Search Results (2,443)

Background/Objectives: tRNAs, tRNAomes, aminoacyl-tRNA synthetases (AARSs), the first proteins, ribosomes and the genetic code coevolved. We utilize sequence data to reconstruct key steps in establishing the first code on Earth. Methods: Networks were constructed to describe initial tRNAome and AARSome evolution. Results: tRNA-34 wobble and tRNA-37 modifications were necessary to evolve the code, as were additional tRNA modifications, so diverse tRNA modification enzymes (i.e., histidyl-tRNA -1 GTP synthase) are among the first proteins. tRNA-linked chemistry brought asparagine, glutamine, cysteine and possibly additional amino acids into the code. tRNA, tRNA modifications and tRNA-linked chemistry were core founding innovations for code evolution. Coevolution of AARSomes was also essential. Class II and class I AARSs have distinct folds but are nonetheless homologs by sequence. Early AARS enzymes folded around Zn motifs. Networks were generated for tRNAomes and AARSomes in ancient Archaea, because Archaea are the closest living organisms to the last universal common ancestor. Conclusions: The first code on Earth was surprisingly ordered, and the few apparent deviations from the regular order can yet be explained. Early in the evolution of the code, innovation was more strongly selected than accuracy. The code froze, however, because of evolving fidelity mechanisms. A historical record was documented in tRNA and in the genetic code structure and has been preserved in living organism sequences. AARSome structure describes the first code evolution more adequately than tRNAomes. Full article

This study aimed to elucidate the molecular mechanisms underlying phenotypic divergence between two Lentinula edodes strains, Le_L and Le_S, which exhibit distinct fruiting body morphologies. While phenotypic variation among mushroom strains has been widely observed, the relative contributions of transcriptional regulation and structural genomic variation to these differences remain poorly understood. Comparative transcriptome analysis identified 8541 differentially expressed genes (DEGs), revealing clear functional divergence between the two strains. Genes upregulated in Le_S were predominantly enriched in ribosomal components and translation-related processes, indicating enhanced protein synthesis activity. In contrast, Le_L-upregulated genes were associated with transporters, transcription factors, and diverse metabolic pathways, suggesting broader regulatory and physiological functions. Protein–protein interaction network analysis further highlighted distinct regulatory architectures, with ribosomal proteins forming highly interconnected hub gene modules in Le_S, whereas Le_L hub genes were functionally diverse and included multiple members of the Major Facilitator Superfamily (MFS). Ortholog analysis across 33 L. edodes strains demonstrated that most hub genes were conserved, indicating their roles as core genetic components. Despite widespread genome-wide variation, including 7931 SNPs and 1149 INDELs, sequence variation within hub genes was limited, and allele-specific expression analysis revealed no significant allelic imbalance. In contrast, presence–absence variation (PAV) analysis identified structural differences affecting MFS transporter genes, which were absent in Le_S but present and upregulated in Le_L. Collectively, these findings suggest that structural genomic variation, particularly involving transporter genes, may play a more prominent role than sequence-level variation in driving phenotypic divergence. This study provides new insights into the genetic basis of strain-specific traits in L. edodes and highlights the importance of integrating multi-level genomic analyses. Full article

This study aimed to characterize the draft genome of Arthrospira platensis NH isolated in Vietnam and evaluate its phylogenetic position within cyanobacteria. Phylogenetic analysis based on 16S rRNA gene sequences confirmed that A. platensis NH belongs to the Arthrospira clade. The assembled genome comprises 5,548,511 bp and contains 4728 genes, including 4683 protein-coding sequences, 42 tRNA genes, and 3 rRNA genes. Genome mapping revealed conserved gene organization with an overall GC content of 44.45%. A comparative genomic analysis with other Arthrospira strains (A. platensis NIES-39 and C1) demonstrated high sequence conservation, supporting their close genetic relationships. Secondary structure prediction showed that all 42 tRNA types adopt typical cloverleaf structures, while the ribosomal RNA genes (16S, 23S, and 5S rRNA) exhibit conserved base composition. An analysis of 16S rRNA sequences from 13 cyanobacterial taxa identified 230 polymorphic sites, providing informative markers for phylogenetic divergence among genera. Collectively, these results establish a comprehensive genomic and phylogenetic framework for A. platensis NH and provide insights into its genetic relationships and potential biotechnological applications. Full article

Programmed cell death 4 (PDCD4) protein is a tumour suppressor protein that inhibits mRNA translation by inhibiting RNA helicase, eukaryotic initiation factor 4A (eIF4A). We have previously reported that PDCD4 interacts with the internal ribosome entry site (IRES) element of B-cell lymphoma extra-large (Bcl-xL) mRNA and inhibits its IRES-mediated translation initiation. S6 kinase (S6K)-mediated phosphorylation of PDCD4 activates its degradation and derepresses IRES-mediated translation initiation of Bcl-xL mRNA. eIF3F (one of the subunits of eIF3 complex) was reported to recruit S6K to phosphorylate eIF3G. Therefore, we investigated the possibility of co-regulation of PDCD4 and eIF3F by S6K and the regulation of IRES-mediated translation initiation by PDCD4–eIF3F. Here, we demonstrated that PDCD4 interacts with several subunits of eIF3. Specifically, eIF3F directly interacts with PDCD4 in an RNA-independent manner. Depletion of PDCD4 in glioblastoma (GBM) cells resulted in decreased levels of certain eIF3 subunits, including eIF3F. Additionally, depletion of eIF3F from GBM cells decreased the levels of PDCD4 protein. We also showed that PDCD4 and eIF3F directly interact with Bcl-xL RNA independently of each other. By performing IRES reporter, polysome profiling assays and EMSA we have demonstrated that eIF3F regulates IRES-mediated translation of Bcl-xL mRNA, likely via its interaction with PDCD4. Full article

Background: Translational regulation constitutes a critical layer of gene expression control in plants, yet the contribution of endogenous 5′ untranslated regions (5′ UTRs) to translational efficiency remains incompletely defined. While viral and synthetic leader sequences have been widely used to enhance protein production, comparatively few native plant 5′ UTRs have been systematically characterised. The objective of this study was to identify and functionally evaluate endogenous plant 5′ UTR elements that promote translation through post-transcriptional mechanisms. Methods: A 79-nucleotide fragment (CYSTM α) derived from the 5′ UTR of Arabidopsis thaliana CYSTM1 (AT1G05340) was cloned upstream of reporter genes and assessed using dual-luciferase assays in transient expression systems (Nicotiana benthamiana and A. thaliana) and in stable transgenic Arabidopsis lines. Translational activity was further evaluated in monocot wheat germ extract and in Escherichia coli. Transcript abundance was quantified by qRT-PCR. Publicly available ribosome profiling and m⁶A datasets were analysed to assess translational efficiency and RNA modification status. Results: In N. benthamiana and A. thaliana, CYSTM α increases reporter protein production 3–7 fold relative to the control and 30–130% above the benchmark Tobacco Mosaic Virus (TMV) Ω leader, without altering mRNA abundance. The CYSTM α sequence also enhances luciferase translation in monocot wheat germ extract and elevates translation 5-fold in E. coli. CYSTM α contains three motifs that may promote translation, namely three CAA repeats that are associated with translation initiation, an AMAYAA motif that is associated with eIF3 binding, and two N6-adenosine DRACH sites that are associated with cap-independent translation. Additionally, ribosome profiling revealed high translational efficiency (TE = 3.25) of native CYSTM1. Conclusions: CYSTM α represents a compact endogenous 5′ UTR element that enhances translation across multiple experimental systems. These findings expand the repertoire of plant-derived translational enhancers and provide insight into sequence features associated with efficient mRNA translation in plants. Full article

This article explores the complex interplay between the process of protein translation and DNA methylation, discussing their combined involvement in brain development. We will emphasize on DNA methylation and related proteins such as DNMTs, TETs, and MeCP2, the latter being the prototype of DNA methyl-binding proteins. Collectively, DNA methylation machinery may be involved in controlling the cell fate commitment of brain cells, as well as their neuronal and glial lineage specification. We aim to summarize current knowledge on the dynamics of protein translation, ribosome biogenesis, and relevant cellular pathways, including the mTOR signaling, in the context of brain development. Special attention is given to MeCP2 because of its unique role as an epigenetic factor that influences the chromatin states with a link to protein translation and its relevance to human disease. We also discuss the impact of DNA methylation-mediated chromatin regulation and protein translation in neurodevelopmental disorders. Our discussions include multi-omics techniques and integrative mechanisms that connect DNA methylation with protein translation. Full article

Background: Neuroinflammation is recognized as a key contributor to Parkinson’s disease (PD), but the relationships between inflammatory signaling, immune-state alterations, and cell-type-specific transcriptional programs remain unclear. Methods: Public transcriptomic datasets, including GSE20141 (discovery cohort) and the substantia nigra subset of GSE114517 (external validation cohort), were analyzed. Genes identified by exploratory differential-expression screening in the discovery cohort were intersected with predefined inflammation- and chemokine-related gene sets to define a candidate space for downstream prioritization. Protein–protein interaction, Gene Ontology, KEGG, and immune-signature analyses were performed, followed by machine learning-based feature prioritization using Elastic Net, support vector machine-recursive feature elimination, and random forest. Prioritized candidates were further evaluated by cross-platform validation, single-nucleus transcriptomic mapping, and a hypothesis-generating in silico perturbation analysis in PD astrocytes. Results: Seventeen genes were retained at the intersection of PD-related differentially expressed genes and inflammation-/chemokine-associated gene sets. These candidates formed a response module enriched in mitochondrial organization, oxidative phosphorylation, and mitophagy pathways. Immune-signature analysis suggested an altered transcriptome-derived immune landscape in PD, with changes in NK cell-related signatures and significant correlations between immune-state scores and the candidate genes. Machine learning-based prioritization yielded five shared candidates, of which only CCL2 and PAK6 showed same-direction support with nominal significance in the external validation cohort. Single-nucleus transcriptomic analysis localized CCL2 predominantly to astrocytes, whereas PAK6 was more strongly associated with neuronal populations, particularly OTX2-positive ventral midbrain neurons. In silico perturbation analysis further predicted that CCL2 suppression in PD astrocytes may be associated with translational- and ribosome-related regulatory programs. Conclusions: CCL2 and PAK6 emerged as prioritized candidate biomarkers associated with PD-related inflammatory and chemokine-linked transcriptional alterations in the substantia nigra. More broadly, this study provides a multi-layered framework for candidate prioritization, cross-platform validation, and cell-type-level contextualization in PD neuroinflammation. Because the study is computational and the perturbation analysis is predictive, orthogonal experimental validation will be required to determine whether CCL2 and PAK6 are biomarkers of disease-associated transcriptional states, functional contributors to PD pathogenesis, or both. Full article

Background/Objectives: Ribosome-inactivating proteins (RIPs) are plant-derived enzymes with potent cytotoxic activity, widely studied as anticancer agents, particularly as toxic payloads in immunoconjugates. Despite numerous encouraging results reported, their clinical application has been limited by their immunogenicity. RIPs from edible plants have been proposed as potentially more suitable candidates due to their possible improved tolerability. However, this aspect still requires validation in vivo in animal models. This study investigated the cytotoxic activity, mechanisms of action and translational potential of sodin 5 (a recently characterized type 1 RIP derived from the edible plant Salsola soda L.) in human colon cancer models, comparing it to the well-known type 1 RIP saporin-S6. Methods: The effects of sodin 5 and saporin-S6 on cell viability, cell death mechanisms and epithelial barrier integrity were assessed on HT29 and Caco-2 cell lines. Sodin 5 cross-reactivity with other anti-type 1 RIP sera was evaluated by ELISA. Finally, its structural characteristics were analyzed. Results: Sodin 5 showed a cytotoxic effect comparable to that of saporin-S6 in HT29 and Caco-2 colon cancer cells, with time- and concentration-dependent reductions in viability. Both type 1 RIPs disrupted the integrity of the intestinal epithelial barrier in mono- and co-culture models and predominantly activated the apoptotic pathway, without inducing necrosis. Sodin 5 exhibited limited immunological cross-reactivity and a conserved catalytic core, supporting its potential relevance as a therapeutic payload for intestinal cancer therapy. Conclusions: Our results indicate that sodin 5 possesses promising characteristics for anticancer applications, particularly in the treatment of intestinal malignancies, where local exposure and repeated administration are often required. Full article

With the rapid progression of global industrialization and urbanization, heavy metal contamination has emerged as a major global threat, especially cadmium pollution. Consequently, optimizing remediation measures has become a pivotal means to solve cadmium contamination. Compared to traditional physical and chemical remediation methods, microbial remediation has great potential in addressing cadmium pollution. In this study, a novel bacterial strain, Chryseobacterium sp. HGX-24, exhibiting high cadmium resistance was successfully isolated and screened from cadmium-contaminated environments. A preliminary discussion of the response mechanisms of this strain under cadmium stress is provided. Additionally, preliminarily explored the synergistic remediation of microbial-plant in cadmium-contaminated soil. Under conditions of high cadmium concentration, cadmium ions were effectively adsorbed by strain HGX-24 through extracellular polymers and functional groups on the cell wall surface, including −COOH, −CONH−, −NH, −OH, and >C=O. Extracellular proteins and polysaccharides were secreted by strain HGX-24 to regulate the adverse effects of heavy-metal cadmium ions on bacterial growth. Furthermore, the expression of genes such as antioxidant defense and ROS scavenging (katG, fabG, ybjT), Fe-S cluster assembly (sufB, sufD), sulfur metabolism (cysAU), amino acid metabolism (hisA, cysD, aspC), phenylacetic acid catabolism (paaC), and ribosomal proteins (rplC, rpsC, rpsL, rplA, rplY, rpmC) was regulated, affecting the synthesis and metabolism of membrane transporters (ABC transporters and efflux RND transporters), antioxidant enzymes (SOD, COT, POD), Fe-S clusters, thioredoxin family proteins, and ribosomal proteins, thereby enhancing resistance to cadmium toxicity. Moreover, strain HGX-24 was found to regulate the activities of redox enzymes in Zea mays L., thereby alleviating oxidative stress and reducing the negative feedback effects of reactive oxygen species in Z. mays. Full article

As global food security challenges intensify, edible crickets are recognized as sustainable protein alternatives; however, genomic resources for commercially important species remain limited, restricting evolutionary inference and the development of robust tools for farm management. We sequenced and assembled the complete mitochondrial genomes of Gryllus bimaculatus and provided the first report for Teleogryllus mitratus, both derived from commercial farms in Thailand, using high-throughput Illumina sequencing, achieving high coverage depths of 32,391× and 63,258×, respectively. The circular mitochondrial genomes were 15,955 bp and 16,046 bp and exhibited the typical insect mitochondrial gene complement of 37 genes, with a strong AT bias. Selective pressure analyses indicated pervasive purifying selection across all protein-coding genes (PCGs) (ω < 1), while episodic diversifying selection was detected in cox1, cox3, cytb, and nad5; additionally, atp8 displayed a comparatively elevated ω. Codon usage analyses revealed a strong preference for AT-ending codons, with leucine codons showing the highest bias. Phylogenetic analyses using concatenated protein-coding and ribosomal RNA genes recovered well-supported relationships within Gryllidae. These farm-derived mitogenomes provide practical foundations for molecular species authentication, population monitoring, and comparative analyses relevant to breeding and traceability. Furthermore, they provide candidate loci for future investigations into mitochondrial evolutionary dynamics and the potential development of molecular markers for commercial breeding management. Full article

Although the ATP-binding cassette (ABC) transporter superfamily of proteins typically facilitates the movement of compounds across cellular membranes, the ABC E subfamily (ABCE) influences protein synthesis via non-transporter roles in ribosome biogenesis. Despite this essential role, our understanding of the impact that ABCE proteins have on insect physiology is limited. Here, we identified and characterized the ABCE gene from Lygus hesperus, a major agricultural pest of crops in North America. LhABCE transcripts were constitutively expressed throughout development and were present in all adult tissues tested. RNA interference (RNAi)-mediated knockdown of LhABCE transcripts in fifth instar nymphs resulted in high nymphal mortality and an incomplete molt. LhABCE knockdown in adults disrupted gametogenesis and reduced longevity. In females, oogenesis was impaired and oocytes did not progress beyond the pre-vitellogenic phase. In males, LhABCE knockdown reduced both spermatozoa abundance and male fertility. LhABCE knockdown, however, had little to no impact on hemolymph protein levels or the levels of circulating vitellogenin. Taken together, the results indicate that LhABCE is critical for the normal progression of processes like molting and gametogenesis that require coordinated bursts of protein synthesis and suggest that ABCE may play an important role in the mechanisms underlying those bursts. Full article

Extracellular vesicles (EVs) from the edible mushroom Pleurotus tuber-regium (PTR) were investigated with respect to their environmental responsiveness, molecular features, and preliminary functional properties. PTR-EVs were characterized by dynamic light scattering, nanoparticle tracking analysis, and transmission electron microscopy. Proteomic analysis revealed enrichment of ribosomal and proteasomal proteins, redox-related enzymes, and vesicle trafficking components, suggesting non-random molecular representation. Small RNA sequencing identified abundant novel miRNAs with predicted targets involved in nitrogen metabolism, cell wall remodeling, redox regulation, and ubiquitin-mediated proteolysis. Among the tested factors, temperature showed the strongest association with vesicle production, with particle concentration increasing from 1.22 × 10⁹ to 7.31 × 10⁹ particles/mL at 34 °C, approximately six-fold higher than at 30 °C. Transcriptomic profiling showed coordinated repression of cell wall-associated genes and redox enzymes, together with induction of endoplasmic reticulum proteostasis pathways, consistent with stress-associated changes in the cellular context of vesicle release. Ultrasonicated PTR-EVs exhibited enhanced DPPH and ABTS radical-scavenging activities in chemical assays, with DPPH increasing from 59.52% to 71.73% and ABTS from 38.25% to 40.51%. Encapsulation efficiencies reached 32.67% ± 1.3% for proanthocyanidins and 46.01% ± 0.5% for curcumin. PTR-EVs showed the best short-term stability at pH 7 and 4 °C, supporting their further evaluation as an edible fungal vesicle platform for food-related nanoscale delivery. Full article

The actinobacterial strain DEC002 was isolated recently from volcanic soils of Deception Island. Its taxonomic identity was resolved through a polyphasic strategy integrating morphology, physiological profiling, multilocus phylogeny, and genome-wide comparisons to resolve its identity. Concatenated core gene trees together with average nucleotide identity and digital DNA–DNA hybridization values place DEC002 within Actinacidiphila fildesensis with robust support. This is the first molecular confirmation of the species beyond King George Island and secures a second verified locality within the South Shetland Archipelago. Growth at low temperature with tolerance to moderate salinity indicates a psychrotolerant lifestyle. Cell-free supernatants inhibited representatives of foodborne Gram-negative and Gram-positive bacteria, including representatives of Enterobacteriaceae, Vibrio, Staphylococcus and Streptococcus. Genome analysis revealed enrichment in multiple biosynthetic gene clusters for nonribosomal peptides, polyketides, terpenes, and ribosomally synthesized and post-translationally modified peptides (RiPPs), supporting the biosynthetic potential of the strain. Functional annotations emphasize replication and repair modules, mobile element-associated proteins, helix–turn–helix regulators, and versatile transport systems, features coherent with cold stress and oligotrophic soils. Antibiotic susceptibility assays indicate a broad resistance phenotype under the experimental conditions tested, together with extracellular antimicrobial activity. These data refine the biogeography of A. fildesensis and indicate DEC002 as a credible Antarctic source of specialized metabolites with antimicrobial promise. Full article

Vibrio alginolyticus is a common pathogenic bacterium and can cause diseases in aquaculture animals. Lysine lactylation (Kla) is a novel post-translational modification (PTM) that has been confirmed to play critical roles in key biological processes. However, the modification landscape and functions of Kla in V. alginolyticus remain unclear. In this study, lactylation modification profiles of the bacterial pathogen V. alginolyticus were first systematically characterized; a total of 9308 lactylation sites on 2155 proteins were successfully identified. The lactylation of cAMP receptor protein (CRP) and triosephosphate isomerase (TPI) was verified by Co-immunoprecipitation (Co-IP) and Western blot to validate the lactylome data. Bioinformatic analysis of the Kla sites revealed 32 conserved sequence motifs surrounding the modified residues. Kla proteins were mainly involved in central metabolic pathways, including glycolysis/gluconeogenesis and ribosome biogen regulators were found to contain Kla modification sites. To investigate crosstalk among lysine acylations in V. alginolyticus, we integrated Kla, lysine acetylation (Kac), and lysine succinylation (Ksuc) profiles and identified 337 co-modified proteins and 5 co-modified sites. Additionally, phylogenetic analysis of Vibrio alginolyticus CobQ based on protein sequence alignment revealed no homology to the known delactylase CobB. Combined in vitro and in vivo functional validation identified VaCobQ as a candidate delactylase with potential NAD⁺-independent activity. This study establishes a lysine lactylation landscape in V. alginolyticus, providing a resource for exploring Kla functions in bacterial metabolism and its possible connections to virulence. Full article

Spinocerebellar Ataxia type 2 (SCA2) and Amyotrophic Lateral Sclerosis type 13 (ALS13) are triggered by polyglutamine expansion in Ataxin-2 (ATXN2). To understand these neurodegenerative disorders at the molecular level, the brains of 10-month-old Atxn2-CAG100-knockin mice were analyzed as microglial, astroglial and neuronal fractions via global RNA sequencing. Data were validated by comparison with the spinal cord oligonucleotide microarray profile or filtered by RNA-seq consistency. Here, we show that the mutation causes a massive inflammatory response in microglia and a reciprocal loss of neuronal transcripts in glial fractions, suggesting severe synapse loss. Beyond these general neurodegenerative signs, we identify pathognomonic changes in the machinery for protein translation and RNA splicing. Glial fractions showed upregulation of Gpnmb (to 2082%), Cst7, Clec7a, Axl, Csf1, Lgals3, Lgals3bp, Slc11a1, and Usp18 as an unspecific neuroinflammatory signature, versus downregulation of axonal Nefh (to <19%), and synaptic Scn4b, Camk2b, Rab15, and Grin1 mRNAs correlating with circuit disconnection. In all fractions, reductions in Kif5a, Rph3a, and Cplx1 were noted versus disease-specific inductions of ribosomal subunits, presumably mirroring the partial loss-of-function of ATXN2 as RNA translation modulator. Selective accumulations of embryonic factors Rnu1b2 and Eef1a1 versus downregulation of adult Eef1a2 specify the mutation impact on splicing and translation elongation. As a potential underpinning of toxic gain-of-function, the proteostasis transcript Rnf213 appeared increased in astroglial and microglial fractions. These transcriptome data suggest altered ribosomal and spliceosome machinery, with massive microgliosis versus mild astrogliosis, at the core of SCA2 and ALS13. Full article