Search Results (12,071)

Background/Objectives: Colorectal neuroendocrine carcinomas (NECs) are rare, aggressive tumors with poorly defined clinicopathologic and molecular features. Their biological behavior and optimal treatment strategies remain unclear. Additionally, a subset of anorectal NECs may be associated with high-risk human papillomavirus (HPV) infection, suggesting potential heterogeneity in pathogenesis. Methods: We retrospectively reviewed 12 cases of colorectal NECs. Clinical outcomes, histologic morphology, immunohistochemistry, molecular profiling, including common oncogenic mutations, and HPV status were analyzed. Results: Seven cases demonstrated small cell NECs, and five showed large cell NECs. The majority of NECs (n = 9) arose in the rectum. TP53 mutations were the most common (75%), followed by KRAS, RB1, FBXW7, and BRAF mutations. One case demonstrated mismatch repair (MMR) deficiency. High-risk HPV was detected in one rectal NEC, which lacked common oncogenic mutations and was the only long-term survivor (54 months). p16 expression did not correlate consistently with HPV in situ hybridization (ISH) status. Among small cell NECs with follow-up, platinum-based chemotherapy resulted in significantly longer survival than FOLFOX (13.5 vs. 4 months, p = 0.0209). Conclusions: Colorectal NECs display histologic and molecular heterogeneity. The tumors of small cell NECs potentially benefit more from platinum-based chemotherapy. HPV-associated NECs may represent a distinct subset with better prognosis, but p16 is not a reliable surrogate marker. Routine subclassification into small vs. large cell types and comprehensive molecular profiling, including HPV testing, may aid clinical decision-making and prognostication. Full article

The rise in the number of cancer cases and the dissemination of strains with multiple drug resistance in the world pose a serious threat to public health care and human well-being. The design and study of new chemotherapeutic agents for cancer and infectious diseases are hot topics in science. Hydrazones, a versatile and diverse class of chemical compounds, gained a lot of attention as a promising base for future drugs. In this paper, we report on the synthesis of eight new gold(III) complexes with hydrazones derived from pyridoxal-5′-phosphate and pyridoxal. The complexes are thoroughly characterized using IR, ¹H, ³¹P NMR, and mass spectroscopy. The cytotoxic effect of twelve various hydrazones derived from pyridoxal 5′-phosphate on both immortalized (HEK293T) and tumor (HCT116) human cell lines was estimated using the MTT assay. In addition, this contribution describes the antibacterial action of complexes of gold(III) and pyridoxal and pyridoxal 5′-phosphate-derived hydrazones, as well as the mixtures of the solutions containing tetrachloroaurate(III) and hydrazones, using the zone of inhibition test. Gold(III) complexes exhibit moderate antibacterial activity against both Gram-positive and Gram-negative bacteria, while free hydrazones show low cytotoxicity and thus could be considered relatively safe for humans. Full article

The design of innovative compounds displaying anti-inflammatory activity in oncological context is a subject of great interest in drug development. It has been proved that a pro-inflammatory microenvironment which accelerates cancer growth and cellular differentiation is often present in malignant bladder tumor. In earlier work, we reported the synthesis of p-aminobenzoic acid derivatives that act as anti-inflammatory compounds able to inhibit the pro-inflammatory markers present in bladder cancer microenvironment. DAB-1 rapidly emerged as an effective lead candidate in this investigation, with its ability to shrink by 90% in 25 days the size of human bladder cancer tumors in an ectopic mouse model. This manuscript discloses the synthesis of 23 new hydrazide derivatives of DAB-1 and reports their in vitro and in vivo biological evaluation. It was discovered that most of the new compounds are essentially nontoxic against RAW 264.7 cells, as evaluated by an MTT assay. Anti-inflammatory activity of the new derivatives was investigated by evaluation of their impact on cellular nitric oxide production, measured by a Griess assay. Some compounds did significatively inhibit nitric oxide production much more effectively than the original DAB-1. Striking activity of 14, which is around four times more potent than DAB-1, promotes this derivative as new lead compound in this study. The study of these analogs reveals that a phenolic/anisole core is a key component to achieve high biological activity. Furthermore, mice models of acute inflammation and invasive BCa tumors were used to assess the in vivo impact of derivative 14, and it was found that this compound does reduce inflammation in these mice, possess similar anti-inflammatory activity but higher anti-tumoral activity compared to DAB-1 with no apparent signs of toxicity. Full article

Background: Most immunologically “cold” tumors do not respond durably to checkpoint blockade because tumor antigen (TA) release and presentation are insufficient to prime effective T-cell immunity. While prior work demonstrated synergy between cisplatin and a TLR7/8/9 agonist (CR108) in 4T1 tumors, the underlying mechanism—particularly whether chemotherapy functions as a broad antigen-releasing agent enabling TLR-driven immune amplification—remained undefined. Methods: Using murine models of breast (4T1), melanoma (B16-F10), and colorectal cancer (CT26), we tested multiple chemotherapeutic classes combined with CR108. We quantified intratumoral and systemic soluble TAs, antigen presentation and cross-priming by antigen-presenting cells, tumor-infiltrating lymphocytes, and cytokine production by flow cytometry/ICS. T-cell receptor β (TCRβ) repertoire dynamics in tumor-draining lymph nodes were profiled to assess amplitude and breadth. Tumor microenvironment remodeling was analyzed, and public datasets (e.g., TCGA basal-like breast cancer) were interrogated for expression of genes linked to TA generation/processing and peptide loading. Results: Using cisplatin + CR108 in 4T1 as a benchmark, we demonstrate that diverse chemotherapies—especially platinum agents—broadly increase the repertoire of soluble tumor antigens available for immune recognition. Across regimens, chemotherapy combined with CR108 increased T-cell recognition of candidate TAs and enhanced IFN-γ⁺ CD8⁺ responses, with platinum agents producing the largest expansions in soluble TAs. TCRβ sequencing revealed increased clonal amplitude without loss of repertoire breadth, indicating focused yet diverse antitumor T-cell expansion. Notably, therapeutic efficacy was not predicted by canonical damage-associated molecular pattern (DAMP) signatures but instead correlated with antigen availability and processing capacity. In human basal-like breast cancer, higher expression of genes involved in TA generation and antigen processing/presentation correlated with improved survival. Conclusions: Our findings establish an antigen-centric mechanism underlying chemo–TLR agonist synergy: chemotherapy liberates a broadened repertoire of tumor antigens, which CR108 then leverages via innate immune activation to drive potent, T-cell-mediated antitumor immunity. This framework for rational selection of chemotherapy partners for TLR7/8/9 agonism and support clinical evaluation to convert “cold” tumors into immunologically responsive disease. Full article

Renal cell carcinoma (RCC) is the most common form of kidney cancer in adults. Immunotherapy, such as the application of interleukin-2 (IL-2), is a crucial treatment. It is known that IL-2 is involved in the upregulation of the anti-tumor immune response; however, a direct action of IL-2 on RCC cells has not yet been demonstrated. In this project, we aimed to investigate the expression and the functionality of the IL-2Rα, IL-2Rβ, and IL-2Rγ subunits on the four human RCC cell lines A-498, ACHN, Caki-1, and Caki-2. The expression of the three subunit genes was investigated via PCR, agarose gel of PCR products, Western blot, and flow cytometry. IL-2R functionality was assessed in RCC cells cultured with or without rhIL-2 using MTT and BrdU assays to investigate cell viability and proliferation; LDH assays, Live-or-Dye staining, and Annexin V/PI staining to study cell death; and Western blot to detect apoptotic markers, cleaved PARP, and cleaved caspases 3 and 9. Expression of IL-2Rα, IL-2Rβ, and IL-2Rγ subunits in the four cell lines was observed at the protein level with Western blot. Flow cytometry confirmed the cell-surface expression of IL-2Rα, IL-2Rβ, and IL-2Rγ subunits. In addition, we observed that rhIL-2 influenced cell survival/proliferation and cell death, depending on the cell line. We conclude that IL-2R is functional in RCC cells and that rhIL-2 could be used as a therapeutic option to act directly on RCC cells. However, further studies are required to elucidate the signaling pathways triggered by the IL-2-receptor binding on RCC cells. Full article

Diketopiperazines (DKPs) are biologically important cyclic dipeptides widespread in nature, associated primarily with microorganisms. This is the case for the 2,5-DKP derivative cyclo(L-Leu-L-Pro) (cLP), also known as gancidin W or PPDHMP, identified from a variety of bacteria and fungi, and occasionally found in food products. The present review retraces the discovery of cLP, its identification in living species, its chemical syntheses, and its biochemical properties. In bacteria, cLP is often associated with other DKPs to serve as a defense element against other microorganisms and/or as a regulator of bacterial growth. cLP plays a role in quorum-sensing and functions as an anticariogenic and antifungal agent. The antimicrobial mechanism of action and molecular targets of cLP are evoked. The interest in cLP for combatting certain parasitic diseases, such as malaria, and cancers is discussed. The capacity of cLP to interact with CD151 and to down-regulate the expression of this tetraspanin can be exploited to reduce tumor dissemination and metastases. The review sheds light on the pharmacology and specific properties of cyclo(L-Leu-L-Pro), which can be useful for the development of a novel therapeutic approach for different human pathologies. It is also of interest to help define the bioactivity and mechanisms of action of closely related DKP-based natural products. Full article

Very-high-energy electron (VHEE) beams, ranging from 50 to 300 or 400 MeV, are the subject of intense research investigation, with considerable interest concerning applications in radiation therapy due to their accurate energy deposition into large and deep-seated tissues, sharp beam edges, high sparing properties, and minimal radiation effects on normal tissues. The very-high-energy electron beam, which ranges from 50 to 400 MeV, and Ultra-High-Energy Electron beams up to 1–2 GeV, are considered extremely effective for human tumor therapy while avoiding the spatial requirements and cost of proton and heavy ion facilities. Many research laboratories have developed advanced testing infrastructures with VHEE beams in Europe, the USA, Japan, and other countries. These facilities aim to accelerate the transition to clinical application, following extensive simulations for beam transport that support preclinical trials and imminent clinical deployment. However, the clinical implementation of VHEE for FLASH radiation therapy requires advances in several areas, including the development of compact, stable, and efficient accelerators; the definition of sophisticated treatment plans; and the establishment of clinically validated protocols. In addition, the perspective of VHEE for accessing ultra-high dose rate (UHDR) dosimetry presents a promising procedure for the practical integration of FLASH radiotherapy for deep tumors, enhancing normal tissue sparing while maintaining the inherent dosimetry advantages. However, it has been proven that a strong effort is necessary to improve the main operational accelerator conditions, ensuring a stable beam over time and across space, as well as compact infrastructure to support the clinical implementation of VHEE for FLASH cancer treatment. VHEE-accessing ultra-high dose rate (UHDR) perspective dosimetry is integrated with FLASH radiotherapy and well-prepared cancer treatment tools that provide an advantage in modern oncology regimes. This study explores technological progress and the evolution of electron accelerator beam energy technology, as simulated by the ASTRA code, for developing VHEE and UHEE beams aimed at medical applications. FLUKA code simulations of electron beam provide dose distribution plots and the range for various energies inside the phantom of PMMA. Full article

The tumor microenvironment (TME) comprises neoplastic and stromal cells, and extracellular matrix elements, all engaging in a complex interplay that ultimately dictates tumorigenesis, cancer progression, and therapeutic response. While extensive research on the TME has been conducted in human oncology, data on its veterinary counterpart, particularly in feline mammary tumors (FMTs), are still scarce. In this review, we explore current understanding of feline mammary carcinoma (FMC) microenvironment, focusing on tumor necrosis, fibrosis, angiogenesis, adipose tissue tumor-associated inflammation, extracellular vesicles, and epithelial–mesenchymal transition (EMT) and their prognostic implications. In FMC, remodeling of collagen fibers, cancer-associated fibroblasts (CAFs), regulatory T cells (Tregs) and elevated serum leptin have been associated with poor prognosis, whereas stromal cytotoxic T cells correlate with more favorable outcomes. By contrast, findings on necrosis and pro-angiogenic factors remain inconsistent, and research on extracellular vesicles (EVs) is still in its early stages. This review presents insights from human breast cancer (HBC) that further support and elucidate the potential relevance of these TME components. As FMCs are highly aggressive tumors, a deeper understanding of their microenvironment could not only improve prognostic accuracy but also uncover novel therapeutic targets. Furthermore, due to their similarities, FMCs offer a potential valuable spontaneous model for HBC, particularly for the aggressive triple-negative phenotypes. Full article

Lacking effective therapeutics, cholangiocarcinoma (CCA) remains a deadly malignancy of the biliary tract. The Hippo pathway effector protein Yes-associated protein (YAP) is implicated in CCA pathogenesis and chemotherapeutic resistance; however, the oncogenic mechanisms underlying YAP regulation remain incompletely understood. An enhanced understanding of YAP and its role in CCA may uncover novel therapeutic targets and better define resistance pathways. Human CCA cells and murine syngeneic CCA models were utilized to explore the molecular relationship of YAP and protein tyrosine phosphatase 1B (PTP1B). Previous work in CCA has demonstrated that YAP interacts with multiple protein tyrosine phosphatases, including SHP2 and PTP1B. We observed that PTP1B pharmacologic inhibition was associated with increased cell proliferation and YAP target gene expression, while genetically enforced overexpression of PTP1B was associated with a decrease in YAP activation. Treatment of CCA cells in vitro and syngeneic, orthotopically implanted CCA murine tumors in vivo with standard cytotoxic chemotherapy, gemcitabine/cisplatin, had enhanced efficacy in the setting of PTP1B overexpression. These findings demonstrate that pYAP^Y357 can be modulated through protein tyrosine 1B phosphatase activity, and reducing pYAP^Y357 through enhanced phosphatase levels can sensitize CCA to chemotherapy. Full article

Colorectal cancer (CRC) remains a leading global health challenge, and natural products are increasingly explored for their multi-targeted therapeutic potential. Litchi chinensis seed extract (LCSE) has shown promising anti-cancer activity in vitro, though its in vivo effects remain underexplored. LCSE was analyzed by colorimetric assays and HPLC to quantify the phytochemical composition. Nude mice bearing HT-29 or SW480 xenografts were orally administered LCSE (0.1 or 0.6 g/kg) daily for 14 days. Tumor volume was measured, and immunohistochemistry was used to assess EGFR, p21, p53, Ki-67, CEA, CK20, CDX2, and Bax expression. Phytochemical profiling demonstrated LCSE contains abundant phenolics and flavonoids, with gallic acid as a predominant constituent, underscoring the potential bioactive properties. LCSE significantly inhibited tumor growth in HT-29 xenografts and dose-dependently reduced EGFR, p21, p53, cell cycle proteins and proliferation/differentiation markers. In SW480 tumors, inhibitory effects were evident primarily at the higher dose, with limited reduction in p53 expression. Bax levels remained unchanged in both models, indicating a non-apoptotic mechanism. No systemic toxicity was observed in treated mice. LCSE exhibits dose-dependent anti-tumor activity in CRC xenografts, likely mediated through suppression of proliferation and modulation of key regulatory proteins rather than apoptosis. These findings support LCSE as a safe, multi-target botanical candidate for CRC intervention and justify further mechanistic and translational studies. Full article

Post-translational modifications (PTMs) of proteins in eukaryotic cells are essential for regulating proteome function and maintaining cellular homeostasis. Among these, the methylation modification of arginine has received much attention in recent years. The enzymatic process of arginine methylation is catalyzed by a family of approximately nine known protein arginine methyltransferases (PRMTs) in humans, which utilize S-adenosylmethionine (SAM) as the methyl group donor. PRMTs are involved in biological processes such as gene transcription, signal transduction, and DNA damage repair. Their role in normal cellular functions and pathological disease states is becoming increasingly clear with the advancement of research. This paper provides a review of the numerous roles of members of the PRMT family in normal cellular function and disease pathophysiology, with a focus on their association with the tumor immune microenvironment (TIME), and discusses their broad impact on various physiological processes and pathological conditions. Full article

Uveal melanoma is a melanocyte-derived malignancy of the eye with a high propensity for liver metastasis. Metastatic uveal melanoma is associated with high mortality and is poorly responsive to currently available therapies. Most uveal melanoma cases are driven by activating mutations in GNAQ and GNA11 genes, which convey oncogenic signaling through the mitogen-activated protein kinase (MAPK) pathway. Despite promising early results, safe doses of pharmacological inhibitors of the MAPK cascade failed to effectively control uveal melanoma in human trials. Considering the role of the RAC/PAK signaling axis as a co-regulator of the MAPK cascade, we set forth to investigate whether the efficacy of MAPK cascade inhibitors in pre-clinical models may be enhanced by direct inhibition of RAC and PAK proteins, or by indirect control of RAC via inhibition of guanylate biosynthesis. We observed that pharmacological inhibition of RAC, PAK and the key guanylate biosynthesis enzyme IMPDH significantly synergized with various inhibitors of the MAPK cascade in suppressing oncogenic signaling and the growth of uveal melanoma cells. In a mouse model, the addition of an IMPDH inhibitor to the treatment regimen significantly enhanced the ability of a MAPK cascade inhibitor to improve the survival of tumor-bearing animals. Targeting of the RAC/PAK axis provides a new strategy to increase the efficacy of targeted therapies in uveal melanoma. While RAC and PAK inhibitors are still undergoing pre-clinical development, clinically available inhibitors of IMPDH offer an opportunity to test the efficacy of this novel synergistic combination in the context of human disease. Full article

Eosinophils are innate immune cells that infiltrate tissues in response to cell proliferation and necrosis, which occurs during normal injury repair, parasitic infections, allergies, and cancer. Their involvement in cancer is controversial particularly with regard to tumor-associated tissue eosinophilia (TATE) and a recently defined mechanism of extracellular trap cell death (ETosis), a particular type of eosinophil cell death that is distinct from both apoptosis and necrosis. This narrative review synthesizes the literature regarding the prognostic significance of TATE, focusing on eosinophil ETosis and the important role of transmission electron microscopy (TEM) in its detection and morphological characterization. The prognostic role of TATE is contradictory: in certain tumors, it is a favorable prognostic marker, while in others, it is unfavorable. However, recent research reveals that TATE is associated with a better prognosis in non-viral neoplasms, but it may correlate with a poor prognosis in virus-related neoplasms, such as human T-lymphotropic virus type 1 (HTLV-1)-associated lymphomas and HPV-positive carcinomas. Our ultrastructural investigations revealed distinct phases of eosinophil ETosis in gastric cancer, which were defined by chromatin decondensation, plasma membrane disruption, granule discharge, and development of extracellular traps. We observed synapse-like interactions between eosinophils, exhibiting ETosis or compound exocytosis, and tumor cells, which showed various degrees of cellular damage, ultimately leading to colloid-osmotic tumor cell death. TEM provides important insights into eosinophil-mediated cytotoxicity, requiring further investigation as potential immune effector mechanisms in non-viral tumors. TATE evaluation, together with the viral status of the neoplasia, may be useful to confirm its prognostic significance and consequently its therapeutic implication in specific cancers. Full article

Background: Cancer remains a leading cause of morbidity and mortality worldwide, and current therapies are limited by toxicity, cost, and resistance. Inhibition of the MDM2–p53 interaction is a promising anticancer strategy, as this pathway is frequently dysregulated across tumors. Spiro-isatin-thiazolidinone derivatives have shown diverse biological activities, including anticancer effects, but require optimization to improve potency and selectivity. The aims were to design, synthesize, and evaluate novel spiro-isatin-thiazolidinone hybrids with enhanced cytotoxicity against cancer cells and reduced toxicity toward normal cells. Methods: Derivatives were designed using molecular docking against MDM2, followed by structural optimization. Cytotoxic activity was evaluated in vitro by MTT assays on human and murine cancer cell lines and pseudo-normal cells. Docking and 100 ns molecular dynamics simulations assessed binding stability, while ADMET properties were predicted in silico. Results: Several derivatives exhibited micromolar cytotoxicity, with compound 18 emerging as the most potent and selective candidate (IC₅₀ 6.67–8.37 µM across most cancer lines; >100 µM in HaCaT). Docking showed a strong affinity for MDM2 (−10.16 kcal/mol), comparable to the reference ligand, and stable interactions in simulations. ADMET predictions confirmed good oral bioavailability and moderate acute toxicity, fully compliant with Lipinski’s Rule of Five. Overall, the newly synthesized spiro-isatin-thiazolidinone hybrids, particularly compound 18, demonstrated potent and selective anticancer activity, favorable pharmacokinetic properties and a good toxicity profile. Full article

Breast cancer remains a leading cause of global mortality. According to international cancer data, significant progress has been made in treating breast cancer; however, metastasis and drug resistance continue to be the primary causes of mortality for many patients. This study investigated the modulation of apoptosis-related genes in response to ionizing radiation and estrogen exposure based on a human breast epithelial cell model (MCF-10F and its transformed variants: Estrogen, Alpha3, Alpha5, Tumor2) previously established, where cells were treated with high linear energy transfer alpha particles, with or without 17β-estradiol. Gene expression profiling was performed using an Affymetrix U133A microarray, and bioinformatic analyses assessed differential expression, estrogen receptor status, and correlations with overall survival. Distinct gene expression patterns emerged across cell lines and tumor subtypes. TP53 expression correlated positively with TP63, BIK, CFLAR, BIRC3, and BCLAF1. TP63, PERP, CFLAR, BCLAF1, GULP1, and BIRC3 were elevated in normal tissue, whereas BIK, PHLDA2, and BBC3 were upregulated in tumors. ER-positive tumors exhibited higher TP63, BIK, BCLAF1, and BBC3 expression, while ER-negative tumors showed increased PERP, CFLAR, BIRC3, and PHLDA2. Notably, elevated BCLAF1 expression was associated with poorer survival in Luminal A patients, and high PHLDA2 expression correlated with reduced survival in Luminal B cases. These findings indicate that resistance to apoptosis is a fundamental mechanism in breast cancer progression and therapeutic evasion. Breast tumors selectively alter the expression of key genes to promote growth, evade apoptosis, and develop therapeutic resistance. The differential expression and correlations of these apoptosis-related genes highlight their potential as molecular targets for future personalized cancer therapies and as valuable biomarkers for prognostic stratification and predicting therapeutic response. Full article