Search Results (229)

Per- and polyfluoroalkyl substances (PFAS) are persistent environmental pollutants that continue to raise concern owing to their ability to accumulate in living organisms. In recent years, a growing body of research has shown that PFAS can exert their toxicity through disruption of both DNA integrity and epigenetic regulation. This includes changes in DNA methylation patterns, histone modifications, chromatin remodeling, and interference with DNA repair mechanisms. These molecular-level alterations can impair transcriptional regulation and cellular homeostasis, contributing to genomic instability and long-term biological dysfunction. In neural systems, PFAS exposure appears particularly concerning. It affects key regulators of neurodevelopment, such as BDNF, synaptic plasticity genes, and inflammatory mediators. Importantly, epigenetic dysregulation extends to non-coding RNAs (ncRNAs), including microRNAs (miRNAs) and long non-coding RNAs (lncRNAs), which mediate post-transcriptional silencing and chromatin remodeling. Although direct evidence of transgenerational neurotoxicity is still emerging, animal studies provide compelling hints. Persistent changes in germline epigenetic profiles and transcriptomic alterations suggest that developmental reprogramming might be heritable by future generations. Additionally, PFAS modulate nuclear receptor signaling (e.g., PPARγ), further linking environmental cues to chromatin-level gene regulation. Altogether, these findings underscore a mechanistic framework in which PFAS disrupt neural development and cognitive function via conserved epigenetic and genotoxic mechanisms. Understanding how these upstream alterations affect long-term neurodevelopmental and neurobehavioral outcomes is critical for improving risk assessment and guiding future interventions. This review underscores the need for integrative research on PFAS-induced chromatin disruptions, particularly across developmental stages, and their potential to impact future generations. Full article

Wharton’s jelly mesenchymal stem cells (WJ-SCs) are a promising source for regenerative medicine due to their multipotency, low immunogenicity, and ethical acceptability. Epigenetic regulation plays a crucial role in modulating their proliferation, differentiation, and therapeutic potential. Key mechanisms, including DNA methylation, histone modifications, and non-coding RNAs (e.g., miRNAs and lncRNAs), influence WJ-SC behavior by dynamically altering gene expression without changing the DNA sequence. DNA methylation often silences genes involved in differentiation, while histone acetylation/methylation can activate or repress lineage-specific pathways. Non-coding RNAs further fine-tune these processes by post-transcriptional regulation. Understanding these mechanisms could optimize WJ-SC-based therapies for tissue repair and immune modulation. This review summarizes current insights into epigenetic regulation in WJ-SCs and its implications for regenerative applications. Full article

Tomato yellow leaf curl virus (TYLCV) is a highly destructive pathogen of global tomato crops. The open reading frame (ORF) of TYLCV V2 contains two initiation codons (ATG1/V2-1 and ATG2/V2-2), producing distinct protein isoforms. Using custom antibodies, we confirmed V2-1 and V2-2 expression in infected Nicotiana benthamiana and tomato plants. Deletion mutants revealed their specialized roles: V2-1 was indispensable for viral replication and systemic spread—its loss severely reduced pathogenicity and genome accumulation. V2-2 acted as an auxiliary factor, and its deletion attenuated symptoms but kept the virus infection. Host-specific effects were observed—V2-1 deletion led to lower viral DNA/coat protein levels in N. benthamiana than in tomato, suggesting host-dependent regulation. Mutant viruses declined progressively in tomato, indicating host defense clearance. Heterologous co-expression of both isoforms via potato virus X induced systemic necrosis in N. benthamiana, demonstrating functional synergy between isoforms. Both initiation codons were essential for V2-mediated suppression of transcriptional gene silencing (TGS) and post-transcriptional gene silencing (PTGS). This study uncovers the mechanistic divergence of V2 isoforms in TYLCV infection, highlighting their collaborative roles in virulence and host manipulation. The findings advance understanding of geminivirus coding complexity and offer potential targets for resistance strategies. Full article

Chronic pain is a multifactorial and complex condition that significantly affects individuals’ quality of life. The underlying mechanisms of chronic pain involve complex alterations in neural circuits, gene expression, and cellular signaling pathways. Recently, ncRNAs, such as miRNAs, lncRNAs, circRNAs, and siRNAs, have been identified as crucial regulators in the pathophysiology of chronic pain. These ncRNAs modulate gene expression at both the transcriptional and post-transcriptional levels, affecting pain-related pathways like inflammation, neuronal plasticity, and sensory processing. miRNAs have been shown to control genes involved in pain perception and nociceptive signaling, while lncRNAs interact with chromatin remodeling factors and transcription factors to modify pain-related gene expression. CircRNAs act as sponges for miRNAs, thereby influencing pain mechanisms. siRNAs, recognized for their gene-silencing capabilities, also participate in regulating the expression of pain-related genes. This review examines the diverse roles of ncRNAs in chronic pain, emphasizing their potential as biomarkers for pain assessment and as targets for novel therapeutic strategies. A profound understanding of the ncRNA-mediated regulatory networks involved in chronic pain could result in more effective and personalized pain management solutions. Full article

Serine/arginine splicing factors (SRSFs) are critical regulators of gene expression that influence alternative splicing through RNA binding via the RNA recognition motif (RRM). Circular RNAs (circRNAs) are a subset of non-coding RNAs that exhibit differential expression in WSSV-infected Litopenaeus vannamei. This study investigates the role of LvSRSF2 in regulating circRNA expression in response to WSSV infection. LvSRSF2 was highly expressed in hemocytes and upregulated during WSSV infection. Silencing LvSRSF2 using dsRNA significantly upregulated the expression of circRNAs (circ-Alpha2, circ-Anillin, circ-Hemocytin, circ-Nephrin, and circ-Toll) in both WSSV-infected and uninfected shrimps at 72 h post-injection with dsRNAs. Knockdown of LvSRSF2 also significantly reduced WSSV copy numbers at 24 h post-infection and extended shrimp survival, with knockdown shrimp surviving up to 9 d compared to the control group. In addition, circ-Hemocytin, an SRSF2-related circRNA, was predicted to interact with six miRNAs targeting immune-related genes such as Toll, STAT, NF-κB, and Vago4. Following WSSV infection, circ-Hemocytin expression increased at 24 and 48 hpi, and the immune genes STAT and Vago4 were also upregulated, suggesting a potential circRNA–miRNA–mRNA regulatory axis in shrimp antiviral defense. Furthermore, targeted suppression of circ-Hemocytin expression using siRNAs significantly reduced its expression without affecting the corresponding linear transcript and resulted in a notable decrease in WSSV load in shrimp gills, highlighting its potential role in antiviral defense. Full article

Epigenetics and genome science have become central to current molecular biology research. Among the key mechanisms ensuring genomic integrity is the silencing of transposable elements in germline cells, a process essential for fertility in both sexes. A pivotal component of this silencing machinery involves PIWI-interacting RNAs (piRNAs), a distinct class of small non-coding RNAs that regulate gene expression and suppress transposable elements at both the transcriptional and post-transcriptional levels. piRNAs function in concert with PIWI proteins, whose expression is critical for proper oogenesis, spermatogenesis, and early zygote development. Disruptions in piRNA or PIWI protein pathways not only impair germline function but also contribute to genome instability, unchecked cell proliferation, and aberrant epigenetic modifications, hallmarks of tumorigenesis. Emerging evidence links the dysregulation of the piRNA/PIWI axis to the development and progression of various cancers, including lung and colorectal carcinomas. This review highlights the fundamental roles of piRNAs and PIWI proteins in reproductive biology and their increasingly recognized relevance in cancer biology. Full article

In eukaryotes, a lot of proteins are transported across the endoplasmic reticulum by the heterotrimeric Sec61 channel. And post-translational transport needs another Sec62/Sec63 complex. However, functions of these genes are poorly explored in insects. In this study, we first identified five Sec genes, named Sec61α, Sec61β, Sec61γ, Sec62 and Sec63, in Locusta migratoria. Quantitative reverse-transcription polymerase chain reaction (RT-qPCR) analysis showed that these five genes were expressed in muti-tissues, including wing pad, leg, foregut, midgut, gastric cecum, hindgut, and highly expressed in the integument. Knockdown of LmSec61α and LmSec61γ by RNA interference (RNAi) lead to the feeding cessation with a mortality rate of 100%. However, there is only 13.4% of dsLmSec61β-injected nymphs died before molting. All nymphs injected with dsLmSec61α and dsLmSec61γ died before molting with the gut atrophy. Furthermore, hematoxylin–eosin staining indicated that the cells of the midguts and gastric caecum were defective, and the microvilli and peritrophic matrix were destroyed seriously after silencing LmSec61α and LmSec61γ. Knockdown of LmSec62 and LmSec63 resulted in high mortality before and during molting. The hematoxylin–eosin (HE) staining and transmission electron microscopy (TEM) results showed that both the formation of the new cuticle and the degradation of the old cuticle were inhibited in dsLmSec63-injected insects compared to the controls. Especially, there was no obvious plaques on microvillar tips of the epidermal cells after silencing of LmSec63. These results revealed that Sec61s and Sec62/Sec63 genes are required in the gut and cuticle development of locusts. Therefore, these genes are potential targets for the control of locusts. Full article

In Argentina, various studies have reported the detection of multiple viruses in honey-producing and queen-rearing apiaries, with Aparavirus apisacutum, the causal agent of acute bee paralysis (ABP), demonstrating a particularly high prevalence. The potential of RNA interference (RNAi) as a strategy to control honey bee viruses has been explored, with initial findings indicating that RNAi could aid in mitigating the economic losses associated with viral infections. This study aimed to evaluate the effect of RNAi technology mediated by double-stranded RNA (dsRNA) on the dynamics of ABPV infection in adult honey bees. Fragments of the ABPV replicase and VP1 genes were used as templates for dsRNA synthesis via in vitro transcription. A gene silencing experiment was conducted through oral administration using five treatments: control, specific dsRNA + Virus, Virus alone, specific dsRNA alone, and non-specific dsRNA + virus. Bee survival was recorded over 10 days for all treatments, and samples were subsequently processed for viral quantification using quantitative real-time PCR. The oral administration of specific dsRNA reduced the viral replication curve, decreased the average viral loads and increased bee survival. This is the first report demonstrating the reduction in ABPV infection in adult honey bees through post-transcriptional gene silencing achieved via oral administration of dsRNA. Full article

Human papillomavirus type 16 (HPV16) is an etiological agent of human cancers that requires endocytosis to initiate infection. HPV16 entry into epithelial cells occurs through a non-canonical endocytic pathway that is actin-driven, but it is not well understood how HPV16–cell surface interactions trigger actin reorganization in a way that facilitates entry. This study provides evidence that Wiskott–Aldrich syndrome protein family verprolin-homologous proteins 1 and 2 (WAVE1 and WAVE2) are molecular mediators of actin protrusions that occur at the cellular surface upon HPV addition to cells, and that this stimulation is a key step prior to endocytosis and intracellular trafficking. We demonstrate through post-transcriptional gene silencing and genome editing that WAVE1 and WAVE2 are critical for efficient HPV16 infection, and that restoration of each in knockout cells rescues HPV16 infection. Cells lacking WAVE1, WAVE2, or both internalize HPV16 at a significantly reduced rate. Microscopic analysis of fluorescently labeled cells revealed that HPV16, WAVE1, WAVE2, and actin are all colocalized at the cellular dorsal surface within a timeframe that precedes endocytosis. Within that same timeframe, we also found that HPV16-treated cells express cellular dorsal surface filopodia, which does not occur in cells lacking WAVE1 and WAVE2. Taken together, this study provides evidence that WAVE1 and WAVE2 mediate a key step prior to HPV entry into cells that involves actin reorganization in the form of cellular dorsal surface protrusions. Full article

Metabolic diseases, including cardiovascular diseases, type 2 diabetes mellitus (T2DM), osteoporosis, and non-alcoholic fatty liver disease (NAFLD), constitute a major global health burden associated with chronic morbidity and mortality. Lactate, once considered as a metabolic byproduct, has emerged as a key regulator of cellular reprogramming through lactylation, a novel post-translational modification (PTM) that dynamically couples metabolic flux to chromatin remodeling. Lactylation exerts dual regulatory roles as a signaling molecule via GPR81/GPR4-mediated pathways and as a substrate for the covalent modification of histones and metabolic enzymes. Pathologically, chronic hyperlactatemia suppresses mitochondrial biogenesis, driving metabolic cardiomyopathy through the epigenetic silencing of oxidative metabolism genes. Conversely, exercise-induced lactate surges transiently enhance insulin sensitivity via AMPK/PGC-1α/GLUT4 signaling, resolve inflammation through GPR81-mediated M2 macrophage polarization, and restore mitochondrial function via lactylation-dependent pathways. This review delineates lactylation as a spatiotemporal rheostat: chronic dysregulation perpetuates metabolic disorders, whereas acute exercise-mediated lactylation remodels transcriptional networks to restore metabolic homeostasis. Future research should integrate multiomics to clarify lactylation’s spatiotemporal dynamics, tissue-specific thresholds, metabolism–immunity interactions, and metabolic–epigenetic crosstalk for the precision management of metabolic diseases. Full article

Small interfering RNA (siRNA) has been deemed a promising therapeutic method for treating diverse diseases. siRNA-based therapeutics provide a distinct mechanism of action by selectively targeting and silencing disease-causing genes at the post-transcriptional level. This paper provides an overview of the present state of siRNA-based therapeutics, highlighting their potential in different therapeutic areas. The first section of this review introduces the basic principles of siRNA technology, including its mechanism of action and delivery methods. Subsequently, we discuss the impediments associated with siRNA delivery and manufacturing development and the strategies for overcoming these obstacles. The clinical advancement of siRNA therapeutics in various disease areas, including cancer, genetic disorders, viral infections, and inflammatory diseases, is summarized. Lastly, we summarize the successes, failures, and lessons learned from the development of siRNAs. With advancements in delivery systems and improvements in target selection, the field of medicine can be revolutionized, and siRNA therapeutics can offer new treatment options for patients. Full article

The Squamosa promoter-binding protein-like (SPL) family proteins plays pivotal roles in plant development and stress adaptation. In this study, we functionally characterized MaSPL8 in mulberry (Morus alba) and investigated its regulatory roles in biotic and abiotic stress responses. MaSPL8 encodes a 364-amino acid protein with a conserved SBP domain and lacks miR156/157 binding sites. Phylogenetic analysis confirmed its orthology to Arabidopsis AtSPL8, albeit with functional divergence. Downregulation of MaSPL8 via virus-induced gene silencing (VIGS) resulted in more susceptibility to Ciboria shiraiana infection, but significantly enhanced resistance to drought and salt stress, as evidenced by reduced oxidative damage, elevated proline accumulation, and increased antioxidant enzyme activities. Transcriptomic profiling of MaSPL8-silenced plants revealed enrichment of differentially expressed genes (DEGs) in brassinosteroid biosynthesis, jasmonic acid metabolism, and oxidative stress responses, suggesting hormone signaling interplay. Furthermore, bioinformatic predictions identified miR5658 and miR4221 as potential post-transcriptional regulators of MaSPL8. This study highlights MaSPL8 as a negative regulator of abiotic stress tolerance and positive regulator of biotic (C. shiraiana) stress tolerance in mulberry and provides insights into its integration with phytohormone pathways. Our findings underscore the evolutionary plasticity of SPL8 genes and propose MaSPL8 as a target for enhancing mulberry’s resilience in challenging environments. Full article

Garden dahlias (Dahlia pinnata) are popular for their rich flower color variations that have produced many typical bicolor cultivars. Previous studies on the anthocyanin biosynthetic pathway (ABP) observed that the miR156-SPL9 module contributes to the formation of white tips on dahlia petals by repressing the MYB-bHLH-WDR complex. In this study, we further detected the potential post-transcriptional regulation involved in the bicolor petal formation by the small RNA sequencing of red bases and white tips. Compared with red bases, 89 differentially expressed miRNAs and 6349 target genes were identified. And 78 up-regulated miRNAs with their 249 down-regulated target genes were involved in the formation process of white petal tips. The target genes of differentially expressed miRNAs significantly enriched in the ABPs and miRNAs of six conserved families (MIR 156, 164, 167, 169, 482 and 6114) targeted to four transcription factor families (ARF, HD-ZIP, SBP and NAC) were involved in the post-transcriptional gene silencing (PTGS) of the ABP. Transcription sequencing and quantitative reverse transcription PCR analysis demonstrated that the MIR167-ARF8 module and the MIR6114-ANL2 module were the candidate regulators of the inactive ABP in the white tips by depressing the transcription of multiple structure genes. The findings gave new insights into the post-transcriptional regulation of the ABP and would be valuable for further studies of the PTGS mechanisms of bicolor petal formation. Full article

Pepper golden mosaic virus (PepGMV) is a bipartite begomovirus of pepper and tomato from North America. In ‘Anaheim’ pepper plants PepGMV-Mo strain (Mo) causes systemic yellow foliar mosaic symptoms, while PepGMV-D strain (D) causes distortion of 1st–6th expanding leaves, and asymptomatic infection of subsequently developing leaves, like other known ‘recovery’ phenotypes. Infections established with DNA-A Mo and D components expressing red-shifted green fluorescent protein in place of coat protein and in situ hybridization, showed PepGMV-Mo localized to phloem and mesophyll cells, while -D was mesophyll restricted. Alignment of PepGMV-Mo and -D DNA-B components revealed three indels upstream of the BC1 gene that encodes the movement protein (MP). To determine if this non-coding region (*BC1) D-strain MP putative promoter contributed to ‘recovery’, plants were inoculated with chimeric DNA-B Mo/D components harboring reciprocally exchanged *BC1, and wild-type DNA-A Mo and D components. Symptoms were reminiscent but not identical to wild-type -Mo or -D infection, respectively, suggesting ‘recovery’ cannot be attributed solely to the *BC1. Both BC1 and D*BC1 were targeted by post-transcriptional gene silencing; however, ‘recovered’ leaves accumulated fewer transcripts and 21–24 nt vsiRNAs. Thus, inefficient in planta movement of PepGMV-D is associated with a non-pepper-adapted ‘defective’ BC1 that facilitates hyper-efficient PTGS, leading to BC1 transcript degradation that in turn limits virus spread, thereby recapitulating disease ‘tolerance’. Full article

Hydrangea macrophylla, renowned for its large inflorescences and a diverse range of colors, highlights a significant limitation in current gene function research, which is the lack of effective molecular genetic tools. This study utilized a tobacco rattle virus (TRV)-based virus-induced gene silencing (VIGS) system to investigate gene function through posttranscriptional gene silencing in H. macrophylla for the first time. The ortholog of phytoene desaturase (PDS) in H. macrophylla, termed HmPDS, was identified. Infection of tissue-cultured seedlings with TRV-HmPDS led to photobleaching of the leaves. Additionally, infection with TRV containing the HmCHS1 fragment in the flowers resulted in decreased anthocyanin production in sepals and a lightening of sepal coloration in the infected flowers. The phenomena and RT-qPCR results proved that the PDS and CHS genes of hydrangea were successfully silenced via the vacuum infiltration method. Furthermore, the introduction of TRV-HmF3′5′H revealed a decrease in delphinidin-3-glucoside content in sepals and caused a color change in the sepals from blue to pink. This study demonstrated that the TRV-VIGS system was successfully established in H. macrophylla and effectively applied to the function analysis of HmF3′5′H. Full article