Ro60 is a conserved RNA-binding protein essential for RNA quality control and implicated in autoimmune responses. In this study, we present the structural and functional characterization of φRo60, an Ro60 homolog from Thermus phage phiLo, with its crystal structure determined at 1.99 Å. Despite limited sequence identity with bacterial and amphibian homologs, φRo60 maintains the canonical doughnut-shaped

Efficient DNA repair is essential for maintaining genome integrity and ensuring cell survival. In Escherichia coli, RecBCD plays a crucial role in processing DNA ends, following a DNA double-strand break (DSB), to initiate repair. While RecBCD has been extensively studied in vitro, less is known about how it contributes to rapid and efficient repair in living bacteria. Here, we use single-molecule

Recently long-read sequencing technologies and bioinformatics have enabled the construction of haplotype-resolved genome assemblies. Here, we present the complete and accurate de novo characterization of two challenging genomic regions, the major histocompatibility complex (MHC) and Killer-cell immunoglobulin-like receptors (KIRs), in phased haplotypic form, using the Oxford Nanopore Technology (ONT)

The emergence of numerous variants of SARS-CoV-2 still presents the major challenges in the fight against this disease by reducing the efficacy of vaccines and drugs. RNA G-quadruplexes (G4s) in the SARS-CoV-2 genome are highly conserved and have thus been spotlighted as a promising therapeutic target to combat a wider range of variants. However, very few RNA G4 specific compounds have been reported

Porphyromonas gingivalis, an anaerobic pathogen in chronic periodontitis, belongs to the Bacteroidota phylum and is associated with various virulence factors. Its antibiotic-resistant strains and its propensity to form biofilms pose a challenge to effective treatment. To explore therapeutic avenues, we studied the high-resolution cryogenic electron microscope structures of ribosomes from the wild-type

DNA methylation plays a fundamental role in regulating transcription during development and differentiation. However, its functional role in the regulation of endothelial cell (EC) transcription during state transition, meaning the switch from an angiogenic to a quiescent cell state, has not been systematically studied. Here, we report the longitudinal changes of the DNA methylome over the lifetime

Telomeres ensure genome stability and the levels of telomeric RNA reflect the integrity of telomeric chromatin. The highly conserved RNA-binding protein Ars2 (Arsenite-resistance protein 2) plays an essential role in the RNA nuclear metabolism and negatively regulates the expression of telomeric transcripts in human cells and in Drosophila. We found that germline knockdown of Drosophila Ars2 does not

The A-loop of the 23S ribosomal RNA is a critical region of the ribosome involved in stabilizing the CCA-end of A-site-bound transfer RNA. Within this loop, nucleotide U2552 is frequently 2′-O-methylated (Um2552) in various organisms belonging to the three domains of life. Until now, two enzymatic systems are known to modify this position, relying on either a Rossmann fold-like methyltransferase (RFM)

Bacteria take up environmental DNA using dynamic appendages called type IV pili (T4P) to elicit horizontal gene transfer in a process called natural transformation. Natural transformation is widespread amongst bacteria yet the parameters that enhance or limit this process across species are poorly understood. We show that the most naturally transformable species known, Acinetobacter baylyi, owes this

We characterized the role and regulation mechanism of a pre-mRNA splicing factor, SRSF10, in the development of oligodendrocyte lineage cells (OLCs) and the myelination process during mouse central nervous system (CNS) development. We found that depletion of SRSF10 specifically in OLCs induces hypomyelination and a decrease in OLCs in the developing mouse CNS, whereas depletion of SRSF10 only in differentiated

Short DNA catenanes [circular double-stranded DNA (dsDNA)] have attracted considerable interest for constructing nanostructures and nanomachines, as well as understanding DNA topology. The study of topoisomers of a circular dsDNA with a definite linking number (Lk) is essential but very difficult for simplifying the complex problems about DNA topology. The topoisomers are difficult to prepare, especially

Apart from the iconic Watson–Crick duplex, DNA can fold into different noncanonical structures, of which the most studied are G-quadruplexes (G4s). Despite mounting structural and biophysical evidence, their existence in cells was controversial until their detection using G4-specific antibodies. However, it remains unknown how antibodies recognize G4s at the molecular level and why G4-specific antibodies

Platinum (Pt) drugs are widely utilized in cancer chemotherapy. Although cytotoxic and resistance mechanisms of Pt drugs have been thoroughly explored, it remains elusive what factors affect the receptiveness of DNA to drug-induced damage in nuclei. Here, we demonstrate that nuclear locations of chromatin play a key role in Pt drug-induced DNA damage susceptibility in vivo. By integrating data from

Eukaryotic ribosomes exhibit higher mRNA translation fidelity than prokaryotic ribosomes, partly due to eukaryote-specific ribosomal RNA (rRNA) insertions. Among these, expansion segment 27L (ES27L) on the 60S subunit enhances fidelity by anchoring methionine aminopeptidase (MetAP) at the nascent protein exit tunnel, accelerating co-translational N-terminal initiator methionine (iMet) processing. However

Deciphering cell identity genes is pivotal to understanding cell differentiation, development, and cell identity dysregulation involving diseases. Here, we introduce SCIG, a machine-learning method to uncover cell identity genes in single cells. In alignment with recent reports that cell identity genes (CIGs) are regulated with unique epigenetic signatures, we found CIGs exhibit distinctive genetic

Fluoroquinolones induce double-strand breaks in bacterial DNA, triggering the SOS response, a major DNA damage response that ensures the expression of repair proteins but also promotes the emergence and spread of antibiotic resistance. Fluoroquinolone resistance, particularly in Escherichia coli, is a growing global health concern. Understanding bacterial responses to these antibiotics is critical

The cricket paralysis virus (CrPV) intergenic region internal ribosome entry site (IRES) binds to the ribosome without the need for any initiation factors. Their length, simple mechanism, and ability to function in diverse cell-free systems make CrPV-like IRESs useful tools to study the mechanism of translation and to express proteins. We report the use of a RelE-based next-generation sequencing method

To improve health outcomes for COVID-19 (coronavirus disease 2019) patients, the factors that influence coronavirus genome variation need to be ascertained. The SARS-CoV-2 (severe acute respiratory syndrome coronavirus 2) genome is rich in predicted RNA secondary structures, particularly stem-loops (SLs) formed by intramolecular base pairing within palindromic sequences. We analyzed the NCBI Virus

Over the past 50 years, research has uncovered the co-regulatory proteins and complexes that silence the expression of the γ-globin gene in a developmental stage-specific manner. Recent research expanded the list of these regulatory factors by showing that the eight twenty-one protein 2 (ETO2) helps recruit the nucleosome remodeling and deacetylase (NuRD) complex to the globin locus. Furthermore, ETO2

Bacteria acquire new traits through the uptake of genetic material from the environment, a process requiring DNA processing. However, the molecular inventory mediating this process is far from being completely understood. Here, we identify YhaM in Bacillus subtilis as a conserved 3′-deoxyribonuclease essential for the uptake and processing of genetic information in the form of single-stranded DNA.

Eukaryotes harbor both Sm-type and Lsm-type heteroheptameric rings, which are essential in RNA metabolism. Despite their similar subunits and evolutionary ties, they interact with RNA in distinct ways, functioning as scaffolds and chaperones, respectively. However, the mechanistic basis of their evolutionary divergence remains unclear. Using the Sm ring (D1-D2-F-E-G-D3-B) and the Lsm2-8 ring, both

Emerging evidence suggests that dysregulated RNA-binding proteins (RBPs) are associated with a wide variety of cancers. However, the exact roles and pathways of RBPs in the tumorigenesis of hepatocellular carcinoma (HCC), the most common subtype of liver cancer, remain largely unknown. Here, we systematically searched for altered RBP candidates in HCC through multi-omics data integrative analyses and

The significance of orthogonal gene expression lies in its ability to ensure consistent and predictable operation of genetic pathways in synthetic biology. In bacteria, σ factors are responsible for promoter recognition, where the recognition pattern of σ54 is distinct from that of σ70. Moreover, σ54-dependent promoters require bacterial enhancer-binding proteins (bEBPs) for transcription initiation

Non-coding RNAs belong to a heterogenous family that, among other functions, acts as a biomolecular regulator of gene expression. In particular, lncRNAs, which are estimated to be as numerous as coding RNAs in humans, are thought to interact with genomic DNA to form triple helices. However, experimental evidence of their involvement with processes, such as chromatin structure dynamics or RNA transcription

In the past two decades, tremendous efforts for increasing the efficiency of ribosomal incorporation of backbone-modifying nonproteinogenic amino acids (npAAs) have been made and given significant successes. For instance, the use of an engineered body sequence of transfer RNA (tRNA), known as tRNAPro1E2, that efficiently recruits EF-Tu and EF-P significantly improves consecutive incorporation of npAAs

N 6-Methyladenosine (m6A), the most abundant modification in eukaryotic messenger RNAs (mRNAs), has also been found at a low level in bacterial mRNAs. However, enzyme(s) that introduce m6A modification on mRNAs in bacteria remain elusive. In this work, we combine deep-sequencing approaches that identify m6A sites with in vitro biochemical studies to identify putative m6A methyltransferases that would

The hijacking of CRM1 export is an important step of the retroviral replication cycle. Here, we investigated the consequences of this hijacking for the host. During HTLV-1 infection, we identified that this hijacking by the viral protein Rex favours the association between CRM1 and the RNA helicase UPF1, leading to a decreased affinity of UPF1 for cellular RNA and its nuclear retention. As a consequence

The tenets of intelligent biological systems are (i) scalable decision-making, (ii) inheritable memory, and (iii) communication. This study aims to increase the complexity of decision-making operations beyond standard Boolean logic, while minimizing the metabolic burden imposed on the chassis cell. To this end, we present a new platform technology for constructing genetic circuits with multiple OUTPUT

Functional RNA molecules are crucial for biological processes from gene regulation to protein synthesis, and analyzing functional motifs and elements is essential for understanding RNA regulation. Building on RegRNA 1.0 and 2.0, we present RegRNA 3.0, a sophisticated meta-workflow that integrates 26 computational tools and 28 databases for annotation, enabling one-step and customizable RNA motif predictions

In therapeutic antibody engineering, utilizing naturally occurring mutations in the human body as a reference for modification is an emerging trend. The theory of convergent evolution presents a viable solution. Nevertheless, the nonuniformity of the antibody rearrangement analysis system and the difficulty in identifying the heavy-chain D-region are significant challenges to research and application

The GEPIA series has provided robust and widely used tools for pan-cancer analysis of gene expression data. In the post-genomic era, a major challenge lies in deconvoluting complex regulatory relationship influenced by multiple factors and discovering gene-based precision therapeutics. Here we present GEPIA3, an advanced version of GEPIA that provides a comprehensive analysis of gene/protein interactions

Whereas alignment has been fundamental to sequence-based assessments of protein homology, it is ineffective for intrinsically disordered regions (IDRs) due to their lowered sequence conservation and unique sequence properties. Here, we present a web server implementation of SHARK (bio-shark.org), an alignment-free algorithm for homology classification that compares the overall amino acid composition

Small interfering RNAs (siRNAs) are a proven therapeutic approach for controlling gene expression in the liver. Expanding the clinical potential of RNA interference requires developing strategies to enhance delivery to extra-hepatic tissues. In this study, we examine inhibiting transthyretin (TTR) gene expression by siRNAs in the eye. Anti-TTR siRNAs have been developed as successful drugs to treat

Messenger RNA (mRNA) therapy has revolutionized modern medicine through its rapid development capabilities and ability to induce effective immune responses, becoming a powerful weapon against infectious diseases. The expression level of target proteins from mRNA sequences is primarily influenced by translational efficiency and stability, which can be significantly enhanced by modifying the 5′ and 3′

Knowledge of protein–ligand binding sites (LBSs) is crucial for advancing our understanding of biology and developing practical applications in fields such as medicine or biotechnology. PrankWeb is a web server that allows users to predict LBSs from a given three-dimensional structure. It provides access to P2Rank, a state-of-the-art machine learning tool for binding site prediction. Here, we present

Base editing enables the high-throughput screening of genetic variants for phenotypic effects. Base editing screens require the design of single guide RNA (sgRNA) libraries to enable either gene- or variant-centric approaches. While computational tools supporting the design of sgRNAs exist, no solution offers versatile and scalable library design enabling all major use cases. Here, we introduce BEscreen

While the cohesin complex is a key player in genome architecture, how it localizes to specific chromatin sites is not understood. Recently, we and others have proposed that direct interactions with transcription factors lead to the localization of the cohesin-loader complex (NIPBL/MAU2) within enhancers. Here, we identify two clusters of LxxLL motifs within the NIPBL sequence that regulate NIPBL dynamics

Transposable elements (TEs) pose threats to genome stability. Therefore, small RNA-mediated heterochromatinization suppresses the transcription and hence the mobility of TEs. Paradoxically, transcription of noncoding RNA (ncRNA) from TEs is needed for the production of TE-targeting small RNAs and/or recruiting the silencing machinery to TEs. Hence, specialized RNA polymerase II (Pol II) regulators

Aptamers are short DNA or RNA sequences that can fold into unique three-dimensional structures, enabling them to bind specifically to target molecules with high affinity, similar to antibodies. A distinctive feature of many aptamers is their ability to adopt a G-quadruplex (G4) fold, a four-stranded structure formed by guanine-rich sequences. While G4 formation has been proposed or demonstrated for

Mutations in RecQ family helicases underlie human genetic disorders associated with genomic instability and cancer predisposition, but questions remain about how properly functioning RecQ reduces these deleterious effects. Importantly, some of the deleterious effects may result from incorrect repair of DNA double-strand breaks (DSBs) by recombinase proteins. Displacement loops (D-loops) are three-strand

CRISPR-dependent base editing (BE) enables the modeling and correction of genetic mutations at single-base resolution. Base editing screens, where point mutations are queried en masse, are powerful tools to systematically draw genotype–phenotype associations and characterise the function of genes and other genomic elements. However, the lack of user-friendly web-based tools for designing base editing

One of the major challenges in precision oncology is the identification of pathogenic, actionable variants and the selection of personalized treatments. We present Onkopus, a variant interpretation framework based on a modular architecture, for interpreting and prioritizing genetic alterations in cancer patients. A multitude of tools and databases are integrated into Onkopus to provide a comprehensive

Antisense oligonucleotides (ASOs) are a promising class of gene therapies that can modulate the gene expression. However, designing ASOs manually is resource-intensive and time-consuming. To address this, we introduce a user-friendly web server for ASOptimizer, a deep learning-based computational framework for optimizing ASO sequences and chemical modifications. Given a user-provided ASO sequence,

LitSense 2.0 (https://www.ncbi.nlm.nih.gov/research/litsense2/) is an advanced biomedical search system enhanced with dense vector semantic retrieval, designed for accessing literature on sentence and paragraph levels. It provides unified access to 38 million PubMed abstracts and 6.6 million full-length articles in the PubMed Central (PMC) Open Access subset, encompassing 1.4 billion sentences and

LIGYSIS-web is a free website accessible to all users without any login requirement for the analysis of protein-ligand binding sites. LIGYSIS-web hosts a database of 65,000 protein-ligand binding sites across 25,000 proteins. LIGYSIS sites are defined by aggregating unique relevant protein–ligand interfaces across different biological assemblies of the same protein deposited on the PDBe. Additionally

Adeno-associated virus (AAV) capsid engineering is essential for advancing gene therapy but remains limited by structural complexity and computational constraints. To address these challenges, we developed CapBuild, a cloud-native web server that streamlines AAV capsid prediction, assembly and engineering. CapBuild provides two distinct workflows: a PDB-based pipeline for assembling complete capsids

We present the CellHit web server (https://cellhit.bioinfolab.sns.it/), a web-based platform designed to predict and analyze cancer patients’ responsiveness to drugs using transcriptomic data. By leveraging extensive pharmacogenomics datasets from the Genomics of Drug Sensitivity in Cancer v1 and v2 (GDSC) and Profiling Relative Inhibition Simultaneously in Mixtures (PRISM) and transcriptomic data

Protein–protein interactions (PPIs) are central to many cellular processes, and the assembly of proteins into complexes is essential for biological function. Clustering with overlapping neighborhood expansion (ClusterONE) has been successfully used to detect overlapping protein complexes in both weighted and unweighted PPI networks. Here, we present ClusterONE Web, a freely available, web-based tool

Nonsense-mediated RNA decay (NMD) is a highly conserved RNA turnover pathway that influences several biological processes. Specific features in messenger RNAs (mRNAs) have been found to trigger decay by NMD, leading to the assumption that NMD sensitivity is an intrinsic quality of a given transcript. Here, we provide evidence that, instead, an overriding factor dictating NMD sensitivity is the cell

Horizontal gene transfer plays a critical role in microbial genome evolution and adaptation. Integrated foreign DNA fragments encompass various types of mobile genetic elements (MGEs), ranging from small transposons to conspicuous integrative and conjugative elements. These regions often confer advantageous traits, including antibiotic resistance or novel metabolic capabilities, and contain foreign

Large-scale analyses of bacterial genomic datasets contribute to the comprehensive characterization of complex microbial dynamics among different strains and species. Such analyses often include open reading frame extraction, orthogroup inference, phylogeny reconstruction, and functional annotation of proteins. We have previously developed the M1CR0B1AL1Z3R web server, a “one-stop shop” for conducting

Atomic structure modeling is a crucial step in determining the structures of protein complexes using cryo-electron microscopy (cryo-EM). This work introduces DEMO-EMol, an improved server that integrates deep learning-based map segmentation and chain fitting to accurately assemble protein–nucleic acid (NA) complex structures from cryo-EM density maps. Starting from a density map and independently modeled

Understanding cell–cell communication (CCC) pathways from single-cell or spatial transcriptomic data is key to unraveling biological processes. Recently, multiple CCC methods have been developed but primarily focus on refining ligand–receptor (L-R) interaction scores. A critical gap for a more comprehensive picture of cellular crosstalks lies in the integration of upstream and downstream intracellular

Simulating protein structure flexibility using classical methods is computationally demanding, especially for large proteins. To address this challenge, we have been developing the CABS-flex method, which enables fast simulations of protein structural flexibility by combining a coarse-grained simulation approach with all-atom detail. Previously available as the CABS-flex 2.0 web server, the method

Our web server MAGNETIC (Motif Associated Gene NETworks in Chromosomes) allows users to search the human genome for correlations between promoter regions of genes. The correlations take into consideration the similarity of the abundance of 5/6-mer motifs in gene promoters. The promoters could be 1, 2, or 6 kb upstream of the gene start site. Genes with similar motif abundances are linked to form a

Accurate and accessible phylogenetic analysis is essential for understanding microbial taxonomy and evolution, which are integral to microbiology, ecology, and drug discovery, yet it remains a challenging task. AutoMLST2 (https://automlst2.ziemertlab.com) is a web server designed to facilitate automated phylogenetic reconstruction and microbial taxonomy analysis for bacterial and archaeal genomes.

Drosophila melanogaster has one of the deepest research bases within the life sciences, with a wealth of high-quality tissue- and cell type-specific transcriptomic data available. However, integrating large datasets derived from disparate sources is not trivial. We have designed a broadly applicable solution to this problem in the form of the Drosophila Interesting Genes in Individual Tissues-tally

BioPortal (https://bioportal.bioontology.org) is the world’s most comprehensive repository of biomedical ontologies. It provides infrastructure for finding, sharing, searching, and utilizing biomedical ontologies. Launched in 2005, BioPortal now includes 1549 ontologies (1182 of them public). Its open, freely accessible website enables anyone (i) to browse the ontology library, (ii) to search for terms

All cellular functions rely on accurate protein biosynthesis. Yet, many variants of transfer RNA (tRNA) genes that induce amino acid misincorporation are found in human genomes. Mistranslation induces pleiotropic effects on proteostasis, ranging from protein misfolding to impaired protein biosynthesis and degradation. We employ Saccharomyces cerevisiae (budding yeast), a genetically and biochemically