STA9090 as a Potential Therapeutic Agent for Liver Fibrosis by Modulating the HSP90/TßRII/Proteasome Interplay: Novel Insights from In Vitro and In Vivo Investigations.

Liver fibrosis is a progressive condition characterized by the build-up of fibrous tissue resulting from long-term liver injury. Although there have been advancements in research and treatment, there is still a need for effective antifibrotic medication. HSP90 plays a crucial role in the development of fibrosis. It acts as a molecular chaperone that assists in the proper folding and stability of TßRII, potentially regulating the signaling of TGF-ß1. It has been established that TßRII can be degraded through the proteasome degradation system, either via ubiquitination-dependent or -independent pathways. In the present study, STA9090 demonstrated promising effects in both in vitro and in vivo models. It reduced LDH leakage, prolonged the survival rate of hepatocytes in rats with liver fibrosis, and improved liver function. Importantly, STA9090 exerted pleiotropic effects by targeting proteins involved in limiting collagen production, which resulted in improved microscopic features of the rat livers. Our findings suggest that STA9090-induced inhibition of HSP90 leads to the degradation of TßRII, a fibrogenic client protein of HSP90, through the activation of the 20S proteasomal degradation system. We also revealed that this degradation mechanism is not dependent on the autophagy-lysosomal pathway. Additionally, STA9090 was found to destabilize HIF-1α and facilitate its degradation, leading to the reduced transcription of VEGF. Moreover, STA9090's ability to deactivate the NFκB signaling pathway highlights its potential as an anti-inflammatory and antifibrotic agent. However, further research is necessary to fully elucidate the underlying mechanisms and fully capitalize on the therapeutic benefits of targeting HSP90 and associated pathways.

Alvespimycin Exhibits Potential Anti-TGF-ß Signaling in the Setting of a Proteasome Activator in Rats with Bleomycin-Induced Pulmonary Fibrosis: A Promising Novel Approach.

Idiopathic pulmonary fibrosis (IPF) is an irreversible and life-threatening lung disease of unknown etiology presenting only a few treatment options. TGF-ß signaling orchestrates a cascade of events driving pulmonary fibrosis (PF). Notably, recent research has affirmed the augmentation of TGF-ß receptor (TßR) signaling via HSP90 activation. HSP90, a molecular chaperone, adeptly stabilizes and folds TßRs, thus intricately regulating TGF-ß1 signaling. Our investigation illuminated the impact of alvespimycin, an HSP90 inhibitor, on TGF-ß-mediated transcriptional responses by inducing destabilization of TßRs. This outcome stems from the explicit interaction of TßR subtypes I and II with HSP90, where they are clients of this cellular chaperone. It is worth noting that regulation of proteasome-dependent degradation of TßRs is a critical standpoint in the termination of TGF-ß signal transduction. Oleuropein, the principal bioactive compound found in Olea europaea, is acknowledged for its role as a proteasome activator. In this study, our aim was to explore the efficacy of a combined therapy involving oleuropein and alvespimycin for the treatment of PF. We employed a PF rat model that was induced by intratracheal bleomycin infusion. The application of this dual therapy yielded a noteworthy impediment to the undesired activation of TGF-ß/mothers against decapentaplegic homologs 2 and 3 (SMAD2/3) signaling. Consequently, this novel combination showcased improvements in both lung tissue structure and function while also effectively restraining key fibrosis markers such as PDGF-BB, TIMP-1, ACTA2, col1a1, and hydroxyproline. On a mechanistic level, our findings unveiled that the antifibrotic impact of this combination therapy likely stemmed from the enhanced degradation of both TßRI and TßRII. In conclusion, the utilization of proteasomal activators in conjunction with HSP90 inhibitors ushers in a promising frontier for the management of PF.

(R,R)-BD-AcAc2 Mitigates Chronic Colitis in Rats: A Promising Multi-Pronged Approach Modulating Inflammasome Activity, Autophagy, and Pyroptosis.

Ulcerative colitis is a chronic and incurable form of inflammatory bowel disease that can increase the risk of colitis-associated cancer and mortality. Limited treatment options are available for this condition, and the existing ones often come with non-tolerable adverse effects. This study is the first to examine the potential benefits of consuming (R,R)-BD-AcAc2, a type of ketone ester (KE), and intermittent fasting in treating chronic colitis induced by dextran sodium sulfate (DSS) in rats. We selected both protocols to enhance the levels of ß-hydroxybutyrate, mimicking a state of nutritional ketosis and early ketosis, respectively. Our findings revealed that only the former protocol, consuming the KE, improved disease activity and the macroscopic and microscopic features of the colon while reducing inflammation scores. Additionally, the KE counteracted the DSS-induced decrease in the percentage of weight change, reduced the colonic weight-to-length ratio, and increased the survival rate of DSS-insulted rats. KE also showed potential antioxidant activities and improved the gut microbiome composition. Moreover, consuming KE increased the levels of tight junction proteins that protect against leaky gut and exhibited anti-inflammatory properties by reducing proinflammatory cytokine production. These effects were attributed to inhibiting NFκB and NLRP3 inflammasome activation and restraining pyroptosis and apoptosis while enhancing autophagy as revealed by reduced p62 and increased BECN1. Furthermore, the KE may have a positive impact on maintaining a healthy microbiome. To conclude, the potential clinical implications of our findings are promising, as (R,R)-BD-AcAc2 has a greater safety profile and can be easily translated to human subjects.

Chronic exposure to tramadol induces cardiac inflammation and endothelial dysfunction in mice.

Tramadol is an opioid extensively used to treat moderate to severe pain; however, prolonged therapy is associated with several tissues damage. Chronic use of tramadol was linked to increased hospitalizations due to cardiovascular complications. Limited literature has described the effects of tramadol on the cardiovascular system, so we sought to investigate these actions and elucidate the underlying mechanisms. Mice received tramadol hydrochloride (40 mg/kg body weight) orally for 4 successive weeks. Oxidative stress, inflammation, and cardiac toxicity were assessed. In addition, eNOS expression was evaluated. Our results demonstrated marked histopathological alteration in heart and aortic tissues after exposure to tramadol. Tramadol upregulated the expression of oxidative stress and inflammatory markers in mice heart and aorta, whereas downregulated eNOS expression. Tramadol caused cardiac damage shown by the increase in LDH, Troponin I, and CK-MB activities in serum samples. Overall, these results highlight the risks of tramadol on the cardiovascular system.

Inhibition of endoplasmic reticulum stress ameliorates cardiovascular injury in a rat model of metabolic syndrome.

Metabolic (Met) syndrome is characterized by hypertension, insulin resistance and dyslipidaemia with high risk of cardiovascular disease. Endoplasmic reticulum (ER) stress is a key contributor in the pathogenesis of Met syndrome. The current study investigates the effect of Tauroursodeoxycholate (TUDCA), an ER stress inhibitor, on Met syndrome-induced cardiovascular complications and the possible underlying signalling mechanisms. Met syndrome was induced in rats, which were then treated with TUDCA. Body weight, blood pressure, glucose tolerance and insulin tolerance tests were performed. ER stress, survival and oxidative stress markers were measured in heart and aorta tissue. The results showed that TUDCA improved metabolic parameters in rats with Met syndrome. Treatment mitigated the Met syndrome-induced cardiovascular complications through upregulating survival markers and downregulating ER and oxidative stress markers. These results highlight the protective effect of ER stress inhibition as a potential target in the management of cardiovascular complications associated with Met syndrome.

Nicotine-induced oxidative stress alters sciatic nerve barriers in rat through modulation of ZO-1 & VEGF expression.

This study aimed to evaluate the histopathological and ultrastructural changes in sciatic nerve barriers after exposure to different doses of nicotine. Twenty-seven adult male rats were divided into 2 groups; group I served as control (n = 9) and group II that received nicotine (n = 18) was subdivided into two equal subgroups; group IIa and group IIb that were injected subcutaneously daily for one month with nicotine at a dose of 3 mg/kg and 6 mg/kg body weight, respectively. Specimens of sciatic nerve were processed for light and electron microscopy. Immunohistochemical expression of ZO-1 and vascular endothelium growth factor (VEGF) were investigated. Abundance of mRNA for VEGF was determined via qRT-PCR. Total antioxidant capacity (TAC), malondialdehyde (MDA), alanine transaminase (ALT) and aspartate transaminase (AST) were measured. Group IIb showed increased perineural fibrosis and myelin abnormalities. ZO-1 expression was significantly decreased. Schwann cells showed features of apoptosis and blood capillaries showed disrupted lining. High statistical difference in the level of mRNA expression of VEGF between group IIb and group I was found. There was decreased level of TAC and increased MDA, ALT and AST. A dose-dependent nicotine-induced oxidative stress on the sciatic nerve occurred via disruption of nerve barriers, altered VEGF and ZO-1 levels.