Verteporfin Exerts Anticancer Effects and Reverses Resistance to Paclitaxel via Inducing Ferroptosis in Esophageal Squamous Cell Cancer Cells

Down-regulation of YAP prevents smoking- and alcohol-induced carcinogenesis of esophageal paracancerous tissue by promoting cellular pyroptosis

Paracancerous tissues (PCTs) were previously considered benign regions, but recent findings reveal genomic instability in these areas. Smoking and alcohol consumption are closely associated with esophageal cancer (EC) development. This study explored the interplay between the Hippo pathway and pyroptosis in EC, PCTs, and distal normal tissues (DNTs). We used molecular epidemiological methods to analyze the effects of smoking and alcohol on these pathways. We found that key genes in both pathways were more altered in smokers and/or drinkers compared to non-smokers and non-drinkers. Additionally, we observed changes in some genes and proteins in PCTs, while the Hippo pathway and pyroptosis had not yet been influenced. We applied 4.0% alcohol combined with various concentrations of cigarette smoke extract (CSE) to PCTs cultured in vitro to observe carcinogenesis and changes in these pathways. Verteporfin, as an inhibitor of YAP, was also used in vitro culture experiments to observe its effects on cellular carcinogenesis. Among 56 EC patients, 41 had a history of smoking and/or alcohol consumption in this study. Compared to DNTs, Hippo pathway genes (Lats1, Yap, and Taz) and pyroptosis genes (Nlrp3, Asc, Gsdmd, and Caspase-1) were altered in 49 EC tissues, while changes of Lats1, Nlrp3, and Asc were observed in 47 PCTs. Additionally, 4.0% alcohol combined with 3.2%, 4.0%, and 5.8% CSE, respectively, not only induced cellular heterogeneity and even cancerous transformation, but also suppressed the Hippo pathway and pyroptosis in the PCTs cultured in vitro. Furthermore, in vitro, 9 μM verteporfin inhibited cellular heterogeneity/carcinogenesis in PCTs induced by 4.0% alcohol combined with 5.8% CSE through inhibiting YAP and promoting pyroptosis. It is speculated that the downregulation of YAP could prevent smoking- and alcohol-induced carcinogenesis in esophageal PCTs by promoting pyroptosis, which may offer new insights for the treatment of esophageal squamous carcinoma.

Snail family transcriptional repressor 1 radiosensitizes esophageal cancer via epithelial-mesenchymal transition signaling: From bioinformatics to integrated study

BACKGROUND

Esophageal cancer (ESCA) poses a significant challenge in oncology because of the limited treatment options and poor prognosis. Therefore, enhancing the therapeutic effects of radiotherapy for ESCA and identifying relevant therapeutic targets are crucial for improving both the survival rate and quality of life of patients.

AIM

To define the role of the transcription factor Snail family transcriptional repressor 1 (SNAI1) in ESCA, particularly its regulation of radiosensitivity.

METHODS

A comprehensive analysis of TCGA data assessed SNAI1 expression in ESCA. Survival curves correlated SNAI1 levels with radiotherapy outcomes. Colony formation assays, flow cytometry, and a xenograft model were used to evaluate tumor radiosensitivity and apoptosis. Western blot validated protein expression, while Chromatin immunoprecipitation assays examined SNAI1's role in regulating epithelial-mesenchymal transition (EMT).

RESULTS

SNAI1 expression in ESCA cell lines and clinical specimens emphasizes its central role in this disease. Elevated SNAI1 expression is correlated with unfavorable outcomes in radiotherapy. Downregulation of SNAI1 enhances the sensitivity of ESCA cells to ionizing radiation (IR), resulting in remarkable tumor regression upon IR treatment in vivo. This study underscores the direct involvement of SNAI1 in the regulation of EMT, particularly under IR-induced conditions. Furthermore, inhibiting deacetylation effectively suppresses EMT, suggesting a potential avenue to enhance the response to radiotherapy in ESCA.

CONCLUSION

This study highlights SNAI1's role in ESCA radiosensitivity, offering prognostic insights and therapeutic strategies to enhance radiotherapy by targeting SNAI1 and modulating EMT processes.

Deciphering Ferroptosis: From Molecular Pathways to Machine Learning-Guided Therapeutic Innovation

Ferroptosis is a unique form of cell death reliant on iron and lipid peroxidation. It disrupts redox balance, causing cell death by damaging the plasma membrane, with inducers acting through enzymatic pathways or transport systems. In cancer treatment, suppressing ferroptosis or circumventing it holds significant promise. Beyond cancer, ferroptosis affects aging, organs, metabolism, and nervous system. Understanding ferroptosis mechanisms holds promise for uncovering novel therapeutic strategies across a spectrum of diseases. However, detection and regulation of this regulated cell death are still mired with challenges. The dearth of cell, tissue, or organ-specific biomarkers muted the pharmacological use of ferroptosis. This review covers recent studies on ferroptosis, detailing its properties, key genes, metabolic pathways, and regulatory networks, emphasizing the interaction between cellular signaling and ferroptotic cell death. It also summarizes recent findings on ferroptosis inducers, inhibitors, and regulators, highlighting their potential therapeutic applications across diseases. The review addresses challenges in utilizing ferroptosis therapeutically and explores the use of machine learning to uncover complex patterns in ferroptosis-related data, aiding in the discovery of biomarkers, predictive models, and therapeutic targets. Finally, it discusses emerging research areas and the importance of continued investigation to harness the full therapeutic potential of targeting ferroptosis.

A review on ferroptosis and photodynamic therapy synergism: Enhancing anticancer treatment

Ferroptosis is an iron-dependent programmed cell death modality, which has showed great potential in anticancer treatment. Photodynamic therapy (PDT) is widely used in clinic as an anticancer therapy. PDT combined with ferroptosis-promoting therapy has been found to be a promising strategy to improve anti-cancer therapy efficacy. Fenton reaction in ferroptosis can provide oxygen for PDT, and PDT can produce reactive oxygen species for Fenton reaction to enhance ferroptosis. In this review, we briefly present the importance of ferroptosis in anticancer treatment, mechanism of ferroptosis, researches on PDT induced ferroptosis, and the mechanism of the synergistic effect of PDT and ferroptosis on cancer killing.

Influence of Different Ratios of DSPE-PEG2k on Ester Prodrug Self-Assembly Nanoparticles for Cell Migration and Proliferation Suppression

Background

Bufalin (BFL, an active anti-tumor compound derived from toad venom) is limited in its application due to high toxicity and rapid metabolism of the cardiotonic steroid. Ester prodrug self-assembly nanoparticles have shown significant improved effects in addressing the above-mentioned issues.

Methods

An ester bond was formed between linoleic acid and bufalin to synthesize linoleic acid-bufalin prodrug (LeB). The self-assembly nanoparticles (LeB-PSNs) containing different mass ratios of DSPE-PEG2k and prodrug (6:4, 7:3, 8:2, 9:1 and 10:0) were prepared via co-precipitation method and defined as 6:4-PSNs, 7:3-PSNs, 8:2-PSNs, 9:1-PSNs and LeB-PSNs, respectively. Further, the characterization (particle size, zeta potential, surface morphology and stability) of the nanoparticles was carried out. Finally, we evaluated the impact of different ratios of DSPE-PEG2k on the hydrolysis rate, cytotoxicity, cellular uptake, cell migration and proliferation suppression potential of the prodrug nanoparticles.

Results

The linoleic acid-bufalin prodrug (LeB) was successfully synthesized. Upon the addition of DSPE-PEG2k at different weight ratios, both particle size and polydispersity index (PDI) significantly decreased, while the zeta potential increased remarkably. No significant differences in particle size, PDI and Zeta potential were observed among the 9:1, 8:2 and 7:3 PSNs. Notably, the 8:2 (w/w) DSPE-PEG2k nanoparticles exhibited superior stability, hydrolysis and cellular uptake rates, along with efficient cell cytotoxicity, cell migration and proliferation suppression.

Conclusion

These findings indicate that DSPE-PEG2k could improve the performance of BFL prodrug nanoparticles, namely enhancing stability and achieving adaptive drug release by modulating the hydrolysis rate of esterase. This study therefore provides more opportunities for the development of BFL application.