Search Results (2,025)

Human endogenous retroviruses (HERVs) are potential driving forces of the pathophysiology of Myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS), linking post-infectious immune dysfunction to chronic inflammation and immune and neurocognitive dysfunction that are hallmark features of ME/CFS. Accumulating evidence from related autoimmune diseases and cancers has shown that reactivated HERVs can contribute to disease pathogenesis by amplifying immune activation through viral protein-mediated innate sensing, long terminal repeat (LTR)-driven transcription, and disrupting epigenetic silencing. HERV signatures are therefore promising biomarkers for diagnosis, patient stratification for drug-repurposing trials, and therapy monitoring. Accumulating evidence suggests a possible correlation between HERV expression and ME/CFS symptom severity, alterations in immune phenotypes, function and inflammatory gene networks. Importantly, locus-specific HERV profiling is a promising approach for distinguishing ME/CFS from overlapping or co-morbid conditions and healthy controls. Furthermore, HERV-targeted antibodies, immune modulators, epigenetic and antiviral interventions offer promise as concomitant therapeutic strategies for ME/CFS. Additional research incorporating viromics and other-omics validation, functional assays, and HERV-stratified clinical trials is now needed to realise this potential and to transform ME/CFS from a symptom-based syndrome into a mechanism-driven, treatable condition. Full article

Plant-derived bioactive compounds represent a major foundation of modern anticancer therapy and remain a prolific source of molecules with clinically relevant activity. This review provides an integrated classification of plant-derived anticancer compounds based on their clinical development status and predominant molecular mechanisms of action. Established chemotherapeutic agents, including taxanes, vinca alkaloids, and camptothecin derivatives, are distinguished from investigational phytochemicals such as polyphenols, flavonoids, terpenoids, and alkaloids that are under preclinical or clinical evaluation. These compounds target key hallmarks of cancer through modulation of microtubule dynamics, inhibition of topoisomerases, regulation of oncogenic signaling and epigenetic processes, and suppression of angiogenesis, invasion, and metastasis. Particular emphasis is placed on multitarget phytochemicals that interfere with PI3K/Akt, NF-κB, JAK/STAT, and MAPK pathways, induce apoptosis, and promote epigenetic reprogramming. In addition, major translational challenges, especially limited bioavailability, are discussed alongside advances in nano-enabled delivery systems designed to enhance therapeutic efficacy and reduce systemic toxicity. Collectively, this framework highlights the continuing relevance of plant-derived compounds in oncology and supports their rational integration into precision cancer therapy. Full article

Protein–protein interactions (PPIs) are critical for cellular signaling, apoptosis regulation, and immune function in the body, and dysregulation is a hallmark of cancer. The large, dynamic, and shallow nature of PPI interfaces rendered them “undruggable” by conventional small molecules in the past. Recent advances in structural biology, chemical innovation, and artificial intelligence have revolutionized the landscape of PPI-directed drug discovery. This review summarizes the mechanistic roles of PPIs in oncogenesis, critically discusses novel therapeutic interventions, such as small molecules, peptidomimetics, stapled peptides, proteolysis-targeting chimeras (PROTACs), molecular glues, and AI-based drug optimization strategies, altering the druggable proteome in oncology. Therapeutics with clinically well-validated action, including Venetoclax and AMG 510, and next-generation candidates demonstrate the translational applications of these approaches. Some of the key challenges, such as interface complexity, specificity, bioavailability, and resistance, are addressed together with countermeasures like rational design, combination therapies, enhanced delivery systems, and biomarker-based patient selection. To this end, the incorporation of multi-omics data and artificial-intelligence (AI)-driven modeling technologies is revolutionizing the personalized cancer therapeutics development space. Collectively, these advances mark a paradigm shift: PPIs, once considered inaccessible, are now at the forefront of precision oncology, offering new hope for patients with previously intractable malignancies. Full article

Gastric cancer (GC) is one of the most aggressive malignancies with a dismal prognosis, late diagnosis, and limited therapy efficacy. Biologically, GC is associated with multiple barriers to therapeutic response including gastric mucosal layer, acidic tumor microenvironment (TME), high accumulation of extracellular matrix (ECM) components, and limited penetration depth of anticancer drugs into tumor tissue. Furthermore, inherent or acquired drug resistance associated with drug efflux transporters, deregulated autophagy, tumor heterogeneity, and cell survival pathways severely compromise treatment response. Nanotechnology has been widely used to develop next-generation nanotherapeutic delivery systems to overcome these biological barriers. Currently available nanoplatforms such as liposomes, polymeric nanoparticles, dendrimers, and inorganic nanocarriers have improved drug loading capacity, aqueous solubility, circulation time stability, tumor-targeted delivery, and sustained release of chemotherapeutics. Smart and stimuli-responsive nanocarriers can also take advantage of pathological hallmarks of tumors including low pH, redox potential, and overexpressed enzymes for enhanced selective delivery to the tumor site. Nanotherapeutics have also shown promise for co-delivery of multiple therapeutic agents to overcome drug resistance, manipulation of TME, and suppression of autophagy and apoptosis signaling pathways associated with drug resistance. This review discusses recent advances in nanotherapeutics for GC including approaches to overcome biological barriers and drug resistance and highlights translational gaps for clinical development. Full article

Mice lacking epidermal Pparg (Pparg-/-^epi) exhibit increased cutaneous carcinogenesis, while PPARγ signaling is reduced in actinic keratoses (AKs) and cutaneous squamous cell carcinomas (cSCCs). Using transcriptomic analysis, we now show that the top upregulated genes in Pparg-/-^epi mouse skin, human AKs and cSCCs encode multiple damage-associated molecular patterns (DAMPs) that are TLR4 ligands, while the TLR4 agonist lipopolysaccharide (LPS) is also predicted to be the top common activated upstream regulator in both Pparg-/-^epi mouse skin and in tumor datasets. By single-cell sequencing, DAMP expression was particularly elevated in myeloid cells and myofibroblasts of Pparg-/-^epi mice, and these cell types exhibit transcriptional changes consistent with TLR4 signaling. Myeloid cells also exhibited a loss of Pparg expression and activity. Transcriptional analysis of published LPS-treated macrophages also reveals a decrease in PPARγ activity. Fibroblasts from Pparg-/-^epi mice included cells with a gene expression profile resembling myofibroblasts found in cancer and fibrotic diseases. This was accompanied by increased dermal fibrosis in aged mice and a transcriptomic profile that indicates a key role for both TLR4 and TGFβ signaling. These data suggest that loss of epidermal PPARγ may disrupt counterbalancing PPARγ–TLR4 signals, leading to chronic inflammation and fibrosis, hallmarks of cutaneous neoplasia. Full article

Aberrant glycosylation is a recognized hallmark of cancer, establishing Golgi α-mannosidase II (GMII) as strategic therapeutic target. While the natural alkaloid swainsonine demonstrated potent anticancer activity, its clinical use is hampered by toxicity from off-target inhibition of the lysosomal α-mannosidase (LMan). This review surveys computational methodologies advancing inhibitor development from empirical observations to precision structural optimization. We examine the evolution from Molecular Docking to advanced Quantum Mechanics (QM) and Molecular Dynamics (MD), highlighting their combined role in modeling metalloenzyme flexibility and energetics. Analysis reveals that selectivity relies on exploiting peripheral structural divergences, organelle-specific pH gradients, and distinct substrate conformational itineraries. In this context, electronic structure calculations and pKa predictions prove critical for designing “electrostatic switches”, inhibitors binding neutrally at Golgi pH while incurring lysosomal repulsion. Structurally, targeting the non-conserved “anchor site”, mimicking specific transition-state ring distortions and utilizing conformationally restricted scaffolds represent the most effective strategies. Integrating dynamic sampling with rigorous energetic profiling is therefore crucial for developing the next generation of safe, selective GMII inhibitors. Full article

The Papanicolaou (Pap) smear, a cornerstone of cervical cancer prevention, has emerged as a compelling, though unconventional, biospecimen for the detection of ovarian cancer (OC). This structured narrative review synthesizes the evolving evidence on the utility of cervicovaginal cytology and molecular analysis of Pap test material for OC detection. While conventional cytology provides a proof of concept, its sensitivity is low, ranging from incidental detection of OC in 0.004% of routine screens to 19.3% in patients with known OC. Specific cytologic findings, however, carry significant predictive value: atypical glandular cells (AGC) confer a two-fold increased OC risk, and psammoma bodies (PB) are strongly associated with serous malignancies. Driven by the sensitivity limitations of morphology, the field has undergone a paradigm shift towards molecular detection. Foundational studies confirmed tumor-derived DNA, including hallmark TP53 mutations, is detectable in Pap samples years before diagnosis, though sensitivity is constrained by low DNA abundance and confounded by background clonal mutations. To overcome this, strategies have expanded to target broader genomic signatures, such as somatic copy number alterations (EVA test: 75% sensitivity, 96% specificity), and multi-gene mutation panels (PapSEEK: 33–45% sensitivity). The most promising advances lie in multi-omic approaches, particularly DNA methylation biomarkers, which have demonstrated sensitivities up to 81% with high specificity. Collectively, this evidence argues against repurposing the Pap test as a standalone OC screen but supports its strategic integration into a risk-stratified clinical algorithm. We propose a “reflex-to-molecular” model where high-risk cytology (e.g., AGC, PB) automatically triggers advanced molecular testing on the same sample. This model efficiently leverages existing infrastructure to triage high-risk women for definitive diagnostics. Prospective validation of this integrated approach is the essential next step toward transforming this test into a sentinel for malignancies of the upper female reproductive tract. Full article

Fucosylation, the enzymatic addition of fucose residues to glycans, modulates receptor signalling and cellular identity in the intestinal epithelium. Its role as an integrative determinant of cancer cell fate in colorectal cancer (CRC) remains undefined. Transcriptomic and clinicopathological data from 976 CRC patients across three independent cohorts (TCGA-CRC, CPTAC2-CRC, Sidra-LUMC) were analysed. A curated fucosylation gene set was used to calculate tumour fucosylation scores. Associations with histogenetic status, genomic features, microenvironmental phenotypes, drug resistance programmes, and survival were evaluated using gene set enrichment analysis, multivariable Cox regression, and integrated molecular subtyping. High-fucosylation tumours exhibited elevated epithelial differentiation, MSI-H/BRAF-mutant enrichment, oxidative phosphorylation dominance, the complete absence of EMT and invasion programmes, and favourable prognosis (HR = 0.633, 95% CI: 0.470–0.853, p = 0.003). Low-fucosylation tumours demonstrated mesenchymal phenotypes, TP53 mutations, chromosomal instability, comprehensive multi-family RTK signalling, immune-excluded microenvironments, and poor outcomes. Distinct multidrug resistance programmes emerged: drug efflux in low-fucosylation tumours versus xenobiotic sensing, target bypass, and drug sequestration in high-fucosylation tumours. Tumour fucosylation status defines two fundamentally distinct CRC cell states with mutually exclusive engagement of invasion programmes, metabolic pathways, immune phenotypes, and resistance mechanisms. Fucosylation represents an independent prognostic biomarker and integrative determinant of cancer cell fate, with significant implications for risk stratification and personalised therapeutic strategies. Full article

Hematological malignancies, including multiple myeloma (MM), leukemia, and lymphoma, represent a major global health burden, accounting for approximately 6.6% of all cancer cases and contributing to significant mortality. The evolutionary conserved WNT/β-catenin signaling pathway is a critical regulator of normal hematopoietic stem cell homeostasis, and its dysregulation is a hallmark of various hematological malignancies. Aberrant activation through mutations, overexpression of ligands, or disruption of the destruction complex drives uncontrolled proliferation, impaired differentiation, and therapeutic resistance to therapy in acute and chronic leukemias, lymphomas, and multiple myeloma. Therapeutic interventions targeting this pathway, such as GSK-3 inhibitors, β-catenin antagonists, and small molecules like CWP291 and salinomycin, have demonstrated promising antitumor effects. Furthermore, combining WNT/β-catenin inhibition with targeted or epigenetic therapies, such as venetoclax and chidamide, can produce synergistic antitumor effects and overcome chemoresistance. Despite this potential, clinical translation is hampered by on-target toxicities in healthy tissues, pathway complexity, and a lack of predictive biomarkers. We conclude that the future of WNT-directed therapy lies in developing biomarker-selective agents, advanced drug delivery systems to improve specificity, and exploring novel combinations with immunotherapy to harness the anti-tumor immune response. Full article

Peripheral nerves provide a direct connection between the brain and the tumor microenvironment. This connection allows the nervous system to influence processes associated with the development, progression, and metastasis of different tumor types. Therefore, tumor innervation by peripheral nerve fibers is currently emerging as a characteristic that contributes to multiple hallmarks of cancer. Several experimental studies have shown that cancer progression involves actively inducing the ingrowth of autonomic and sensory nerve fibers into tumor tissue. In this process, known as neoaxonogenesis, cancer and other cells in the tumor microenvironment play an important role by synthesizing and releasing neurotrophic factors (e.g., nerve growth factor, brain-derived neurotrophic factor, glial cell line-derived neurotrophic factor), axonal guidance molecules (netrins, semaphorins, ephrins, slits), exosomes (containing microRNA and axonal guidance molecules), and other molecules present in the tumor microenvironment (e.g., granulocyte colony-stimulating factor, leukemia inhibitory factor), which modulate the ingrowth of nerve fibers into the tumor. This results in an increased nerve supply to tumor tissue, which is primarily linked to its growth. However, there are also studies demonstrating the protective effects of increased nerve fiber density against processes associated with cancer progression in certain types of cancer. The findings from these studies contribute to the complexity of neuro-cancer interactions, which is probably based on the type of cancer and the physiological specializations of the nerve fibers in a given organ. Despite contrasting findings, the stimulatory effects of nerve fibers on cancer growth are supported by several studies that described reducing the negative impact of nerve fibers on tumors and thus inhibiting cancer progression. The most significant approaches to reducing neural effects appear to be denervation, the administration of neurotransmitter receptor antagonists, the administration of local anesthetics, and the administration of antibodies against neurotrophic factors. Other significant approaches include methods that improve quality of life, such as psychotherapy and heart rate variability biofeedback. Despite their therapeutic potential, there are several limitations to using approaches that manipulate cancer innervation in clinical practice. These limitations include impaired normal tissue function and nervous system function, as well as the problematic direct application of the therapeutic agent to the tumor site, dosage-dependent, cancer type-dependent, cancer stage-dependent, duration-dependent, and timing-dependent effects. Procedures that modify neoaxonogenesis and nerve fiber signaling appear to be a promising new therapeutic approach in oncology. However, more research is needed to better understand their effects on cancer progression. In the future, the assessment of the presence and density of nerve fibers in tumors, as well as the evaluation of approaches aimed at reducing their negative impact, could be part of personalized anticancer therapy. As part of this therapy, a fresh tumor sample would be collected from the patient to generate patient-derived organoid models to test and consider the possibility of using supportive therapy and to predict its efficacy. Based on these results, it would be possible to evaluate the applicability of nerve-fiber-targeted therapy for a given patient. This review article summarizes and describes the current knowledge concerning the significance of nerve fibers in cancer progression, with a particular emphasis on neoaxonogenesis in tumors and the various factors that influence this process. Full article

Background: Aberrant protein O-fucosylation mediated by protein O-fucosyltransferase 1 (POFUT1), has emerged as a hallmark of tumorigenesis that regulates key signaling pathways, including Notch, which is frequently dysregulated in cancers. Protein O-fucosylation, catalyzed by POFUT1, regulates Notch signaling and has been implicated in individual cancers, but its pan-cancer expression patterns, clinical significance, and relationship to tumor immunity remain incompletely characterized. Methodology: We conducted a multi-omics bioinformatics analysis using TCGA and other public datasets to evaluate POFUT1 expression across 33 cancer types (n > 10,000). Differential expressions, tumor stage correlations, and survival outcomes were assessed. Immune cell infiltration was estimated using SangerBox and TIMER algorithms, while promoter methylation patterns were analyzed through UALCAN. Functional enrichment and protein–protein interaction networks were constructed to elucidate functional mechanism. Western blot validation in prostate and ovarian cancer cell lines confirmed our computational analysis. Results: POFUT1 showed significant overexpression in 16 of 33 cancer types (FDR-adjusted p < 0.05), with the highest elevation in BRCA (breast invasive carcinoma; log2FC = 2.31) and LUAD (lung adenocarcinoma; log2FC = 2.1). A high POFUT1 expression correlated with poor overall survival in eight cancer types (HR range: 1.8–3.2, p < 0.01) and disease-free survival in seven cancers. POFUT1 levels positively correlated with myeloid-derived suppressor cells (MDSCs) infiltrating in 15 cancer types, while inversely correlated with natural killer T (NKT) cells presence in 15 cancers (mean R = −0.34, p < 0.05), indicating an association with immunosuppressive microenvironments. Promoter hypomethylation in tumors suggested epigenetic dysregulation as a potential driver of its overexpression. Western blot analysis confirmed POFUT1 protein upregulations in prostate and ovarian cancer cell lines (1.7–2.1-fold. p < 0.01), corroborating transcriptomic findings. Conclusion: This pan-cancer study establishes POFUT1 as a critical oncogenic factor linked to aggressive disease, immune evasion, and poor prognosis. Its consistent overexpression and functional impact highlight its potential as a biomarker and target for anticancer therapy. While these computational findings require experimental validation, POFUT1 emerges as a candidate biomarker warranting functional studies and potential therapeutic targeting. Full article

Background/Objectives: Triple-negative breast cancer (TNBC) is frequently characterized by notably elevated Ki-67 expression, a hallmark of uncontrolled rapid cell-cycle progression. However, the underlying mechanisms remain unclear, leading to limited therapeutic options. Methods: In this study, hub gene was identified through integrated bioinformatic analysis of public datasets (TCGA-BRCA and METABRIC). Subsequent functional validation was performed both in vitro and in vivo using siRNA-mediated knockdown and small-molecule inhibitors. Phenotypic effects—including cell viability, cell cycle distribution, DNA synthesis, and clonogenic survival—were comprehensively assessed using MTT assays, flow cytometry, EdU, and colony formation assays. Protein-level changes were confirmed by Western blotting and immunohistochemistry (IHC). To dissect the transcriptional regulation of the key hub gene TTK, we first predicted potential upstream transcription factors using the JASPAR database; binding specificity was then validated through in silico motif analysis, luciferase reporter assays, and chromatin immunoprecipitation followed by quantitative PCR (ChIP-qPCR). Results: The mitotic kinase TTK is significantly overexpressed in TNBC compared with non-TNBC breast cancers. Notably, TTK overexpression exhibited a strong positive correlation with elevated Ki-67 indices and reduced overall survival in TNBC patients. Functional validation demonstrated that pharmacological or genetic inhibition of TTK effectively induced G2/M cell-cycle arrest and potently suppressed TNBC proliferation in both in vitro cell cultures and in vivo xenograft models. Mechanistically, TTK overexpression stems from enhanced transcriptional initiation driven by the transcription factor NFYA binding to the CCAAT box in the TTK promoter—an interaction newly identified here. Concurrently, TTK blockade disrupted spindle assembly checkpoint (SAC) signaling via BUB1B/MAD1L1 downregulation, triggering mitotic arrest and catastrophe. Conclusions: Collectively, these findings establish TTK as a key cell-cycle regulator driving TNBC proliferation. More importantly, targeting mitotic control through TTK inhibition represents an efficient strategy to impede the aberrantly fast cell cycle progression in TNBC. Full article

Background: DNA methylation alterations represent a key epigenetic mechanism linking environmental exposures to disease pathogenesis. The present study aimed to identify differentially methylated genes and shared biological processes associated with lung cancer (LuCa), chronic obstructive pulmonary disease (COPD) and tobacco exposure. Methods: A comprehensive literature search was performed in PubMed to identify studies evaluating DNA methylation in LuCa, COPD and smoking-related models. A total of 117 articles were selected, including 83 studies on lung cancer, 18 on COPD and 16 on smoking exposure. Genes exhibiting statistically significant methylation changes relative to controls were extracted from each study. To provide additional support for these findings, differential methylation signatures were further evaluated using The Cancer Genome Atlas (TCGA) lung adenocarcinoma (LUAD) and lung squamous cell carcinoma (LUSC) datasets. Functional and transcription factor motif enrichment analyses were subsequently conducted to identify shared biological pathways and regulatory mechanisms. Results: In total, 324 genes displaying altered methylation patterns across these conditions were identified. Seven tumor suppressor genes (CDKN2A, CDH13, MGMT, MIR137, DAPK1, RARB, and RASSF1A) consistently exhibited hypermethylation in both lung cancer and in association with smoking exposure. In addition, AHRR hypomethylation emerged as a shared epigenetic hallmark across all three conditions. TCGA-based analyses confirmed several of these methylation patterns and revealed subtype-specific methylation profiles associated with smoking history. Functional enrichment highlighted common biological processes and signaling pathways, particularly those related to transcriptional regulation, apoptosis and cancer-associated pathways. Conclusions: These results provide an integrative overview of shared DNA methylation alterations associated with smoking exposure, COPD, and lung cancer, and suggest potential DNA methylation candidates that may be relevant for future biomarker development and mechanistic studies. Full article

Non-coding RNAs (ncRNAs) have emerged as important regulators of gene expression and cellular homeostasis, and their dysregulation is now recognized as a hallmark of cancer. Over the past decades, extensive research has demonstrated that diverse ncRNA classes, including microRNAs (miRNAs), long non-coding RNAs (lncRNAs), circular RNAs (circRNAs), and other small ncRNA species, participate in complex regulatory networks that influence tumor initiation, progression, metastasis, and therapy response. Through mechanisms such as transcriptional regulation, post-transcriptional gene silencing, epigenetic modulation, and competitive endogenous RNA interactions, ncRNAs shape the molecular circuitry underlying cancer development. In addition to their functional roles in tumor biology, many ncRNAs are released into biological fluids and can be detected as circulating molecules in blood, urine, saliva, and other biofluids. Their remarkable stability in extracellular environments has generated considerable interest in their use as minimally invasive biomarkers in liquid biopsy applications. Emerging evidence has shown that circulating ncRNAs (c-ncRNAs) can support cancer detection, disease stratification, and treatment monitoring. This narrative review provides an integrated view that links ncRNA-mediated regulatory networks with their application as liquid biopsy biomarkers, positioning ncRNAs as comprehensive indicators of tumor conditions. Particular emphasis is placed on c-ncRNA biomarkers, the integration of multiple ncRNA classes, and multi-analyte biomarker strategies that combine ncRNAs with complementary circulating molecules such as cell-free DNA and protein markers. Finally, we discuss the technical and clinical challenges that currently limit the translation of ncRNA-based diagnostics into clinical practice and highlight future directions for advancing ncRNA-guided liquid biopsy approaches in precision oncology. Full article

Oncolytic viruses represent a paradigm-shifting approach to cancer immunotherapy, functioning as in situ vaccines that convert immunologically “cold” tumors into “hot” tumors through induction of immunogenic cell death (ICD). Despite the clinical success of checkpoint inhibitors targeting programmed cell death protein 1 (PD-1)/programmed death-ligand 1 (PD-L1) and cytotoxic T-lymphocyte-associated protein 4 (CTLA-4), many patients exhibit primary or acquired resistance due to insufficient tumor immunogenicity and exclusion of tumor-infiltrating lymphocytes. Oncolytic viruses address this limitation by selectively replicating in tumor cells, inducing robust ICD characterized by four cardinal hallmarks: calreticulin exposure, ATP secretion, HMGB1 release, and type I interferon production. This review systematically examines the molecular mechanisms underlying virus-induced ICD, compares DNA virus platforms (Vaccinia, HSV-1, Adenovirus) with RNA virus platforms (Coxsackieviruses A21, A11, and B3), and analyzes clinical trial data demonstrating synergistic efficacy when combined with checkpoint inhibitors. Notably, RNA viruses generate higher type I interferon responses compared to DNA viruses, correlating with superior clinical outcomes. Coxsackievirus A21 combined with pembrolizumab achieved a 47% objective response rate in melanoma in the CAPRA trial, representing notable efficacy exceeding either monotherapy. Coxsackievirus A11 demonstrates exceptional selectivity for thoracic cancers through ICAM-1-dependent receptor tropism and potent immunogenic cell death induction. Japanese researchers have pioneered microRNA-targeted Coxsackievirus B3, achieving cardiac safety attenuation while preserving complete oncolytic potency and ICD-inducing capacity. This comprehensive analysis synthesizes molecular mechanisms, platform comparisons, clinical efficacy data, and translational challenges to guide future development of oncolytic virotherapy as a cornerstone of cancer immunotherapy. Full article