Search Results (630)

Stress granule formation is a type of liquid–liquid phase separation in the cytoplasm, leading to RNA–protein condensates that are associated with various cellular stress responses and implicated in numerous pathologies, including cancer, neurodegeneration, inflammation, and cellular senescence. One of the key components of mammalian stress granules is the DEAD-box RNA helicase DDX3, which unwinds RNA in an ATP-dependent manner. DDX3 is involved in multiple steps of RNA metabolism, facilitating gene transcription, splicing, and nuclear export and regulating cytoplasmic translation. In this study, we investigate the role of the RNA helicase DDX3’s enzymatic activity in shaping the RNA content of ribonucleoprotein (RNP) condensates formed during arsenite-induced stress by inhibiting DDX3 activity with RK-33, a small molecule previously shown to be effective in cancer clinical studies. Using the human osteosarcoma U2OS cell line, we purified the RNP granule fraction and performed RNA sequencing to assess changes in the RNA pool. Our results reveal that RK-33 treatment alters the composition of non-coding RNAs within the RNP granule fraction. We observed a DDX3-dependent increase in circular RNA (circRNA) content and alterations in the granule-associated intronic RNAs, suggesting a novel role for DDX3 in regulating the cytoplasmic redistribution of non-coding RNAs. Full article

The ataxia–telangiectasia-mutated (ATM) protein plays a crucial role in the DNA damage response, particularly in the homologous recombination (HR) pathway. This study aimed to assess the impact of deleterious ATM variants on homologous recombination deficiency (HRD) and response to PARP inhibitors (PARPi) in melanoma patients, using a cell line established from melanoma tissue of a patient carrying the c.5979_5983del germline ATM variant. Despite proven loss of heterozygosity, lack of ATM activation, and HRD, our model did not show sensitivity to PARPi. We assessed the potential contribution of the Schlafen family member 11 (SLFN11) helicase, whose expression is inversely correlated with PARPi sensitivity in other cancers, to the observed resistance. The ATM mutant cell line lacked SLFN11 expression and featured hypermethylation-mediated silencing of the SLFN11 promoter. While sensitive to the ATR inhibitor (ATRi), the addition of ATRi to PARPi was unable to overcome the resistance. Our findings suggest that ATM mutational status and HRD alone do not adequately account for variations in sensitivity to PARPi in our model. A comprehensive approach is essential for optimizing the exploitation of DNA repair defects and ultimately improving clinical outcomes for melanoma patients. Full article

Epigenetic modifications are heritable, reversible alterations that causally reshape chromatin architecture and thereby influence DNA repair without changing nucleotide sequence. DNA methylation, histone modifications and non-coding RNAs profoundly influence DNA repair mechanisms and genomic stability. Aberrant epigenetic patterns in cancer compromise DNA damage recognition and repair, therefore impairing homologous recombination (HR), non-homologous end joining (NHEJ), and base excision repair (BER) by suppressing key repair genes and lowering access to repair sites. Then it is dissected how loss-of-function mutations in Switch/Sucrose non-fermentable, imitation switch and CHD (Chromodomain helicase DNA-binding) chromatin-remodeling complexes impair nucleosome repositioning, preventing effective damage sensing and assembly of repair machinery. Non-coding RNAs contribute to epigenetic silencing at DNA break sites, exacerbating repair deficiencies. This review evaluates recent advances concerning epigenetic dysfunction and DNA repair impairment. It is also highlighted that nanoparticle-mediated delivery strategies are designed to overcome pharmacologic resistance. It is presented how epigenetic dysregulation of DNA repair can guide more effective and drug-resistant cancer therapies. Full article

WRN helicases play a key role in DNA replication, repair, and other processes in a variety of tumors. It has become one of the hot targets of genotoxic drugs, but the effect and mechanism of targeting WRN against prostate cancer is still unclear. In our previous study, we found a quinazoline compound kzl052, which has a WRN-dependent inhibitory effect on prostate cancer cells, but its molecular mechanism needs to be further explored. In this study, kzl052 significantly inhibited the growth of PC3 (IC₅₀ = 0.39 ± 0.01 μM) and LNCaP (IC₅₀ = 0.11 ± 0.01 μM) cells in vitro and showed a good inhibition effect on PCa in vivo. It inhibits PC3 cell growth by binding to WRN proteins and affecting its non-enzymatic function. Then the mechanism of kzl052 against prostate cancer progression was revealed to be by regulating the stability of DNA replication forks and the RB pathway. This study will provide a theoretical basis and treatment strategy for targeting WRN helicase in the treatment of prostate cancer. Full article

Tetrahelical DNA structures, such as G-quadruplexes (G4s) or i-motifs (iMs), are adopted by sequences comprising several G/C tracts, exist in equilibria with respective duplexes, and may contribute to genomic instability upon helicase deficiency. To understand genomic rearrangements resulting from the juxtaposition of G/C-rich DNA duplexes, models of possible intermediate structures are needed. In this study, a general strategy for creating and verifying in silico 3D models of tetrahelical DNA was proposed. This strategy was used to investigate contacts of two or more duplexes with n G₃/C₃ tracts (n = 2–6) separated by T/A nucleotides. The revealed viable structures of DNA–DNA contacts include stacks of right-handed and left-handed G-quadruplexes (G4s), Holliday structure-resembling assemblies with the G4 and iM opposite each other on the borders of the central “hole”, etc. Based on molecular dynamic simulations, the most probable variants were determined by estimating the contributions to the free energy. The results may be used to clarify the mechanisms of strand exchange and other rearrangements upon DNA breaks near prolonged G/C-rich sites in living systems. Additionally, they provide a balanced view on the polymorphic versus programmed DNA assemblies in artificial systems. Full article

To address the issue of aflatoxin contamination, which poses a significant threat to food safety and human health, we have conducted extensive research. We have isolated a strain of Myroides odoratimimus (3J2MO) from the soil that exhibited remarkable efficiency in degrading various aflatoxin types, including AFB1, AFB2, AFG1, AFG2, and AFM1. SDS-PAGE analysis confirmed the purity of the enzymes to be over 95%. Through fluorescence assays, we quantified the enzymatic activity, with an AFB1 degradation rate of 95% achieved at 37 °C and a pH of 8.0. Further analysis using HPLC-MS/MS identified the degradation intermediates, revealing the mechanisms of lactone ring cleavage and epoxy group hydrolysis. GO/COG/KEGG annotations provided insights into the functions of these enzymes, with peroxidase linked to reactive oxygen species (ROS) generation and helicase associated with ATP-dependent conformational changes. Helicase, on the other hand, hydrolyzes ATP, driving conformational changes in AFB1 and facilitating its breakdown into non-toxic metabolites. The potential industrial-scale application of this discovery could significantly mitigate aflatoxin-related economic losses while minimizing chemical residues in the food chain. Full article

The rapid global expansion of Aedes aegypti-borne diseases such as dengue, chikungunya, and Zika has positioned this mosquito as a key target for vector control programs. These programs rely heavily on insecticide use, leading to the widespread emergence of insecticide resistance. Understanding the molecular basis of resistance is essential for developing effective management strategies. In this study, we employed a whole-transcriptome (RNA-seq) approach to analyze gene expression in three Ae. aegypti populations from Mexico that underwent four generations of laboratory selection with deltamethrin. Several cytochrome P450 genes (CYP6AG4, CYP6M5, CYP307A1) and a chitin-binding peritrophin-like gene (Ae-Aper50) were significantly overexpressed following selection, supporting roles for both detoxification and midgut protection. We also observed a consistent downregulation of cuticular protein genes in deltamethrin-selected groups relative to the baseline populations, suggesting their involvement in baseline tolerance rather than induced resistance. Additionally, the overexpression of immune- and stress-related genes, including the RNA helicase MOV-10, indicates that insecticide selection may trigger broader physiological responses. These findings highlight complex, multi-pathway transcriptomic changes associated with resistance development in Ae. aegypti. Full article

Acute Myeloid Leukemia (LAML) is a life-threatening hematological malignancy, and the DEAD-box helicase 3 X-linked (DDX3X) gene is a potential yet underexplored target gene for LAML. Biomolecules derived from medicinal plants like Aerva javanica offer a great source of therapeutic candidates. This study aimed to investigate the role of DDX3X in LAML and identify plant-derived biomolecules that could inhibit DDX3X using computational approaches. Pan-cancer mutational profiling, a transcriptomic analysis, survival, protein–protein interaction networks, and a principal component analysis (PCA) were employed to elucidate functional associations and transcriptomic divergence. Subsequently, biomolecules from A. javanica were subjected to in silico screening using molecular docking and ADMET profiling. The docking protocol was validated using RK-33, a known DDX3X inhibitor. DDX3X was found to be linked to key leukemogenic pathways, including Wnt/β-catenin and MAPK signaling, indicating it to be a potential target. Molecular docking of A. javanica compounds revealed CIDs 15559724, 5490003, and 74819331 as potent DDX3X inhibitors with strong binding affinity and favorable pharmacokinetic and toxicity profiles compared to RK-33. This study highlights the importance of DDX3X in LAML pathogenesis and suggests targeting it using plant-derived inhibitors, which may require further in vitro and in vivo validation. Full article

The maintenance of genome stability requires the coordinated actions of multiple proteins and protein complexes. One critical family of proteins is the recombination mediators. Their role is to facilitate the formation of recombinase nucleoprotein filaments on single-stranded DNA (ssDNA). Filament formation can take place on post-replicative ssDNA gaps as well as on 3′-tailed duplexes resulting from helicase–nuclease processing. In prokaryotes, the RecF, O, and R proteins are widely distributed and mediate RecA loading as either the RecFOR or RecOR complexes, depending on the species being studied. In this review, I compare and contrast the available biochemical and structural information to provide insight into the mechanism of action of this critical family of mediators. Full article

Background: The 2C protein of foot-and-mouth disease virus (FMDV), a member of helicase superfamily 3 (SF3), drives viral genome replication and serves as a critical target for antiviral drug development. Methods: A fluorescence resonance energy transfer (FRET)-based high-throughput screening (HTS) platform was developed to identify 2C helicase inhibitors. Primary screening evaluated 4424 compounds for helicase inhibition. Molecular docking analyzed inhibitor interactions with the N207 residue within the catalytic core and helicase inhibition assays classified the inhibitor type (mixed, competitive, noncompetitive). Differential scanning fluorimetry (nanoDSF) quantified 2C thermal destabilization. Antiviral activity was assessed via indirect immunofluorescence, RT-qPCR, and plaque reduction assays. Results: Six compounds inhibited 2C helicase activity at >620 μM. Molecular docking revealed hydrogen bonding, hydrophobic interactions, and π-cation stabilization at the catalytic core. 2-MPO and MPPI were classified as mixed-type inhibitors, 5-TzS⁻ and 2-PyOH as competitive, and DCMQ/Spiro-BD-CHD-dione as noncompetitive. NanoDSF showed a ΔT_m ≥ 1.5 °C (2.5 mM compounds), with reduced destabilization in N207A mutants. Antiviral assays identified 2-MPO and MPPI as optimal inhibitors. MPPI achieved effective FMDV suppression at 160 μM, exhibiting two orders of magnitude higher potency than 2-MPO (400 μM). Conclusions: The established FRET-based HTS platform targeting 2C helicase facilitates anti-FMDV lead discovery, while 2C inhibitors may serve as an effective therapeutic strategy against other picornaviruses. Full article

Background: The accurate determination of bird sex is crucial in various biological fields, including ecology, behavioral research, and conservation. However, this task remains challenging in species in which males and females exhibit similar external morphologies, such as owls. Although polymerase chain reaction (PCR)-based molecular sexing techniques that target the chromodomain helicase DNA-binding protein 1 gene found on sex chromosomes Z (CHD1-Z gene) and W (CHD1-W gene) are widely used, we encountered atypical banding patterns when applying the previously reported primers 2550F and 2718R to four wild owls of unknown sex. This study aims to reveal the owl-specific genetic structure of the CHD1 gene. Methods: We developed a new primer set and determined the nucleotide sequences—including the binding sites for the primers 2550F and 2718R—within both the CHD1-Z and CHD1-W genes. Results: Sequencing analysis, conducted using a newly developed primer set that successfully amplified both Z- and W-derived CHD1 products across various owl species, revealed a unique genetic insertion of approximately 600 bp in intron 17 of the CHD1-W gene. This insertion reversed the usual length relationship between PCR products from the chromosomes Z and W. Additionally, mutations identified in the 2550F primer binding site of the CHD1-Z gene in certain owl species may explain the failure to amplify CHD1-Z-derived PCR products. Conclusion: These findings provide valuable insights for improving molecular sexing in owls. Full article

Long interspersed element-1 (LINE-1) is the only active autonomous transposon comprising about 17% of human genomes. LINE-1 transposition can cause the mutation and rearrangement of the host’s genomic DNA. The host has, therefore, developed multiple mechanisms to restrict LINE-1 mobility. Here, we report that SLFN11, a member of the Schlafen family, can restrict LINE-1 retrotransposition, and the inhibitory activity requires its helicase domain. Mechanistically, SLFN11 specifically binds to the LINE-1 5′ untranslated region (5′UTR) and blocks RNA polymerase II recruitment, thereby suppressing its transcription. Furthermore, SLFN11 promotes heterochromatinization, suggesting an epigenetic inhibition pathway. Full article

Background/Objectives: DDX41, DEAD-box RNA helicase 41 gene located on chromosome 5q25.3, is one of the most mutated genes in patients with germline predisposition to myeloid neoplasms. Germline and somatic mutations often have different locations and patterns of mutation, with some hotspots displaying diversity based on ethnicity. We aimed to explore clinical outcomes in patients with various DDX41 hot-spot mutations. Methods: This was a retrospective study of patients at Mayo Clinic with DDX41 mutation identified through Next Generation Sequencing (NGS) between 2018 and 2024. We completed unadjusted comparisons using continuous or categorical variables, and survival rates were assessed using the Kaplan–Meier method and cox regression analysis. Results: Overall survival appears to be higher in those with p.M1| when compared to p.Asp140GlyFs*2 and p.Arg525His, with comparable survival between p.Arg525His and p.Asp140GlyFs*2. Among males with p.M1| who underwent bone marrow transplant, those who underwent bone marrow transplant appeared to have lower survival rates, although not statistically significant. Our study was limited by a small sample size, therefore limiting our ability to reach significance. Conclusions: Our findings suggest potential implications for clinical outcomes based on DDX41 mutation hot-spots. Full article

Salt stress is one of the most prominent abiotic stresses. Behind the intricate adaptive responses of plants to salt stress, the regulation of gene expression assumes a pivotal role. Complementing transcriptional mechanisms, post-transcriptional regulation performed by RNA-binding proteins provides an additional layer of control through sophisticated molecular machinery. RBPs interact with both RNA molecules and protein partners to coordinate RNA metabolism and, thus, fine-tune the expression of salt-responsive genes, enabling plants to rapidly adapt to ionic challenges. This review systematically evaluates the functional roles of RBPs localized in distinct subcellular compartments, including nuclear, cytoplasmic, chloroplastic, and mitochondrial systems, in mediating post-transcriptional regulatory networks under salinity challenges. Specific classes of RBPs are discussed in detail, including glycine-rich RNA-binding proteins (GR-RBPs), serine/arginine-rich splicing factors (SR proteins), zinc finger domain-containing proteins, DEAD-box RNA helicases (DBRHs), KH domain-containing proteins, Pumilio domain-containing proteins (PUMs), pentatricopeptide repeat proteins (PPRs), and RBPs involved in cytoplasmic RNA granule formation. By integrating their subcellular localization and current mechanistic insights, this review concludes by summarizing the current knowledge and highlighting potential future research directions, aiming to inspire further investigations into the complex network of RBPs in modulating plant responses to salt stress and facilitating the development of strategies to enhance plant salt tolerance. Full article

Human papillomaviruses (HPVs) are small double-stranded DNA viruses that infect epithelial cells and cause cervical, anogenital, and oropharyngeal cancers. HPV genome replication relies on the viral E1 and E2 proteins to initiate DNA replication. The first step is the assembly of the E1-E2 complex at the origin of replication. We have examined the role of full-length HPV E1 helicase and its interaction with E2 in pre-initiation complex formation. Electrophoretic mobility shift assays (EMSAs) with purified E1 and E2 proteins revealed that the HPV genome does not have a specific E1 binding site, or such a sequence is not required for pre-initiation complex formation. E1 alone did not show any binding to the origin DNA sequences, while E2 facilitated E1 recruitment to the origin, forming the E1-E2-DNA ternary complex. Formation of such a complex required at least two E2 binding sites. These findings led us to propose a novel mechanism in which E2 dimers serve as the primary recruiters of E1 to form the pre-initiation complex. This study provides new insights into the mechanistic role of E2 in the recruitment of E1 at the origin of HPV DNA replication, enhancing our understanding of HPV biology and potentially informing future therapeutic strategies. Full article