Yuwei Yao

Histone lactylation has been reported to involve in tumorigenesis and development. However, its biological regulatory mechanism in endometrial carcinoma (EC) is yet to be reported in detail. In the present study, we evaluated the modification levels of global lactylation in EC tissues by immunohistochemistry and western blot, and it was elevated. The non-metabolizable glucose analog 2-deoxy-d-glucose (2-DG) and oxamate treatment could decrease the level of lactylation so as to inhibit the proliferation and migration ability, induce apoptosis significantly, and arrest the cell cycle of EC cells. Mechanically, histone lactylation stimulated USP39 expression to promote tumor progression. Moreover, USP39 activated PI3K/AKT/HIF-1α signaling pathway via interacting with and stabilizing PGK1 to stimulate glycolysis. The results of present study suggest that histone lactylation plays an important role in the progression of EC by promoting the malignant biological behavior of EC cells, thus providing insights into potential therapeutic strategies for endometrial cancer.

BACKGROUND: Metabolic reprogramming is one of hallmarks of cancer progression and is of great importance for the tumor microenvironment (TME). As an abundant metabolite, lactate has been found to play a critical role in cancer development and immunosuppression of TME. However, the potential role of lactate metabolism-related genes in endometrial cancer (EC) remains obscure. METHODS: RNA sequencing data and clinical information of EC were obtained from The Cancer Genome Atlas (TCGA) database. Lactate metabolism-related genes (LMRGs) WERE from Molecular Signature Database v7.4 and then compared the candidate genes from TCGA to obtain final genes. Univariate analysis and Least Absolute Shrinkage and Selection Operator (LASSO) Cox regression were performed to screen prognostic genes. A lactate metabolism-related risk profile was constructed using multivariate Cox regression analysis. The signature was validated by time-dependent ROC curve analysis and Kaplan-Meier analysis. The relationship between the risk score and age, grade, stage, tumor microenvironmental characteristics, and drug sensitivity was as well explored by correlation analyses. Gene ontology (GO) enrichment analysis and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway functional analysis between the high and low-risk groups were performed. CCK8, EdU, and clone formation assays were applied to detect the proliferation ability of EC cells, Transwell assay was performed to detect the migration ability of EC cells, and intracellular lactate and glucose content was used to asses lactate metabolism. RESULTS: We constructed a risk signature based on 18 LMRGs. Kaplan-Meier curves confirmed that the high-risk group had poorer prognosis compared to the low-risk group. A nomogram was then constructed to predict the probability of EC survival. We also performed GO enrichment analysis and KEGG pathway functional analysis between the high and low-risk groups, and the outcome revealed that the features were significantly associated with energy metabolism. There was a significant correspondence between LMRGs and tumor mutational load, checkpoints and immune cell infiltration. C1, C2, and C4 were the most infiltrated in the high-risk group. The high-risk group showed increased dendritic cell activation, while the low-risk group showed increased plasma cells and Treg cells. Drug sensitivity analysis showed LMRGs risk was more resistant to Scr kinase inhibitors. We further proved that one of the lactate metabolism related genes, TIMM50 could promote EC cell proliferation, migration and lactate metabolism. CONCLUSION: In conclusion, we have established an effective prognostic signature based on LMRG expression patterns, which may greatly facilitate the assessment of prognosis, molecular features and treatment modalities in EC patients and may be useful in the future translation to clinical applications. TIMM50 was identified as a novel molecule that mediates lactate metabolism in vitro and in vivo, maybe a promising target for EC prognosis.

BACKGROUND: Ovarian cancer (OC) has the highest fatality rate among all gynecological malignancies, necessitating the exploration of novel, efficient, and low-toxicity therapeutic strategies. Ferroptosis is a type of programmed cell death induced by iron-dependent lipid peroxidation and can potentially activate antitumor immunity. Developing highly effective ferroptosis inducers may improve OC prognosis. RESULTS: (BMO) and MXene reduced the bandgap width by 0.44 eV, increased the carrier-separation efficiency, and decreased the recombination rate of electron-hole pairs under ultrasound stimulation. Therefore, the reactive oxygen species yield was enhanced. Under spatiotemporal ultrasound excitation, BMO-MXene effectively inhibited OC proliferation by more than 90%, induced lipid peroxidation, decreased mitochondrial-membrane potential, and inactivated the glutathione peroxidase and cystathionine transporter protein system, thereby causing ferroptosis in tumor cells. Ferroptosis in OC cells further activated immunogenic cell death, facilitating dendritic cell maturation and stimulating antitumor immunity. CONCLUSION: We have succeeded in developing a highly potent ferroptosis inducer (BMO-MXene), capable of inhibiting OC progression through the sonodynamic-ferroptosis-immunogenic cell death pathway.

BACKGROUND: The efficacy of current therapies for ovarian cancer is limited due to the multilevel and complex tumor microenvironment (TME), which induces drug resistance and tumor progression in a single treatment regimen. Additionally, poor targeting and insufficient tissue penetration are important constraints in ovarian cancer treatment. RESULT: We constructed PH20-overexpressing cancer-associated fibroblast (CAF)-cancer hybrid-cell membrane vesicles (PH20/CCM) for the dual-targeted delivery of carboplatin (CBP) and siRNA targeting p65 (sip65) loaded on the poly (dimethyl diallyl ammonium chloride) (PDDA)-modified MXene (PMXene), named PMXene@CBP-sip65 (PMCS). The nanoparticle PH20/CCM@PMCS could penetrate the extracellular matrix of tumor tissues and target both cancer cells and CAFs. After tumor cell internalization, these nanoparticles significantly inhibited cancer cell proliferation, generated reactive oxygen species, induced endoplasmic reticulum stress, and triggered immunogenic cell death. After CAF internalization, they inhibited pro-tumor factor release and activated immune effects, promoting immune system infiltration. In an experiment with ID8 homograft-carrying mice, PH20/CCM@PMCS significantly improved tumor inhibition and enhanced immune infiltration in tumor tissues. CONCLUSION: These new therapeutic nanoparticles can simultaneously target tumor cells, CAFs, immune cells, and the extracellular matrix, thereby increasing treatment sensitivity and improving the TME. Therefore, these TME-regulating nanoparticles, combining specificity, efficiency, and effectiveness, provide new insights into ovarian cancer treatment.

Radiation therapy (RT) remains the primary treatment modality for advanced cervical cancer, however, recurrence due to radioresistance presents a significant challenge. Cancer-associated fibroblasts (CAFs) within the tumor microenvironment (TME) are key contributors to this resistance, driven by their inherent radioresistance and radiation-induced phenotypic adaptations. Addressing this issue requires strategies specifically designed to target CAFs and enhance their radiosensitivity. In this study, we developed a biomimetic metal–organic framework (MOF) nanoplatform for the dual-targeted co-delivery of the FAK inhibitor IN10018 and Bismuth (Bi), aimed at improving radiosensitivity in cervical cancer. The IN10018 and Bi-loaded zeolitic imidazolate framework 8 (ZIF-8) nanoparticles (IZB) were further coated with hybrid membranes derived from CAFs and cancer cells, enabling precise targeting of both cell types. Upon exposure to an acidic environment, the nanoparticles disassemble, releasing IN10018, which reduces CAFs infiltration and enhances radiosensitivity. Simultaneously, the incorporation of Bi enhances radiation absorption efficiency, further sensitizing tumor cells to radiotherapy. This dual-target strategy represents a promising approach to overcoming radioresistance in cervical cancer and exemplifies how integrating nanotechnology with targeted therapies can enhance RT efficacy and improve patient outcomes. Schematic Illustration of IZB@CCM Construction and Application for Cervical Cancer to Improve Radiosensitivity. (1) IZB was fabricated through the one-pot method. (2) Preparation of hybrid CAF-cancer cell membrane. (3) IZB@CCM were obtained by co-extrusion of IZB and hybrid membrane (CCM). (4) IZB@CCM demonstrated the ability to target CAFs and cancer cells. (5) IZB@CCM inhibited the expression of FAK and released radiosensitizer Bi to enhance the radiosensitivity of cervical cancer.