP neither altered in vitro kinase activities nor exhibited immunotoxicity or induced in vivo toxicity at the maximum tolerated oral dose. These findings underscore the nLNP's safety and potential as a promising epithelial/macrophage-targeted drug delivery platform for oral ulcerative colitis (UC) treatment.

Discovery of Thiazole Carboxamides as Novel Vanin-1 Inhibitors for Inflammatory Bowel Disease Treatment.

Inflammatory bowel disease (IBD) is a clinically heterogeneous disease demanding more therapeutic targets and intervention strategies. Vanin-1, an oxidative stress-regulating protein, has emerged as a promising target for alleviating inflammation and oxidative stress. In this study, a series of thiazole carboxamide derivatives as vanin-1 inhibitors were designed and synthesized. The preferred compound, X17, demonstrated potent inhibition against vanin-1 at the protein, HT-29 cell, and tissue levels, whose binding mode with the target was confirmed via the cocrystal structure. X17 achieved a high bioavailability of 81% in rats, accompanied by concentration-dependent inhibition of serum vanin-1. In a DSS-induced mouse colitis model, X17 exhibited potent anti-inflammatory and antioxidant activities, repressing the inflammatory factor expressions and myeloperoxidase activity, elevating the colonic glutathione reserve, and restoring the intestinal barrier. Collectively, these findings depict the discovery of a potent vanin-1 inhibitor, providing an opportunity for further drug candidate development for treating IBD.

Benzoylmesaconine mitigates NLRP3 inflammasome-related diseases by reducing intracellular K+ efflux and disrupting NLRP3 inflammasome assembly

BackgroundBenzoylmesaconine (BMA), a major alkaloid derived from the traditional Chinese medicine Aconitum carmichaeli Debx, exhibits potent anti-inflammatory properties. However, the precise mechanism underlying its action remains unclear. PurposeThis study aimed to investigate the inhibitory mechanism of BMA on the NLRP3 inflammasome and assess its therapeutic efficacy in NLRP3-related metabolic diseases. MethodsA classic NLRP3 inflammasome-activated bone marrow-derived macrophage (BMDM) model was established to evaluate BMA's effects on NLRP3 upstream and downstream protein expression, as well as pyroptosis. Two distinct animal disease models, MSU-induced gouty arthritis and DSS-induced colitis, were utilized to validate BMA's anti-inflammatory activity in vivo. ResultsIn vitro findings revealed that BMA can suppress NLRP3 inflammasome activation by inhibiting interleukin-1β (IL-1β) secretion and GSDMD-N protein expression. This mechanism involved blocking intracellular K+ efflux and interfering with the formation of NLRP3 inflammasomes. In vivo studies demonstrated that BMA significantly alleviated inflammatory symptoms in MSU-induced acute gout and DSS-induced colitis models. ConclusionThese findings suggest that BMA effectively inhibits the activation of the NLRP3 signaling pathway through dual mechanisms: reducing intracellular K+ efflux and disrupting NLRP3 inflammasome assembly. This multifaceted action highlights the therapeutic potential of BMA for NLRP3-related diseases.

A derivative of tanshinone IIA and salviadione, 15a, inhibits inflammation and alleviates DSS-induced colitis in mice by direct binding and inhibition of RIPK2.

Inflammatory bowel diseases (IBDs) are chronic inflammatory conditions primarily affecting the gastrointestinal tract. Previous studies established the role of the NF-κB signaling pathway in the development of IBDs, suggesting that anti-inflammatory therapies might offer a viable treatment strategy. Tanshinone IIA and salviadione, both derived from Salviae Miltiorrhizae Radix et Rhizoma, possess anti-inflammatory and anti-oxidative activities. A series of new compounds were synthesized by hybridizing salviadione with tanshinone. Among these compounds, 15a showed beneficial effects in LPS-induced acute lung injury and diabetes-induced renal injury mouse models. The current study explored the therapeutic efficacy of 15a using both acute and chronic colitis models and elucidated the underlying mechanisms. DSS-induced colitis models were established in mice, where acute colitis was treated with compound 15a (5 or 10 mg·kg-1·d-1) for 8 days, while chronic colitis mice received compound 15a (5 or 10 mg·kg-1·d-1, i.g.) during 2.5% DSS administration. The 15a treatment significantly alleviated DSS-induced pathological and inflammatory damages in both acute and chronic colitis mouse models. In mouse intestinal epithelial cell line MODE-K, pretreatment with compound 15a (5 or 10 μM) significantly suppressed LPS + L18-MDP-induced inflammatory responses. The receptor-interacting serine/threonine kinase 2 (RIPK2) was identified as a direct binding target of compound 15a using microarrays and recombinant human proteins. Moreover, 15a could directly bind to and inhibit the phosphorylation of RIPK2, leading to the suppression of the NF-κB and MAPK signaling pathways. Furthermore, LEU153 and VAL32 were identified within the KD domain of RIPK2 as critical amino residues for the binding of 15a. Briefly, the current findings demonstrate that compound 15a holds promise as a therapeutic agent for managing acute and chronic colitis.

Lipopolysaccharide-regulated RNF31/NRF2 axis in colonic epithelial cells mediates homeostasis of the intestinal barrier in ulcerative colitis

BackgroundAlthough previous studies have shown that the Ring Finger Protein 31 (RNF31) gene confers susceptibility to inflammatory disease and colorectal cancer, the exact function of this protein in ulcerative colitis (UC) has not been determined. MethodsA mouse dextran sulfate sodium (DSS)-induced experimental colitis model was used to study RNF31 and NRF2 in colitis. RNF31 silencing or overexpression in vitro was applied to address the role of RNF31 in colonic mucosal barrier damage. Immunohistochemistry and silico analysis was performed to investigate the expression of RNF31 via taking advantage of UC tissue samples and Gene Expression Omnibus (GEO) data, respectively. The cycloheximide (CHX)-chase experiment and Co-Immunoprecipitation (Co-IP) assays were conducted to explore the association of RNF31 protein with NRF2 and P62. ResultsRNF31 is highly expressed in UC patients, in inflamed murine colon induced DSS and Lipopolysaccharide (LPS)-treated epithelial cells, while the express of NRF2 was Tabdecreased. RNF31-knockdown mice in the DSS-induced colitis model had a less severe phenotype, which was associated with a more integrated barrier of colon epithelial cells. While depletion of NRF2 in colitis model exacerbated intestinal inflammation. Mechanistically, RNF31 promoted the degradation of NRF2 by regulating its ubiquitination. Upon stimulation by RNF31, NRF2 is K63 ubiquitinated, which is associated with the C871 residue of RNF31. Moreover, downregulated NRF2 mediates inflammation by promoting the secretion of IL1β and IL18, leading to damage of the intestinal barrier. Upon LPS stimulation, the interaction of the PUB domain of RNF31 with the UBA domain of P62 increased, resulting in decreased degradation of the RNF31 protein via autophagy. ConclusionOverall, depletion of RNF31 effectively relieves DSS-induced colitis in mice by inhibiting NRF2 degradation, suggesting that RNF31 may be a potential therapy for human ulcerative colitis.

Mannose coated selenium nanoparticles normalize intestinal homeostasis in mice and mitigate colitis by inhibiting NF-κB activation and enhancing glutathione peroxidase expression

Impaired intestinal homeostasis is a major pathological feature of inflammatory bowel diseases (IBD). Mannose and selenium (Se) both demonstrate potential anti-inflammatory and anti-oxidative properties. However, most lectin receptors bind free monosaccharide ligands with relatively low affinity and most Se species induce side effects beyond a very narrow range of dosage. This has contributed to a poorly explored therapies for IBD that combine mannose and Se to target intestinal epithelial cells (IECs) for normalization gut homeostasis. Herein, a facile and safe strategy for ulcerative colitis (UC) treatment was developed using optimized, mannose-functionalized Se nanoparticles (M-SeNPs) encapsulated within a colon-targeted hydrogel delivery system containing alginate (SA) and chitosan (CS). This biocompatible nanosystem was efficiently taken up by IECs and led to increased expression of Se-dependent glutathione peroxidases (GPXs), thereby modulating IECs’ immune response. Using a mouse model of DSS-induced colitis, (CS/SA)-embedding M-SeNPs (C/S-MSe) were found to mitigate oxidative stress and inflammation through the inhibition of the NF-kB pathway in the colon. This stabilized mucosal homeostasis of IECs and ameliorated colitis-related symptoms, thereby providing a potential new approach for treatment of IBD.

Synthesis and Anti-Inflammatory Bowel Disease Activity of Pterostilbene Derivatives.

The aberrant activation of NLRP3 inflammasomes is intricately linked to various inflammatory diseases. In this study, we present the discovery and optimization of a series of NLRP3 inflammasome inhibitors based on the pterostilbene skeleton. All compounds underwent screening to evaluate their inhibitory effects on LPS/Nigericin-induced IL-1β secretion and anti-cellular pyroptosis. Most compounds exhibit good biological activity and cellular safety, with compound D20 showing the most prominent activity. Preliminary mechanism studies suggest that compound D20 may affect the assembly of NLRP3 inflammasomes by targeting the NLRP3 protein, thereby inhibiting the activation of NLRP3 inflammasomes. The in vivo anti-inflammatory activity demonstrated significant therapeutic effect of compound D20 on DSS-induced acute colitis model in mice. This work has important reference significance for the development of drugs targeting NLRP3 inflammasomes.

Optimization of a gelatin/carboxymethylcellulose-based probiotic microcapsule and its application in preventing dextran sodium sulfate-induced colitis in mice.

Oral administration of probiotics has demonstrated substantial potential in alleviating colitis. However, most of the ingested microorganisms struggle to survive the harsh conditions of the gastrointestinal tract, leading to decreased efficacy. In the present study, using double emulsification (W1/O/W2) and complex coacervation methods, we developed a gelatin/carboxymethyl cellulose (CMC)-based probiotic microcapsule and analyzed the efficacy of encapsulated probiotics in preventing dextran sodium sulfate (DSS)-induced colitis in mice. Our results reveal that nearly 90% of the encapsulated probiotics remained viable after 30-day storage at 4°C and approximately 38.1% of viable bacteria (4.0 × 108 cfu/g) survived after 4-h simulated gastrointestinal digestion. In a DSS-induced colitis model, pretreatment with probiotics exerted significant protective effects, with the bacterial microcapsule-treated group having superior outcomes to those of the bacterial suspension plus empty carrier group. Probiotic treatments, especially those administered in the encapsulated form, significantly increased fecal short-chain fatty acid contents, and altered the intestinal microbial composition. The family Muribaculaceae, dominant bacteria in the mouse gut, may be the key microorganism involved in the BM regulation process. Our study presents an alternative approach to treating colitis using probiotics. PRACTICAL APPLICATION: The encapsuled probiotic showed remarkable storage stability at 4°C, maintained good vitality after simulated digestion, and gained superior outcomes in preventing colitis. Our results offer an alternative approach for the probiotic preparations aiming to prevent the intestinal inflammation.

Weizmannia coagulans spores alleviates DSS-induced ulcerative colitis model by modulation of gut flora, metabolites and suppressing TLR4/MyD88/NF-κB pathway

<em>Weizmannia coagulans</em> spores alleviates DSS-induced ulcerative colitis model by modulation of gut flora, metabolites and suppressing TLR4/MyD88/NF-κB pathway

Neuroprotective effects of whey and buttermilk-based formulas on a DSS-induced colitis murine model.

Inflammatory bowel disease is a gut-brain axis disorder that comprises chronic inflammatory conditions affecting the gastrointestinal tract, where alterations in the mood of patients are common. Gut-brain axis is a bidirectional communication that link gut and brain. The close association between inflammatory bowel disease and neuroinflammation has far-reaching implications, as is increasingly recognized as a contributing factor to neuropsychiatric and neurodegenerative diseases. The increasing prevalence and high economic cost, together with the loss of life quality of people suffering from these diseases, point to the need to find alternatives to alleviate them. Exploring new therapeutic avenues prompts us to consider the potential benefits of milk fractions, taking advantage of the use of dairy by-products, such as whey and buttermilk. This study examines the impact of cow's whey- and buttermilk-based formulas supplemented with bovine lactoferrin and milk fat globule membrane on the expression of cytokines, as well as on the components of immune and serotonergic system of the brain in a murine model of dextran sodium sulfate-induced colitis. Our results show the potential of these dairy by-products, especially whey, as functional foods in ameliorating neuroinflammation and safeguarding the central nervous system function amid the neurological complications induced or concomitant with intestinal inflammatory processes.

Design, Synthesis, and Bioevaluation of Novel NLRP3 Inhibitor with IBD Immunotherapy from the Virtual Screen.

NLRP3, a crucial member of the NLRP family, plays a pivotal role in immune regulation and inflammatory modulation. Here, we report a potent and specific NLRP3 inhibitor Z48 obtained though docking-based virtual screening and structure-activity relationship studies with an IC50 of 0.26 μM in THP-1 cells and 0.21 μM in mouse bone marrow-derived macrophages. Mechanistic studies indicated that Z48 could bind directly to the NLRP3 protein (KD = 1.05 μM), effectively blocking the assembly and activation of the NLRP3 inflammasome, consequently manifesting anti-inflammatory properties. Crucially, with acceptable mouse pharmacokinetic profiles, Z48 demonstrated notable therapeutic efficacy in a mouse model of DSS-induced ulcerative colitis, while displaying no significant therapeutic impact on NLRP3KO mice. In conclusion, this study provided a promising NLRP3 inflammasome inhibitor with novel molecular scaffold, poised for further development as a therapeutic candidate in the treatment of inflammatory bowel disease.

NPSR1 promotes chronic colitis through regulating CD4+ T cell effector function in inflammatory bowel disease

BackgroundNeuropeptide S receptor 1 (NPSR1) has been implicated in the the onset of inflammatory bowel disease (IBD), though its exact mechanism remains unclear. This study investigates the role of NPSR1 in regulating CD4+ T cell effector function in IBD. MethodsPeripheral blood and colonic mucosal biopsies from IBD patients, as well as dextran sodium sulfate (DSS)-induced mouse colitis models, were analyzed to assess the effects of NPSR1 on colitis and CD4+ T cell-mediated immune responses. NPSR1 knockdown was conducted both in vitro and in vivo to elucidate underlying mechanisms. Expression of NPSR1 and CD4+ T cell-related factors was measured using quantitative real-time PCR, immunoblotting, cytometric bead array, immunofluorescence, and immunohistochemistry. CD4 + T cell effector functions were evaluated through flow cytometry, EdU incorporation assay, Annexin V-FITC/PI staining, and transwell assay. ResultsNPSR1 expression was elevated in the intestinal tissues from IBD patients. Its downregulation provided protection in DSS-induced mouse colitis models. NPSR1 correlated positively with CD4 + T cell-mediated inflammation, and its knockdown reduced CD4+ T cell-mediated immune responses and inhibited CD4+ T cell differentiation. Additionally, NPSR1 knockdown decreased CD4+ T cell proliferation, increased apoptosis, and enhanced CCL2-induced migration in vitro, while significantly reducing Th1 cell chemotaxis in vivo. ConclusionsThis study demonstrates that NPSR1 promotes chronic colitis by regulating CD4 + T cell effector functions in IBD, offering potential new therapeutic strategies for IBD treatment.

Dual-layer probiotic encapsulation using metal phenolic network with gellan gum-tamarind gum coating for colitis treatment

Probiotic oral therapy has been recognised as an effective treatment for inflammatory bowel disease (IBD). However, the efficacy of probiotics is often diminished due to their limited resistance to harsh gastrointestinal conditions. Therefore, the importance of designing innovative strategies for oral probiotic delivery for the effective treatment of IBD is increasingly recognised. In this study, we present a novel encapsulation strategy of Lactobacillus plantarum (L.P) using the dual-layer system consisting of a tannic acid‑calcium network and polysaccharide coating (gellan gum-tamarind gum) named L.P-C/T-G/T. This double-layer encapsulation system not only does not affect the normal proliferation of probiotics and provide protection, but also endows probiotics with more functions. More specifically, the acid resistance ability of the encapsulated probiotics is increased by 10 times, the free radical scavenging rate is enhanced by 5 times, and the intestinal retention time can be prolonged by 6–12 h. In the DSS-induced murine colitis model, it significantly alleviated colon shortening, inhibited ROS overexpression, and promoted the repair and regeneration of the mucus layer. This dual-layer encapsulation approach for a single probiotic demonstrates a significant advancement in probiotic delivery technology, offering hope for a comprehensive approach to the treatment of colitis and potentially other gastrointestinal disorders.

Orally biomimetic metal-phenolic nanozyme with quadruple safeguards for intestinal homeostasis to ameliorate ulcerative colitis

BackgroundUlcerative colitis (UC) is defined by persistent inflammatory processes within the gastrointestinal tract of uncertain etiology. Current therapeutic approaches are limited in their ability to address oxidative stress, inflammation, barrier function restoration, and modulation of gut microbiota in a coordinated manner to maintain intestinal homeostasis.ResultsThis study involves the construction of a metal-phenolic nanozyme (Cur-Fe) through a ferric ion-mediated oxidative coupling of curcumin. Cur-Fe nanozyme exhibits superoxide dismutase (SOD)-like and •OH scavenging activities, demonstrating significant anti-inflammatory and anti-oxidant properties for maintaining intracellular redox balance in vitro. Drawing inspiration from Escherichia coli Nissle 1917 (EcN), a biomimetic Cur-Fe nanozyme (CF@EM) is subsequently developed by integrating Cur-Fe into the EcN membrane (EM) to improve the in vivo targeting ability and therapeutic effectiveness of the Cur-Fe nanozyme. When orally administered, CF@EM demonstrates a strong ability to colonize the inflamed colon and restore intestinal redox balance and barrier function in DSS-induced colitis models. Importantly, CF@EM influences the gut microbiome towards a beneficial state by enhancing bacterial diversity and shifting the compositional structure toward an anti-inflammatory phenotype. Furthermore, analysis of intestinal microbial metabolites supports the notion that the therapeutic efficacy of CF@EM is closely associated with bile acid metabolism.ConclusionInspired by gut microbes, we have successfully synthesized a biomimetic Cur-Fe nanozyme with the ability to inhibit inflammation and restore intestinal homeostasis. Collectively, without appreciable systemic toxicity, this work provides an unprecedented opportunity for targeted oral nanomedicine in the treatment of ulcerative colitis.

Protopanaxadiol derivative: A plant origin of novel selective glucocorticoid receptor modulator with anti-inflammatory effect

Constant efforts have been made to move towards maintaining the positive anti-inflammatory functions of glucocorticoids (GCs) while minimizing side effects. The anti-inflammatory effect of GCs is mainly attributed to the inhibition of major inflammatory pathways such as NF-κB through GR transrepression, while its side effects are mainly mediated by transactivation. Here, we investigated the selective glucocorticoid receptor modulator (SGRM)-like properties of a plant-derived compound. In this study, glucocorticoid receptor (GR)-mediated alleviation of inflammation by SP-8 was investigated by a combination of in vitro, in silico, and in vivo approaches. Molecular docking and cellular thermal shift assay suggested that SP-8 bound stably to the active site of GR via hydrogen bonding and hydrophobic interactions. SP-8 activated GR, induced GR nuclear translocation, and inhibited NF-κB pathway activation. Furthermore, SP-8 did not up-regulate the gene and protein expression of PEPCK and TAT in HepG2 cells, and it did not induce fat deposition like GC and has little effect on bone metabolism. Interestingly, SP-8 upregulated GR protein expression and did not cause GR phosphorylation at Ser211 in RAW264.7 cells. This work proved that SP-8 dissociated characteristics of transrepression and transactivation can be separated. In addition, the in vitro and in vivo anti-inflammatory effects of SP-8 were confirmed in LPS-induced RAW 264.7 cells and in a mouse model of DSS-induced ulcerative colitis, respectively. In conclusion, SP-8 might serve as a potential SGRM and might hold great potential for therapeutic use in inflammatory diseases.

Optimal development of apoptotic cells-mimicking liposomes targeting macrophages

Macrophages are multifunctional innate immune cells that play indispensable roles in homeostasis, tissue repair, and immune regulation. However, dysregulated activation of macrophages is implicated in the pathogenesis of various human disorders, making them a potential target for treatment. Through the expression of pattern recognition and scavenger receptors, macrophages exhibit selective uptake of pathogens and apoptotic cells. Consequently, the utilization of drug carriers that mimic pathogenic or apoptotic signals shows potential for targeted delivery to macrophages. In this study, a series of mannosylated or/and phosphatidylserine (PS) -presenting liposomes were developed to target macrophages via the design of experiment (DoE) strategy and the trial-and-error (TaE) approach. The optimal molar ratio for the liposome formulation was DOPC: DSPS: Chol: PEG-PE = 20:60:20:2 based on the results of cellular uptake and cytotoxicity evaluation on RAW 264.7 and THP-1 in vitro. Results from in vivo distribution showed that, in the DSS-induced colitis model and collagen II-induced rheumatoid arthritis model, PS-presenting liposomes (PS-Lipo) showed the highest accumulation in intestine and paws respectively, which holds promising potential for macrophage target therapy since macrophages are abundant at inflammatory sites and contribute to the progression of corresponding diseases. Organs such as the heart, liver, spleen, lung, and kidney did not exhibit histological alterations such as inflammation or necrosis when exposed to PC-presenting liposomes (PC-Lipo) or PS-Lipo. In addition, liposomes demonstrated hemobiocompatibility and no toxicity to liver or kidney for circulation and did not induce metabolic injury in the animals. Thus, the well-designed PS-Lipo demonstrated the most potential for macrophage target therapy.

Paeonol alleviates ulcerative colitis by modulating PPAR-γ and nuclear factor-κB activation

Ulcerative colitis (UC) is a chronic idiopathic inflammatory disease affecting the gastrointestinal tract. Although paeonol has been used for treating UC due to its anti-inflammatory and antioxidant effects, the underlying mechanisms remain unclear. In this study, we investigated the mechanisms of paeonol’s action on UC by conducting in-vitro and in-vivo studies using NCM460 cells and RAW264.7 cells, and the DSS-induced mice colitis model. The in vitro studies demonstrate that paeonol exerts inhibitory effects on the activation of the NF-κB signaling pathway through upregulating PPARγ expression, thereby attenuating pro-inflammatory cytokine production, reducing reactive oxygen species levels, and promoting M2 macrophage polarization. These effects are significantly abrogated upon addition of the PPARγ inhibitor GW9662. Moreover, UC mice treated with paeonol showed increased PPARγ expression, which reduced inflammation and apoptosis to maintain intestinal epithelial barrier integrity. In conclusion, our findings suggest that paeonol inhibits the NF-κB signaling pathway by activating PPARγ, reducing inflammation and oxidative stress and improving Dss-induced colitis. This study provides a new insight into the mechanism of treating UC by paeonol.

Abstract Tu022: Gut-derived bacterial metabolites promote cardiac inflammation, leading to heart failure in murine model of DSS-induced colitis

Background: Inflammatory Bowel Disease (IBD) affects millions of people all over the world. This has been known to contribute to several other comorbidities. Recently, impaired gut-barrier permeability has been known to contribute to cardiovascular diseases in IBD patients. However, the precise mechanisms remain unclear. In this study, we propose that bacterial metabolites, like peptidoglycan, may play a role in promoting cardiac inflammation and ultimately leading to heart failure in mice following colitis. Methods: We induced colitis in C57 black mice with DSS (dextran sodium sulfate) treatment. Further, we collected fecal sample for 16s rRNA analysis to evaluate microbial flora. Additionally, heart and intestine tissues were collected to determine inflammatory genes expression (qPCR), immune cell infiltration (FACS), and intestinal permeability (WB and immunohistochemistry). Blood was collected to quantify the circulating peptidoglycan (PGN) level. The effect of PGN on NFkB inflammatory pathways was evaluated in macrophages. Results: Echo-data showed cardiac dysfunction in DSS mice. Masson’s trichrome staining showed deteriorated intestinal villi, while western blot data indicated decreased Occludin and increased PV-1 level, suggesting a leaky gut in DSS treated mice. Comparative analysis of 16s rRNA sequencing data showed significantly altered Firmicutes/Bacteroidetes ratio in DSS treated mice as compared to control mice. Moreover, plasma PGN level was significantly increased 3 weeks following DSS treatment. Real-time gene expression data of pro-inflammatory cytokines (TNFα) and fibrosis associated genes (col1α1, fibronectin) were increased in DSS mice heart. Increased CD68 expression in the immunostaining data of DSS mice heart suggests the recruitment of inflammatory macrophages. At the molecular level, CDK9 expression was significantly increased in macrophage following PGN treatment, which ultimately leads to an increase in NFkB signaling. Finally, CDK9 inhibition attenuated PGN-induced NFkB signaling. Conclusion: Together, our study suggests that colitis-induced gut leakage leads to CDK9-mediated NFκB upregulation, contributing to cardiac inflammation. Ongoing research will shed light on the underlying molecular mechanisms of cardiovascular dysfunction.

Protective properties of Ophiopogonin D in DSS-induced colitis: insights into microbiota modulation.

Ulcerative colitis (UC), a chronic inflammatory gastrointestinal disorder, is becoming increasingly prevalent worldwide. Ophiopogonin D, which is derived from Ophiopogon japonicus, exhibits anti-inflammatory and antioxidant properties, yet its therapeutic potential in UC remains unclear. In this study, we employed a mouse model of DSS-induced colitis to assess the impact of Ophiopogonin D on various parameters, including weight loss, bloody stools, and inflammation in the colon. Ophiopogonin-D treatment significantly mitigated these DSS-induced effects, improved colon permeability, and modulated inflammatory markers like ZO-1, MUC-2, TNF-α, and IL-1β in mice compared with the control. Furthermore, compared to the DSS-treatment group, Ophiopogonin-D treatment improved the α- and β-diversity indices of the mouse intestinal microbiota, along with an increase in the abundance of genera such as Akkermansia (AKK) and a decrease in the abundance of genera such as Enterobacter. Notably, propionic acid, a metabolite of AKK, demonstrated significant improvement in the symptoms of DSS-induced colitis in mice compared to the control. Moreover, propionic-acid administration also resulted in alterations in the levels of inflammatory factors and calreticulin within the intestinal tissues. Overall, Ophiopogonin D significantly affects intestinal microbiota composition, thereby improving symptoms of DSS-induced colitis in mice. These findings present promising therapeutic strategies and potential pharmaceutical candidates for the treatment of ulcerative colitis.