Ubiquitination of ADRα1d/SerpinA1 complex stimulates hypoxia to induce gastric tumorigenesis with a combination of Helicobacter pylori and chronic stress through IL-1α

The heterogeneous roles of neutrophils in gastric cancer: scaffold or target?

Gastric cancer (GC) is a significant challenge for global health. Neutrophils, the predominant white blood cells in the innate immune system, are increasingly becoming known as potential contributors to either tumor-promoting or tumor-suppressive activities within different tumor biology settings. This review highlights such dual roles of neutrophils in GC, where complex interactions occur within the tumor microenvironment. Specifically, we focus on the formation and function of neutrophil extracellular traps (NETs), which have emerged as critical players in GC progression. NETs influence key processes such as inflammation, angiogenesis, and metastasis. This review offers a comprehensive analysis of the polarization of neutrophils into two of its distinct subtypes, namely N1 and N2, which exert opposing influences on tumor biology. While N1 neutrophils exert anti-tumor properties, N2 neutrophils are generally regarded as pro-tumor. We uniquely discuss how these subtypes interact with cancer cells, affecting epithelial-mesenchymal transition and immune evasion mechanisms. These interactions change the tumor microenvironment and impact overall GC progression. In addition, we underscore the potential of neutrophils and their associated molecules as biomarkers and therapeutic targets. Specific neutrophil-derived markers and neutrophil-associated signaling pathways, along with their perspectives in personalized medicine that would pave the way for neutrophil-based anti-GC therapy, have been discussed in this review. Through the integration of these perspectives, we aim to guide future research involving neutrophils and their therapeutic implications, thus establishing strategies to precisely and effectively treat GC and improve prognosis.

Long-Term Dietary Consumption of Grapes Alters Phenotypic Expression in Skeletal Muscle of Aged Male and Female Mice

(1) Background: Nutrigenomics investigates how diet influences gene expression and how genetic variation impacts dietary responses. Grapes, rich in phytochemicals, exhibit potential disease-preventive properties through nutrigenomic mechanisms rather than direct chemical interactions. This study aimed to explore the modulation of gene expression in muscle tissue resulting from long-term grape consumption. (2) Methods: A mouse model was employed to assess gene expression in the skeletal muscles of males and females fed a grape-enriched diet versus a bland diet over 2.5 years. Heatmaps and principal component analyses were performed to identify patterns, and pathway analyses using KEGG, GO, and Reactome were conducted. (3) Results: Significant sex-specific gene expression changes were observed, with female phenotypes showing greater alterations and converging toward male-like characteristics. Twenty-five differentially expressed genes associated with muscle health were identified. Up-regulated genes such as Ahsg, Alb, Apoa1, and Arg1, and down-regulated genes including Camp, Lcn2, and Irf4, suggest improved muscle function. (4) Conclusions: Long-term grape consumption appears to enhance female muscle traits toward a male-like phenotype, potentially indicating broader health benefits. Further studies and clinical trials are needed to confirm human applicability and the physiological implications of these findings. Nonetheless, this research underscores the role of nutrigenomics in understanding dietary influences on gene expression and sex-specific responses.

Investigating the crosstalk between chronic stress and immune cells: implications for enhanced cancer therapy

Chronic stress has a substantial influence on the tumor microenvironment (TME), leading to compromised effectiveness of anti-cancer therapies through diverse mechanisms. It disrupts vital functions of immune cells that play a critical role in anti-tumor immunity, such as the inhibition of dendritic cells (DCs) and lymphocytes, while simultaneously enhancing the activity of immune cells that support tumor growth, such as myeloid-derived suppressor cells and tumor-associated macrophages. Furthermore, chronic stress exerts a significant impact on crucial mechanisms within the TME, including angiogenesis, DNA repair, hypoxia, extracellular matrix deposition, and tumor metabolism. These alterations in the TME, induced by stress, result from the activation of the hypothalamic-pituitary-adrenal axis and sympathetic nervous system, in conjunction with epigenetic modifications. In conclusion, chronic stress significantly influences the TME and impedes the efficacy of anti-cancer treatments, underscoring the importance of targeting stress pathways to improve therapeutic results.