Malignant melanoma is the most lethal form of skin cancer, characterised by a poor survival rate. One of the key factors driving the aggressive growth of melanoma cells is the elevated expression of the proto-oncogene Bcl-3. This study aims to optimise, evaluate and characterise a second-generation Bcl-3 inhibitor, using melanoma as a model to demonstrate its potential therapeutic efficacy.

We synthesised and screened a series of structural analogues and selected A27, the most promising candidate for further investigation. We assessed whether A27 disrupted the interaction between Bcl-3 and its binding partner, p50, and examined the subsequent effects on cyclin D1 expression. Additionally, we evaluated the impact of A27 on melanoma cell proliferation and migration in vitro, as well as its therapeutic efficacy in various in vivo melanoma models.

Nuclear magnetic resonance (NMR) confirmed that A27 directly binds to Bcl-3, effectively inhibiting its function. By disrupting the Bcl-3/p50 interaction, A27 led to a significant down-regulation of cyclin D1 expression. In cellular assays, A27 markedly reduced proliferation and migration of melanoma cells. In vivo, treatment with A27 resulted in a substantial reduction in melanoma tumour growth, with no observed toxicity in treated animals.

At present, no other Bcl-3 inhibitors exist for clinical application in the field of oncology, and as a result, our novel findings provide a unique opportunity to develop a highly specific drug against malignant melanoma to meet an urgent clinical need.

Immune checkpoint inhibitors (ICIs) have revolutionized the treatment of metastatic melanoma, but a percentage of patients did not show benefit. Circulating tumor DNA (ctDNA) has emerged as a potential non-invasive tool for monitoring disease evolution and treatment response. The present study aimed to evaluate the clinical utility of ctDNA dynamics in patients with metastatic melanoma receiving ICIs, while exploring its role in the oncological course.

The LIQUID-MEL study is a prospective, single-centre pilot study including patients with BRAF/NRAS-mutant metastatic melanoma. ctDNA was quantified using digital droplet PCR (ddPCR) at four different time points. Uni- and multivariable Cox regression models were used to assess the correlation between shedding and progression-free survival (PFS), and overall survival (OS).

Overall, 23 patients were included. At baseline, ctDNA was detectable in 5/23 (21.7 %) cases. Baseline ctDNA shedding was associated with shorter PFS (3.88 months vs. 0.69 months, p=0.012). A strong numerical trend was observed also in OS (12.66 months vs. 2.53 months, p=0.287). Shedding at baseline did not demonstrate independent prognostic or predictive value in the uni- and multivariable analysis. The longitudinal analysis revealed intriguing patterns of ctDNA shedding in individual patients.

ctDNA detectability and its dynamic changes during treatment may have potential clinical utility in patients with metastatic melanoma, offering a valuable non-invasive tool for monitoring disease and treatment response. The small sample size limited the statistical power of the analysis. Further studies with larger cohorts are needed to validate its role in routine clinical practice.

The escalating global threat of ultraviolet (UV) radiation is manifested through multifaceted damage pathways including cutaneous carcinogenesis, photodegradation of organic substrates, marine ecosystem destabilization, and infrastructure weathering. These urgent challenges have catalyzed sustained interdisciplinary efforts toward advanced UV-shielding technologies spanning biomedical, environmental, and industrial domains. Current material arsenals include melanin, lignin, tannin, polydopamine, zinc oxide and titanium dioxide, etc. These materials can be applied to diverse fields such as food packaging, sunscreen fabrics, sunscreen creams, eyeglasses, and sunscreen films through tailored processing techniques and employing distinct photoprotective mechanisms. Notwithstanding significant progress, the development of an integrated selection framework that reconciles efficiency, durability, and environmental compatibility persists as a critical knowledge gap. In this context, the main mechanisms of various types of UV shielding materials and their applications in different fields are described systematically. Subsequently, a comparative analysis of the advantages and shortcomings of different materials is presented, focusing on their UV shielding efficiency and stability impact. Moreover, the review delves into their unique value in specific scenarios. Finally, building on these analyses, current challenges and future development prospects of UV shielding materials are further discussed, with emphasis on scalability, eco-friendly alternatives, and multifunctional integration, providing valuable insights and guidance for advancing research and promoting sustainable and functional innovations in this field.

Allosteric inhibitors of the tyrosine phosphatase Src homology 2 domain-containing protein tyrosine phosphatase 2 (SHP2) hold therapeutic promise in cancers with overactive RAS/ERK signaling, but adaptive resistance to SHP2 inhibitors may limit benefits. Here, we utilized tumor cells that proliferate similarly with or without endogenous SHP2 to explore means to overcome this growth independence from SHP2. We found that SHP2 depletion profoundly altered the output of vascular regulators, cytokines, chemokines, and other factors from SHP2 growth-resistant cancer cells. Tumors derived from inoculation of SHP2-depleted, but SHP2 growth-independent, mouse melanoma and colon carcinoma cell lines displayed a typically subverted architecture, in which proliferative tumor cells surrounding a remodeled vessel formed "vascular islands", each limited by surrounding hypoxic and dead tumor tissue, where inflammatory blood cells were limited. Although vascular islands generally reflect protected sanctuaries for tumor cells, we found that vascular island-resident, highly proliferative, SHP2-depleted tumor cells acquired an increased sensitivity to blockage of MEK/ERK signaling, resulting in reduced tumor growth. Our results show that the response to targeted therapies in resistant tumor cells was controlled by tumor cell-induced vascular changes and tumor architectural reorganization, providing a compelling approach to elicit tumor responses by exploiting tumor- and endothelium-dependent biochemical changes.

Somatic cells can transform into tumors due to mutations, and the tumors further evolve towards increased aggressiveness and therapy resistance. We develop DiffInvex, a framework for identifying changes in selection acting on individual genes in somatic genomes, drawing on an empirical mutation rate baseline derived from non-coding DNA that accounts for shifts in neutral mutagenesis during cancer evolution. We apply DiffInvex to >11,000 somatic whole-genome sequences from ~30 cancer types or healthy tissues, identifying genes where point mutations are under conditional positive or negative selection during exposure to specific chemotherapeutics, suggesting drug resistance mechanisms occurring via point mutation. DiffInvex identifies 11 genes exhibiting treatment-associated selection for different classes of chemotherapies, linking selected mutations in PIK3CA, APC, MAP2K4, SMAD4, STK11 and MAP3K1 with drug exposure. Various gene-chemotherapy associations are further supported by differential functional impact of mutations pre- versus post-therapy, and are also replicated in independent studies. In addition to nominating drug resistance genes, we contrast the genomes of healthy versus cancerous cells of matched human tissues. We identify noncancerous expansion-specific drivers, including NOTCH1 and ARID1A. DiffInvex can also be applied to diverse analyses in cancer evolution to identify changes in driver gene repertoires across time or space.

Elongator acetyltransferase complex subunit 6 (ELP6), a subunit of the elongator complex, can increase the migratory potential of melanoma cells in vitro. However, the clinical relevance of ELP6 in patients with melanoma remains unclear. The present study aimed to investigate the role of ELP6 expression in melanoma progression and association with patient survival rates. Transcriptomic data from patients with melanoma available in The Cancer Genome Atlas, Gene Expression Profiling Interactive Analysis and cBioPortal databases were analysed to evaluate the associations between ELP6 expression levels and patient survival. In vitro experiments were conducted using short hairpin RNAs to downregulate ELP6, with a focus on cell viability, cell cycle regulation and the ERK1/2 signalling pathway. ELP6 expression levels were significantly elevated in patients with melanoma and were associated with poor survival outcomes. Knockdown of ELP6 resulted in decreased expression levels of p42 MAPK, reduced cell viability, G1 phase cell cycle arrest and led to reduced responsiveness to the MEK1/2 inhibitor U0126. ELP6 promotes melanoma progression via the ERK1/2 signalling pathway. Therefore, assessing ELP6 expression may offer potential therapeutic strategies for patients with melanoma.

Malignant melanoma presents a significant challenge in oncology due to its aggressive nature and high metastatic potential. Conventional systemic treatments often fail to effectively reach tumor sites, limiting their therapeutic impact. This study introduces a groundbreaking triple-strategy approach for treating malignant melanoma. A novel prodrug, an oligonucleotide, comprising 10 units of Floxuridine (5-fluoro-2'-deoxyuridine) (FdU) nucleoside antimetabolites are developed, to enhance half-life and reduce rapid metabolism. Encapsulated in soluble colloidal silica nanoparticles, this compound is protected and directed toward tumor neovasculature precursor endothelial cell receptors, ensuring local delivery. The strategy focuses on releasing the prodrug in the tumor microenvironment, aiming to eradicate both melanoma cells and their supportive structures. Efficacy is demonstrated in cell culture studies and preclinical models of malignant melanoma, showing a remarkable 50% reduction in tumor size after just three intravenous treatments. These findings underscore the transformative potential of targeting endothelial cell membrane proteins for drug delivery. This study paves the way for innovative targeted therapies, promising significant advancements in treatment strategies and improves outcomes for patients with metastatic cancers.

SWI/SNF (switch/sucrose non-fermentable) chromatin remodelers possess unique functionalities difficult to dissect. Distinct cancers harbor mutations in specific subunits, such as the polybromo-associated BAF (PBAF)-specific component ARID2 in melanoma. Here, we perform epigenomic profiling of SWI/SNF complexes and their associated chromatin states in melanocytes and melanoma. Time-resolved approaches reveal that PBAF regions are generally less sensitive to ATPase inhibition than BAF sites. We further uncover a subset of PBAF-exclusive regions within Polycomb-repressed chromatin that are enriched for REST (RE1 silencing transcription factor), a transcription factor that represses neuronal genes. In turn, PBAF complex disruption via ARID2 loss hinders REST's ability to bind and inactivate its targets, leading to upregulation of synaptic transcripts. Remarkably, this gene signature is conserved in melanoma patients with ARID2 mutations and correlates with an expression program enriched in melanoma brain metastases. Overall, we demonstrate a unique role for PBAF in generating accessibility for a silencing transcription factor at repressed chromatin, with important implications for disease.

Immune checkpoint inhibitors (ICIs), particularly PD-1/PD-L1 blockade, have shown great success in treating melanoma. PD-L1 (B7-H1, CD274), a ligand of PD-1, binds to PD-1 on T cells, inhibiting their activation and proliferation through multiple pathways, thus dampening tumor-reactive T cell activity. Studies have linked PD-L1 expression in melanoma with tumor growth, invasion, and metastasis, making the PD-1/PD-L1 pathway a critical target in melanoma therapy. However, immune-related adverse events are common, reducing the effectiveness of anti-PD-L1 treatments. Recent evidence suggests that the gut microbiome significantly influences anti-tumor immunity, with the microbiome potentially reprogramming the tumor microenvironment and overcoming resistance to anti-PD-1 therapies in melanoma patients. This review explores the mechanisms of PD-1/PD-L1 in melanoma and examines how gut microbiota and its metabolites may help address resistance to anti-PD-1 therapy, offering new insights for improving melanoma treatment strategies.

Cutaneous melanoma is a common cancer in Australia and New Zealand, Europe, and North America, and its incidence is still increasing in many regions. Ultraviolet (UV) radiation exposure (for example, through excessive sunlight exposure) remains the primary risk factor for melanoma; however, public awareness campaigns have led to a marked reduction in mortality. In addition to genetic damage from UV radiation, specific genetic alterations have been linked to melanoma. The stage of the tumour at the time of diagnosis is of greater importance for melanoma prognosis than in almost any other cancer. Context-dependent genetic mutations that attenuate tumour-suppressive mechanisms or activate growth-promoting signalling pathways are crucial factors in the development of cutaneous melanoma. In addition to external factors such as UV radiation, the tumour microenvironment can contribute to melanoma progression, invasion and metastasis. Cutaneous melanoma treatment has improved considerably over the past decade with the discovery and development of immune checkpoint inhibitors and therapy targeting BRAF and MEK. Over the next decade, several priorities are likely to influence melanoma research and management, including the continued advance of precision medicine methods to identify the most suitable patients for the most effective treatment, with the aim of improving clinical outcomes.

Cancer development is driven by mutations, yet tumor-causing mutations only lead to tumor formation within specific cellular contexts. The reasons why certain mutations trigger malignant transformation in some contexts but not others remain often unclear. Both intrinsic and extrinsic factors play a key role in driving carcinogenesis by leading the cells toward a state of 'oncogenic competence'. This state is shaped by the transcriptional and epigenetic programs that define a specific cell in time and space. These programs arise from the interplay between genetic mutations, cellular lineage, differentiation state, and microenvironment. A deeper understanding of oncogenic competence is essential to uncover the mechanisms behind tumor initiation and, ultimately, advance the development of novel targeted therapies for cancer treatment and prevention.

There has been an upsurge in the incidences of skin disorders and their mortalities owing to various environmental, hormonal, and epigenetic risk factors. Melanoma, atopic dermatitis, psoriasis, and photoaging and associated consequences are largely observed in the population globally. The social stigma, economic burden, and adverse effects from chronic medication endured by the patients emphasize the necessity of more effective natural therapeutics. Carotenoids are economically valuable tetraterpenoid pigments synthesized by plants and microorganisms, which play a paramount role in their overall growth and development. Extensive in vitro and in vivo investigations evidenced that phytopigments like carotenoids target multiple intracellular signaling pathways involving the mitogen-activated protein kinases, Janus kinase/signal transducers, and activators of transcription, apoptotic, and autophagy proteins to ameliorate melanoma. Besides, carotenoids curbed the activation and the release of immunoregulatory molecules such as cytokines and chemokines to abrogate skin immune disorders, photoaging, and associated consequences. Here, we provide a holistic discussion on the pathophysiology of prominent skin disorders and the ameliorating effects of carotenoids as evidenced in the in vitro, in vivo, and clinical interventions. We also advocate the requisite of formulating carotenoid medications after extensive clinical interventions and validation for mitigating various skin dysfunctions.

Drosophila melanogaster crystal cells are a specialized type of blood cells for the innate immune process upon injury. Under normal conditions, crystal cells rarely proliferate and constitute a small proportion of fly blood cells. Notch signaling has been known to guide the cell fate determination of crystal cells and maintain their survival. Here, we reported that protein phosphatase V (PpV), the unique catalytic subunit of protein phosphatase 6 in Drosophila, is a novel regulator of crystal cell proliferation and integrity. We found that PpV proteins highly accumulated in crystal cells in the larval hematopoietic organ termed the lymph gland. Silencing PpV using RNA interference led to increased crystal cell proliferation in a Notch-independent manner and induced crystal cell rupture dependent on Notch signaling. Moreover, additive PpV prevented the rupture of crystal cells in lymph glands upon a needle injury, suggesting the involvement of PpV in wound healing. Altogether, our results indicated that PpV plays a dual role in lymph glands, preventing crystal cell proliferation to limit the cell number, as well as inhibiting crystal cell rupture to maintain their survival.

In recent years, there has been a gradual increase in the incidence and mortality rates of melanoma, posing a significant threat to human health and life. Protein tyrosine phosphatases (PTPNs) have been implicated in the progression of various human cancers, including breast, lung, and cervical cancer. To investigate PTPN9 expression in melanoma, impacting the disease's survival and prognosis. Our study, which involved an analysis of The Cancer Genome Atlas database and immunohistochemical staining of pathological sections, identified an upregulation of PTPN9 expression in melanoma, impacting the disease's survival and prognosis. At the cellular level, we investigated the effects of PTPN9 on the proliferation, invasion, and metastasis of A375 and SK-MEL-28 cells. Through various experimental techniques such as Western blot protein detection, electron microscopy, and oil red O staining, we observed that PTPN9 potentially contributes to the development of skin cutaneous melanoma (SKCM) by regulating ferroptosis-related proteins ACSL4, FTH1, and P53, thereby influencing lipid metabolism. The results of this study highlight the unique role of PTPN9 in SKCM and suggest its potential as a biomarker for the disease.

Skin cutaneous melanoma (SKCM) is one of the most lethal cancers translating into 75% of skin cancer-related deaths. Despite the advances in SKCM management and treatment strategies, the overall survival of patients remains unsatisfactory due to the metastatic properties of SKCM as well as the absence of effective prognostic biomarkers. Recent studies have shown that overload copper renders accumulation of mitochondrial proteins and fuels a form of cell death at odds with known death mechanisms and is hinged on mitochondrial respiration, the so-called cuproptosis. However, the exact role of cuproptosis in SKCM development and progression is unknown, and painting a clear picture of its functions in SKCM is fraught with challenges. A more systematic investigation is justified. In this study, we were posed to dissect the clout and latent regulatory mechanisms of cuproptosis-related genes (CRGs) in reining in SKCM progression. Also, we identified three CRGs that stood out were used to construct a prognostic model, which could be employed to predict the prognosis of patients with SKCM. Finally, through pan-cancer analysis, we found that the four cuproptosis key genes play a role in multiple tumors, suggesting that cuproptosis may impact tumor progression at the pan-cancer level. Taken together, these findings may not only contribute to the development of treatment strategies but also provide clues for treatment decision-making.

MicroRNAs (miRNAs) play crucial roles in gene regulation, and their dysregulation is associated with various diseases, including cancer. Abnormal DNA methylation can alter gene expression and influence carcinogenesis. DNA methylation-based biomarkers are emerging as promising tools for early cancer diagnosis. This study aimed to investigate the role of miR-129-2-3p in esophageal cancer (EC) and explore its potential as a diagnostic biomarker.

To achieve these objectives, we employed multi-sample MethylTarget technology to assess the methylation status of miR-129-2-3p in EC tissues. The diagnostic value of miR-129-2-3p was evaluated using logistic regression and receiver operating characteristic (ROC) curve analysis. Functional assays were conducted to examine the effects of miR-129-2-3p overexpression on EC cell proliferation and migration. Luciferase reporter assays were performed to confirm Protein Phosphatase 6 Catalytic Subunit (PPP6C) as a direct target of miR-129-2-3p. Finally, the impact of PPP6C overexpression on the inhibitory effects induced by miR-129-2-3p was assessed.

We found that miR-129-2-3p is hypermethylated in EC tissues. Diagnostic analysis revealed that miR-129-2-3p had a sensitivity of 0.884, a specificity of 0.659, and an area under the curve (AUC) of 0.799. Overexpression of miR-129-2-3p significantly suppressed EC cell proliferation and migration. Furthermore, PPP6C was identified as a direct target of miR-129-2-3p, and its expression was suppressed. The elevation of PPP6C counteracted the inhibitory effects of miR-129-2-3p on EC cell proliferation and migration.

Hypermethylated miR-129-2-3p inhibits EC cell proliferation and migration by downregulating PPP6C expression, suggesting that miR-129-2-3p may serve as a potential diagnostic biomarker for EC.

With ever-increasing incidence and high metastatic potential, cutaneous melanoma is the deadliest skin cancer. Risk prediction based on the Tumor-Node-Metastasis (TNM) staging system has medium accuracy with intermediate IIB-IIIB stages, as roughly 25% of patients with low-medium-grade TNM, and hence a favorable prognostic, undergo an aggressive disease with short survival and around 15% of deaths arise from metastases of thin, low-risk lesions. Therefore, reliable prognostic biomarkers are required. We used genomic and clinical information of melanoma patients from the TCGA-SKCM cohort and two GEO studies for discovery and validation of potential biomarkers, respectively. Neither mutation nor overexpression of major melanoma driver genes provided significant prognostic information. Conversely, expression of MGRN1 and the melanocyte-specific genes MLANA, PMEL, and TYRP1 provided a simple 4-gene signature identifying with high-sensitivity (>80%), low-medium TNM patients with adverse outcomes. Transcriptomic analysis of tumors with this signature, or from low-medium-grade TNM patients with poor outcomes, revealed comparable dysregulation of an inflammatory response, cell cycle progression, and DNA damage/repair programs. A functional analysis of MGRN1-knockout cells confirmed these molecular features. Therefore, the simple MGRN1-MLANA-PMEL-TYRP1 combination of biomarkers complemented TNM staging prognostic accuracy and pointed to the dysregulation of immunological responses and genomic stability as determinants of a melanoma outcome.

Metastatic melanoma remains a major clinical challenge. Large-scale genomic sequencing of melanoma has identified bona fide activating mutations in RAC1, which are associated with resistance to BRAF-targeting therapies. Targeting the RAC1-GTPase pathway, including the upstream activator PREX2 and the downstream effector PI3Kβ, could be a potential strategy for overcoming therapeutic resistance, limiting melanoma recurrence, and suppressing metastatic progression. Here, we used genetically engineered mouse models and patient-derived BRAFV600E-driven melanoma cell lines to dissect the role of PREX2 in melanomagenesis and response to therapy. Although PREX2 was dispensable for the initiation and progression of melanoma, its loss conferred sensitivity to clinically relevant therapeutics targeting the MAPK pathway. Importantly, genetic and pharmacologic targeting of PI3Kβ phenocopied PREX2 deficiency, sensitizing model systems to therapy. These data reveal a druggable PREX2/RAC1/PI3Kβ signaling axis in BRAF-mutant melanoma that could be exploited clinically. Significance: Cotargeting the MAPK and the PREX2/RAC1/PI3Kβ pathways has remarkable efficacy and outperforms monotherapy MAPK inhibition in BRAF-mutant melanoma, supporting the potential of this combination therapy for treating metastatic melanoma.

Melanoma brain metastases (MBM) are a common and lethal complication of metastatic melanoma. Despite improvements in treatments, subsets of patients with MBM experience rapid clinical decline, and currently, few prognostic biomarkers have been identified. An improved understanding of the molecular features specifically associated with MBM overall survival (OS) and intracranial progression-free survival (PFS) could facilitate the development of more effective clinical management strategies.

We established an initial cohort of 102 MBMs, 970 unmatched melanoma extracranial metastases (ECM), and 569 unmatched melanoma primaries with available targeted exome sequencing data covering 182 genes and a validation cohort of 50 MBMs with SMARCA4 genomically profiled. Kaplan-Meier analysis, log-rank test, and Cox proportional hazards model were used to evaluate associations between pathogenic genomic alterations and OS and intracranial PFS. We evaluated 14 MBMs and 19 ECMs with paired RNA sequencing and whole-exome sequencing data to identify genotype-transcriptome correlations.

Of 43 genes significantly mutated among MBMs, only pathogenic mutations in SMARCA4 significantly associated with shorter OS and intracranial PFS on univariable and multivariable analyses in patients with MBM but not from first ECM or primary tumor diagnosis. SMARCA4 mutations significantly associated with enrichment of oxidative phosphorylation and depletion of immune signaling gene sets.

Pathogenic SMARCA4 mutations independently predict an association with shorter OS and intracranial PFS in patients with MBM and associate with expression of pathways known to mediate melanoma virulence. These findings add to our understanding of MBM pathogenesis and suggest their potential use as prognostic biomarkers in patients with MBM and possible therapeutic opportunities.

S-acylation, which includes S-palmitoylation, is the only known reversible lipid-based post-translational protein modification. S-palmitoylation is mediated by palmitoyl acyltransferases (PATs), a family of 23 enzymes commonly referred to as zDHHCs, which catalyze the addition of palmitate to cysteine residues on specific target proteins. Aberrant S-palmitoylation events have been linked to the pathogenesis of multiple human diseases. While there have been advances in elucidating the molecular mechanisms underlying the pathogenesis of various skin conditions, there remain gaps in the knowledge, specifically with respect to the contribution of S-palmitoylation to the maintenance of skin barrier function. Towards this goal, we performed PubMed literature searches relevant to S-palmitoylation in skin to define current knowledge and areas that may benefit from further research studies. Furthermore, to identify alterations in gene products that are S-palmitoylated, we utilized bioinformatic tools such as SwissPalm and analyzed relevant data from publicly available databases such as cBioportal. Since the targeting of S-palmitoylated targets may offer an innovative treatment perspective, we surveyed small molecules inhibiting zDHHCs, including 2-bromopalmitate (2-BP) which is associated with off-target effects, and other targeting strategies. Collectively, our work aims to advance both basic and clinical research on skin barrier function with a focus on zDHHCs and relevant protein targets that may contribute to the pathogenesis of skin conditions such as atopic dermatitis, psoriasis, and skin cancers including melanoma.

Metabolic dysfunction-associated steatohepatitis (MASH) is a serious chronic liver disease for which therapeutic options are limited. Although fibroblast growth factor 21 (FGF21) analogs have shown therapeutic promise for MASH in multiple preclinical and clinical studies, their underlying mechanisms of action remain elusive.

Liver-specific PPP6C and βKlotho knockout mice and their wild-type littermates were fed an AMLN (Amylin liver NASH) diet for 16 weeks or a CDA-HFD (choline-deficient, L-amino acid-defined, high-fat diet) for 8 weeks, followed by daily subcutaneous injection of recombinant FGF21 (0.5 mg/kg) or vehicle for 4 weeks. A mass spectrometry assay identified PPP6C as a βKlotho-binding protein. An in vitro phosphatase assay was used to evaluate the effects of FGF21 on PPP6C activity. PPP6C expression was also analyzed in human samples from patients with MASH.

We identified serine and threonine phosphatase PPP6C as a direct target of FGF21. Hepatic PPP6C deficiency accelerates MASH progression in mice fed an AMLN diet or CDA-HFD, which blocks the effect of FGF21 on MASH. Mechanistically, PPP6C is sufficient to interact with the coreceptor βKlotho upon FGF21 treatment and directly dephosphorylates tuberous sclerosis complex 2 (TSC2) at Ser939 and Thr1462, thereby inhibiting mTORC1 and promoting nuclear entry of TFE3 and Lipin1. In the livers of patients with MASH, expression levels of PPP6C are decreased whereas TSC2 phosphorylation is elevated.

PPP6C acts as a fundamental downstream mediator essential for FGF21 signaling in hepatocytes and targeting PPP6C by FGF21 may offer therapeutic potential for treating MASH in humans.

Metabolic dysfunction-associated steatohepatitis (MASH) is a severe chronic liver disease that increases susceptibility to more severe cirrhosis and hepatocellular carcinoma. Effective therapeutic strategies for MASH remain an unmet need. Herein, we have identified serine and threonine protein phosphatase PPP6C as a negative regulator of MASH progression in mice and humans. PPP6C activity is increased by FGF21 via an autocrine effect mediated by FGFRs/βKlotho in hepatocytes. Pharmacological administration of FGF21 protects against MASH pathology at least in large through the interaction between βKlotho and PPP6C and PPP6C-mediated dephosphorylation of TSC2 in hepatocytes. This study implies that pharmacological approaches targeting PPP6C activity may offer attractive prospects for treating liver fibrosis and MASH.

Melanoma is one of the deadliest skin cancers and challenges clinicians worldwide due to rising incidence, potential aggressiveness, and propensity for metastasis, necessitating comprehensive follow-up programs after primary treatment. Circulating tumor DNA (ctDNA) is a promising biomarker that may indicate disease progression earlier than traditional surveillance methods, including 18F-FDG PET-CT, ultrasound, and clinical examination. This study examines ctDNA detection in blood as a minimally invasive method for early identification of progression following primary treatment of melanoma. The aim is to overcome the limitations of current methods, potentially improving prognosis and survival.

Patients with high risk of recurrence following primary treatment of melanoma are offered inclusion. Blood sampling is performed at each follow-up visit. In case of recurrence, patient-specific mutations are identified through next-generation sequencing (NGS) of formalin and paraffin embedded tissue from diagnostic routine. Detection of mutation-specific ctDNA is performed on blood using digital droplet polymerase chain reaction (ddPCR) or NGS. This allows determination of the value and sensitivity of ctDNA for early detection of recurrence.

For validation purposes, we conducted a small pilot study using blood samples from 10 patients who had experienced recurrence and had a clinically confirmed BRAF V600E mutation. Detection of BRAF V600E ctDNA using ddPCR varied from 0/5 (0%) in DNA harvested from 4 mL plasma, to 3/5 (60%) in DNA from 8 mL of plasma. These results show promise and highlight the importance of high sensitivity and sampling volumes to ensure accurate detection of low levels of ctDNA.

Bulky DNA adducts are mostly formed by external factors such as UV irradiation, smoking or treatment with DNA crosslinking agents. If such DNA adducts are not removed by nucleotide excision repair, they can lead to formation of driver mutations that contribute to cancer formation. Transcription factors (TFs) may critically affect both DNA adduct formation and repair efficiency at the binding site to DNA. For example, "hotspot" mutations in melanoma coincide with UV-induced accumulated cyclobutane pyrimidine dimer (CPD) adducts and/or inhibited repair at the binding sites of some TFs. Similarly, anticancer treatment with DNA cross-linkers may additionally generate DNA adducts leading to secondary mutations and the formation of malignant subclones. In addition, some TFs are overexpressed in response to UV irradiation or chemotherapeutic treatment, activating oncogenic and anti-oncogenic pathways independently of nucleotide excision repair itself. This review focuses on the interplay between TFs and nucleotide excision repair during cancer development and progression.

Cohesin, a crucial regulator of genome organisation, plays a fundamental role in maintaining chromatin architecture as well as gene expression. Among its subunits, STAG2 stands out because of its frequent deleterious mutations in various cancer types, such as bladder cancer and melanoma. Loss of STAG2 function leads to significant alterations in chromatin structure, disrupts transcriptional regulation, and impairs DNA repair pathways. In this review, we explore the molecular mechanisms underlying cohesin-STAG2 function, highlighting its roles in healthy cells and its contributions to cancer biology, showing how STAG2 dysfunction promotes tumourigenesis and presents opportunities for targeted therapeutic interventions.

Melanoma is the fifth most common cancer in the United States. The advent of immunotherapy and molecular targeted therapy has improved progression-free and overall survival in many patients with advanced disease. However, the selection of therapeutic choices requires a nuanced approach, especially when considering molecularly targeted agents. This case report highlights a diagnostic and therapeutic challenge in managing a patient with a history of chronic lymphocytic leukemia (CLL) and recurrent melanoma. Molecular testing suggested discordant BRAF V600E testing and a simultaneous NRAS G12D mutation. After a careful literature review, repetition of his molecular testing, and analysis of the timelines and results of all his molecular testing, we concluded that the BRAF V600E mutation result was falsely positive. The patient was treated with two cycles of ipilimumab (1 mg/kg) and nivolumab (3 mg/kg) as per the NADINA trial and had a complete radiographic response. He then underwent resection demonstrating a pathologic partial response ranging from 20% to 95% tumor necrosis, dependent on the satellite examined. This case report underscores the importance of precise molecular diagnostics in guiding melanoma treatment and demonstrates the complexities of managing a patient with a coexisting malignancy.

Overcoming therapy resistance is critical for effective melanoma control. Upregulation of Rho/MRTF signaling in human and mouse melanomas causes resistance to targeted therapies. Inhibition of this pathway by MRTFi, CCG-257081 resensitized resistant melanomas to BRAF and MEK inhibitors. It also prevented the development of resistance to vemurafenib (Vem). Here, we investigate the role of apoptosis and the protein pirin in CCG-257081-mediated suppression of drug resistance.

Using naïve and resistant mouse YUMMER melanoma cells, we studied the effect of the BRAF inhibitor Vem with or without CCG-257081 on real-time growth and apoptosis (activation of caspase, Propidium iodide (PI) staining, and PARP cleavage). The effects of CCG-257081 on proliferation (Ki67) and caspase-3 activation were assessed in resistant YUMMER_R tumors in vivo. Finally, two CCG-257081 enantiomers were tested for pirin binding, inhibition of the Rho/MRTF-mediated activation of ACTA2 gene expression in fibroblasts, and the prevention of Vem resistance development by YUMMER_P cells.

Vem reduced growth of parental but not resistant cells, while CCG-257081 inhibited both. The combination was more effective than Vem alone. CCG-257081, but not Vem, induced activation of caspase-3 and -7 in resistant cells and increased PARP cleavage and PI staining. CCG-257081 reduced proliferation and activated caspase-3 in YUMMER_R melanoma tumors. Both CCG-257081 enantiomers robustly suppressed development of Vem-resistant colonies with the S isomer being more potent (1 μM IC50).

CCG-257081 appears to target pre-resistant cells and Vem-induced resistant cells through enhanced apoptosis. Inhibition of pirin or the Rho/MRTF pathway can be employed to prevent melanoma resistance.

SMARCA2 is an attractive synthetic lethal target in human cancers with mutated, inactivated SMARCA4. We report herein the discovery of highly potent and selective SMARCA2 PROTAC degraders, as exemplified by SMD-3236, which was designed using a new, high-affinity SMARCA ligand and a potent VHL-1 ligand. SMD-3236 achieves DC50 < 1 nM and Dmax > 95% against SMARCA2 and >2000-fold degradation selectivity over SMARCA4. SMD-3236 potently inhibits cell growth in a panel of SMARCA4-deficient cell lines and displays minimal activity in SMARCA4 wild-type cell lines. SMD-3236 induces profound and persistent SMARCA2 depletion in tumor tissues for 1 week with a single administration, while sparing SMARCA4 protein. SMD-3236 effectively inhibits tumor growth with weekly administration in the H838 SMARCA4-deficient human cancer xenograft model at well-tolerated dose schedules. SMD-3236 represents a promising SMARCA2 degrader for extensive evaluation as a new therapy for the treatment of SMARCA4-deficient human cancers.

In the SWI/SNF chromatin-remodeling complex, the mutually exclusive catalytic ATPase subunits SMARCA2 and SMARCA4 proteins have a synthetic-lethal relationship. Selectively targeting SMARCA2 for degradation is a promising and new therapeutic strategy for human cancers harboring inactivated mutated SMARCA4. In this study, we report the design, synthesis, and biological evaluation of novel SMARCA2/4 ligands and our subsequent design of PROTAC degraders using high-affinity SMARCA ligands and VHL-1 ligands. Our efforts led to the discovery of high-affinity SMARCA2/4 bromodomain ligands and the development of a potent and selective SMARCA2 degrader and a highly potent SMARCA2/4 and PBRM1 degrader.

We describe the identification of selective SMARCA2, VHL-based heterobifunctional degraders. Structurally novel indolo[1,2-a]quinazolin-5(7H)-one SMARCA bromodomain binders were optimized and then converted to SMARCA2 degraders by linking them to well-defined VHL ligands. Our exploration led to the discovery of potent and selective degraders of SMARCA2 over the SMARCA4 paralog, leading to potent and selective growth inhibition of SMARCA4 mutant versus wild type cell lines. We further highlight the optimization of the pharmacokinetic profile of a subset of compounds leading to potent and selective degradation of SMARCA2 in the xenograft model. These compounds provide valuable tools with desirable properties for continued exploration of the biology defining the susceptibility of SMARCA4 mutant cancers to selective loss of SMARCA2.

Ponicidin has demonstrated effectiveness against HCC by promoting mitochondria apoptosis and generating ROS through the stabilization of the Keap1-PGAM5 complex. However, ROS can exhibit both tumor-promoting and tumor-suppressing activities in cancers, and exhibit different effects depending on its source-mtROS vs non-mtROS. Additionally, since ROS from different sources possesses distinct functions, mitochondria-targeted antioxidants, and non-targeted antioxidants may have entirely different effects on cancer progression. To address this complexity, novel measurement techniques such as MitoSOX, MitoPY1, and siDMA are used to specifically assess mtROS, providing deeper insights into mitochondrial function during treatment. Therefore, distinguishing the sources of ROS and separately detecting and targeting mtROS and non-mtROS can further clarify the anti-tumor mechanisms of ponicidin and provide a foundation for subsequent research.

Somatic driver mutations play important roles in cancer and must be precisely identified to advance our understanding of tumorigenesis and its promotion and progression. However, identifying somatic driver mutations remains challenging in Homo sapiens genomics due to the random nature of mutations and the high cost of qualitative experiments. Building on the powerful sequence interpretation capabilities of language models, we propose a self-attention-based contextualized pretrained language model for somatic driver mutation identification. We pretrained the model with the Homo sapiens reference genome to equip it with the ability to understand genome sequences and then fine-tuned it for oncogene and tumor suppressor gene prediction tasks, enabling it to extract features related to driver genes from the original genome sequence. The fine-tuned model was used to obtain the mutations' carcinogenic effect characteristics to further identify whether the mutation is a driver or a passenger. Compared with other computational algorithms, our method achieved excellent somatic driver mutation identification performance on the test set, with an absolute improvement of 4.31% in AUROC over the best comparison method. The strong performance of our method indicates that it can provide new insights into the discovery of cancer drivers.

This study aims to perform a comprehensive bibliometric analysis of global research on BRAF and MEK inhibitor resistance in melanoma, identifying key research trends, influential contributors, and emerging themes from 2003 to 2024.

A systematic search was conducted in the Web of Science Core Collection (WoSCC) database to retrieve publications related to BRAF and MEK inhibitor resistance from 1 January 2003, to 1 September 2024. Bibliometric analyses, including publication trends, citation networks, and keyword co-occurrence patterns, were performed using VOSviewer and CiteSpace. Collaborative networks, co-cited references, and keyword burst analyses were mapped to uncover shifts in research focus and global cooperation.

A total of 3,503 documents, including 2,781 research articles and 722 review papers, were analyzed, highlighting significant growth in this field. The United States, China, and Italy led in publication volume and citation impact, with Harvard University and the University of California System among the top contributing institutions. Research output showed three phases of growth, peaking in 2020. Keyword and co-citation analyses revealed a transition from early focus on BRAF mutations and MAPK pathway activation to recent emphasis on immunotherapy, combination therapies, and non-apoptotic cell death mechanisms like ferroptosis and pyroptosis. These trends reflect the evolving priorities and innovative approaches shaping the field of resistance to BRAF and MEK inhibitors in melanoma.

Research on BRAF and MEK inhibitor resistance has evolved significantly. This analysis provides a strategic framework for future investigations, guiding the development of innovative, multi-modal approaches to improve treatment outcomes for melanoma patients.

Melanoma is a serious type of skin cancer that originates from melanocytes. Rodent melanoma models have provided valuable insights into melanoma pathology; however, they often lack applicability to humans owing to genetic, anatomical, physiological, and metabolic differences. Herein, we developed a transgenic porcine melanoma model that closely resembles humans via somatic cell nuclear transfer (SCNT). Our model features the conditional oncogenes cassettes, TP53R167H and human BRAFV600E, controlled by melanocyte-specific CreER recombinase. After SCNT, transgenic embryos developed normally, with the capacity to develop porcine embryonic stem cells. Seven transgenic piglets with oncogene cassettes were born through embryo transfer. We demonstrated that Cre recombination-mediated oncogene activation remarkably triggered the mitogen-activated protein kinase pathway in vitro. Notably, intradermal injection of 4-hydroxytamoxifen activated oncogene cassettes in vivo, resulting in melanocytic lesions resembling hyperpigmented nevi with increased proliferative properties similar to early human melanomas. This melanoma-inducing system, heritably transmitted to offspring, supports large-scale studies. The novel porcine model provides a valuable tool for elucidating melanoma development and metastasis mechanism, advancing translational medicine, and facilitating preclinical evaluation of new anticancer drugs.

Cancer is a major cause of death worldwide. Next-generation sequencing (NGS) has dramatically increased the sequencing data output and transformed biomedical investigations. NGS enables the generations of genetic data specific to patients from tumor tissue samples so that targeted therapies can be used. The obtained data further allows the prioritization of effective therapies based on the tumor-specific genotype. Practitioners in the field of clinical genomics can make the best use of testing facilities while lessening the possible off-targets by choosing a priori gene set. Therefore, targeted sequencing has arisen as a more affordable technique for the genomic profiling of tumors. Drug resistance is commonly observed in cancer because of mutations. Thus, precise genetic and molecular profiling of tumors ought to be routinely done prior to the use of targeted therapy or precision cancer therapy. NGS already has the capacity to ameliorate genetic screening in families with previous histories of the high occurrence of various cancer-associated genes, including TP53, APC, BRCA2, and BRCA1. By using NGS system, researchers detected increased variants in cancer cells with greater specificity and sensitivity than conventional diagnostic approaches, which suggest the potential of NGS in diagnosis. The field of precision cancer therapy is continuously growing and because of their specificity at the molecular level has improved the management and treatment of numerous cancers. These therapies are less toxic and more efficient compared to conventional chemotherapies used in cancer treatment. The field of precision cancer therapy is likely to significantly expand as NGS system advances. This review provides extensive information regarding current advances in the NGS field in terms of methods, clinical applications, genomic profiling, and the role of NGS of precision cancer therapy.

MAP2K1/MEK1 mutations are potentially actionable drivers in cancer. MAP2K1 mutations have been functionally classified into three groups according to their dependency on upstream RAS/RAF signaling. However, the clinical efficacy of mitogen-activated protein kinase (MAPK) pathway inhibitors (MAPKi) for MAP2K1-mutant tumors is not well defined. We sought to characterize the genomic and clinical landscape of MAP2K1 mutant tumors to evaluate the relationship between MAP2K1 mutation class and clinical activity of MAPKi.

We interrogated American Association for Cancer Research (AACR) GENIE (v13) to analyze solid tumors with MAP2K1 mutations. We performed a systematic review and meta-analysis of published reports of patients with MAP2K1-mutant cancers treated with MAPKi according to Preferred Reporting Items for Systematic Reviews and Meta-Analyses guidelines. The primary end point was progression-free survival (PFS), and secondary end points were overall treatment response rate (ORR), duration of response (DOR), and overall survival.

In the AACR GENIE data set, class 2 MAP2K1 mutations (63%) were more prevalent than class 1 (24%) and class 3 (13%) mutations (P < .0001). Co-occurring MAPK pathway-activating mutations were more likely to occur in class 1 versus class 2 or 3 MAP2K1-mutant tumors (P < .0001). Our systematic meta-analysis of the literature identified 46 patients with MAP2K1-mutant tumors who received MAPKi. In these patients, ORR was 28% and median PFS was 3.9 months. ORR did not differ according to MAP2K1 mutation class or cancer type. However, patients with class 2 mutations experienced longer PFS (5.0 months) and DOR (23.8 months) compared with patients with class 1, 3, or unclassified MAP2K1 mutations (PFS 3.5 months, P = .04; DOR 4.2 months, P = .02).

Patients with class 2 MAP2K1 mutations represent a novel subgroup that may derive benefit from MAPKi. Prospective clinical studies with novel MAPKi regimens are warranted in these patients.