The Sequence Alignment/Map format and SAMtools

Short-term antiretroviral therapy may not correct the dysregulations of plasma virome and cytokines induced by HIV-1 infection

An expansion of plasma anelloviruses and dysregulation of inflammation was associated with HIV-1 infection. However, how antiretroviral therapy (ART) affects the dynamics of plasma virome and cytokine profile remains largely unknown. To characterize the dynamics of plasma virome and cytokines in HIV-1-infected individuals before and during the first year of ART, a cohort of 26 HIV-1-infected individuals and 19 healthy controls was recruited. Blood samples were collected and subjected to metagenomic analysis and the measurement of 27 cytokines. Metagenomic analysis revealed an increased abundance and prevalence of human pegivirus type 1 (HPgV-1) and a slightly decreased diversity and abundance of anellovirus in plasma of HIV-1-infected individuals after ART. No obvious impact was observed on other plasma commensal viruses. Increased abundance and prevalence of HPgV-1 were further confirmed by RT-qPCR assay in a larger cohort of 114 HIV-1-infected individuals. Notably, most dysregulated cytokines were not fully restored by ART, with extremely abnormal levels of IL-10, GM-CSF, VEGF, and eotaxin, and a significantly increased level of plasma I-FABP. Anelloviruses showed significantly negative correlations with other commensal viruses except HPgV-1 but had positive correlations with several anti-inflammatory and Th1 cytokines. These results suggest that short-term ART may not significantly correct the virome and cytokine dysregulations induced by HIV-1 infection. The results highlight a need for further investigation into the long-term effects of ART on virome and cytokine profiles in HIV-1-infected individuals.

Bacteriophage-driven DNA inversions shape bacterial functionality and long-term co-existence in Bacteroides fragilis

Bacterial genomic DNA inversions, which govern molecular phase-variations, provide the bacteria with functional plasticity and phenotypic diversity. These targeted rearrangements enable bacteria to respond to environmental challenges, such as bacteriophage predation, evading immune detection or gut colonization. This study investigated the short- and long-term effects of the lytic phage Barc2635 on the functional plasticity of Bacteroides fragilis, a gut commensal. Germ-free mice were colonized with B. fragilis and exposed to Barc2635 to identify genomic alterations driving phenotypic changes. Phage exposure triggered dynamic and prolonged bacterial responses, including significant shifts in phase-variable regions (PVRs), particularly in promoter orientations of polysaccharide biosynthesis loci. These shifts coincided with increased entropy in PVR inversion ratios, reflecting heightened genomic variability. In contrast, B. fragilis in control mice exhibited stable genomic configurations after gut adaptation. The phase-variable Type 1 restriction-modification system, which affects broad gene expression patterns, showed variability in both groups. However, phage-exposed bacteria displayed more restrained variability, suggesting phage-derived selection pressures. Our findings reveal that B. fragilis employs DNA inversions to adapt rapidly to phage exposure and colonization, highlighting a potential mechanism by which genomic variability contributes to its response to phage. This study demonstrates gut bacterial genomic and phenotypic plasticity upon exposure to the mammalian host and to bacteriophages.

Gut microbiota-mediated conversion of mangiferin to norathyriol alters short chain fatty acid and urate metabolism

Mangiferin (MAN), a natural C-glycosylxanthone, is recognized for its health-promoting effects in traditional medicinal preparations. However, its poor bioavailability and limited intestinal permeability restrict its direct biological activity in vivo. Previous studies have suggested a potential bacterial breakdown of MAN into norathyriol (NOR), an aglycone with significantly higher bioavailability and absorption. Yet, the prevalence of MAN-metabolizing microbes, the presence of MAN or NOR within the gut microbial community, and their effects on the composition and metabolic activity of the gut microbiome remain unclear. In this study, fecal samples from healthy adult volunteers treated with MAN revealed its conversion to NOR, with interindividual variation attributed to the uncultured bacterial strain CAKRHR01 sp934339005. While MAN had minimal impact on microbial composition and metabolic activity, NOR treatment significantly increased pH, reduced overall bacterial cell counts, and selectively suppressed short-chain fatty acid-producing bacteria, including Faecalibacterium prausnitzii as well as urate consumers, such as Enterocloster bolteae. These findings underscore the potential of NOR to modulate gut microbial activity and highlight the importance of understanding microbiome-mediated metabolism when assessing the health implications of phytochemicals.

Reutericyclin, a specialized metabolite of Limosilactobacillus reuteri, mitigates risperidone-induced weight gain in mice

The role of xenobiotic disruption of microbiota, corresponding dysbiosis, and potential links to host metabolic diseases are of critical importance. In this study, we used a widely prescribed antipsychotic drug, risperidone, known to influence weight gain in humans, to induce weight gain in C57BL/6J female mice. We hypothesized that microbes essential for maintaining gut homeostasis and energy balance would be depleted following treatment with risperidone, leading to enhanced weight gain relative to controls. Thus, we performed metagenomic analyses on stool samples to identify microbes that were excluded in risperidone-treated animals but remained present in controls. We identified multiple taxa including Limosilactobacillus reuteri as a candidate for further study. Oral supplementation with L. reuteri protected against risperidone-induced weight gain (RIWG) and was dependent on cellular production of a specialized metabolite, reutericyclin. Further, synthetic reutericyclin was sufficient to mitigate RIWG. Both synthetic reutericyclin and L. reuteri restored energy balance in the presence of risperidone to mitigate excess weight gain and induce shifts in the microbiome associated with leanness. In total, our results identify reutericyclin production by L. reuteri as a potential probiotic to restore energy balance induced by risperidone and to promote leanness.

RNA Pol-II transcripts in nucleolar associated domains of cancer cell nucleoli

We performed a comparative study of the non-ribosomal gene content of nucleoli from seven cancer cell lines, using identical methods of purification and analysis. We identified unique chromosomal domains associated with the nucleolus (NADs) and genes within these domains (NAGs). Four cell lines have relatively few NAGs, which appears mostly transcriptionally inactive, consistent with literature. The remaining three lines formed a separate group with nucleoli with unique features and NADS. They constitute larger number of common NAGs, marked by ATAC-seq and having accessible promoters, with histone markers for transcriptional activity and detectable RNA Pol II bound at their promoters. The transcripts of these genes are almost entirely exported from the nucleolus. These results indicate that RNA Pol II dependent transcription in NADs can vary widely in different cell types, presumably dependent on the cell's developmental stage. Nucleolus-associated genes are likely to be distinguished marks reflecting the cell's metabolism.

Concurrent severe fever with thrombocytopenia syndrome virus outbreaks on multiple fox farms, China, 2023

The role of farmed animals in the viral spillover from wild animals to humans is of growing importance. Between July and September of 2023 infectious disease outbreaks were reported on six Arctic fox (Vulpes lagopus) farms in Shandong and Liaoning provinces, China, which lasted for 2-3 months and resulted in tens to hundreds of fatalities per farm. Severe Fever with Thrombocytopenia Syndrome Virus (SFTSV) was identified in tissue/organ and swab samples from all the 13 foxes collected from these farms. These animals exhibited loss of appetite and weight loss, finally resulting in death. In autopsy and histopathology, prominently enlarged spleens and extensive multi-organ hemorrhage were observed, respectively, indicating severe systemic effects. Viral loads were detected in various tissues/organs, including brains from 9 of the 10 foxes. SFTSV was also detected in serum, anal swabs, as well as in environmental samples, including residual food in troughs used by dying foxes in follow-up studies at two farms. The 13 newly sequenced SFTSV genomes shared >99.43% nucleotide identity with human strains from China. Phylogenetic analyses showed that the 13 sequences belonged to three genotypes, and that two sequences from Liaoning were genomic reassortants, indicative of multiple sources and introduction events. This study provides the first evidence of SFTSV infection, multi-tissue tropism, and pathogenicity in farmed foxes, representing an expanded virus host range. However, the widespread circulation of different genotypes of SFTSV in farmed animals from different provinces and the diverse transmission routes, highlight its increasing and noticeable public health risk in China.

Development and validation of a new mpox virus sequencing and bioinformatic analysis pipeline

Sequencing and bioinformatic analysis of mpox virus (MPXV) remain challenging in resource-limited settings. We developed and validated a PCR-based sequencing assay that targets a 12.5 kilobase (kb) region that is phylogenetically representative of the whole ∼ 200 kb MPXV genome. We combined this sequencing assay with a lightweight, downloadable, on-and-off-grid-bioinformatics pipeline for rapid phylogenetic analysis. Our findings demonstrate that this simplified sequencing method, and the associated bioinformatics pipeline accurately distinguished clades, subclades, and clusters of MPXV. Therefore, this assay will provide rapid sequence information for understanding transmission patterns and sources of outbreaks in resource-limited settings. In addition, this assay provides a unique opportunity to decentralize mpox molecular surveillance capacities that are needed to contain the ongoing outbreak.

RNA-seq analyses reveal the relevance of RNAs involved in ribosomal complex to induce mammalian prion protein aggregation and phase separation in vitro

Conformational conversion of cellular prion protein (PrPC) into infectious PrP (PrPSc) is one of the most intriguing processes in modern Biology. It is well accepted that this transition is catalysed by one or more cofactors that lower the energy barrier between the different PrP forms. Among potential candidates, RNA molecules are strong contenders. Our group has pursued nucleic acids, both DNA and RNA, capable of inducing PrP misfolding, aggregation, and, more recently, phase separation, a process proposed to precede aggregation in degenerative disorders. We found that the interaction between recombinant PrP (rPrP) and total RNA extracted from neuroblastoma cells (N2aRNA) results in significant structural alterations. Here, we use rPrP:N2aRNA as a model to search for RNAs capable of inducing full-length murine rPrP phase separation and/or aggregation. N2aRNA was incubated with rPrP and after that, RNA-seq analysis was conducted with RNAs isolated from the insoluble material using two different protocols. We analysed thousands of RNA-seq reads, most of which represented ribosomal RNA molecules. The set of recovered molecules is heterogeneous; nevertheless, three low-complexity consensus motifs within the sequences of RNAs involved in ribosomal complex were identified as significantly enriched in the RNAs bound to rPrP, suggesting that a population of RNAs is responsible for inducing PrP phase transitions. We hypothesize that RNA transcripts enriched in a set of low complexity motif sequences with predicted structural similarities can be involved in PrPC binding. This interaction would lead to phase separation and, ultimately, result in aggregation into scrapie-like species, in a stoichiometry-dependent manner.

Genomic characterization and insights into the belted coat pattern of a local, reconstituted pig population

The Cinghiato pig population originates from a breeding project aimed at reconstituting an extinct local swine breed, historically depicted in frescoes in Umbria, Central Italy. The selection strategy employed a reconstruction breeding program, choosing mating pairs based on the unique coat phenotype represented in these artworks. Unlike the traditional Cinta Senese breed, Cinghiato pigs exhibit a white belt encircling the trunk, while their forelimbs remain black. This study explores the genetic background of the belted coat pattern observed in the heterogeneous reconstituted population. Twenty-two pigs were genotyped using the Porcine GGP 80K SNP BeadChip. Genetic analyses were conducted to assess population structure and diversity, with comparisons made to other Italian pig breeds and wild boars. Findings reveal moderate genetic diversity within the Cinghiato population. Runs of Homozygosity patterns suggest historical inbreeding events. Moreover, several genomic regions were associated with traits relevant to niche pork production, including feed intake, leg conformation, and fat deposition. Polymorphisms were detected in 10 coat color-related genes (KIT, MC1R, ASIP, EDNRB, KITLG, MITF, OCA2, PAX3, SOX10, and TYRP1). Although some candidate variants were identified, this preliminary study highlights the need for further research to clarify the genetic mechanisms underlying the phenotypic variability of belted coat patterns.

MTD: A cloud-based omics database and interactive platform for Myceliophthora thermophila

Nowadays, biological databases are playing an increasingly critical role in biological research. Myceliophthora thermophila is an excellent thermophilic fungal chassis for industrial enzyme production and plant biomass-based chemical synthesis. The lack of a dedicated public database has made access to and reanalysis of M. thermophila data difficult. To bridge this gap, we developed MTD (https://mtd.biodesign.ac.cn/), a cloud-based omics database and interactive platform for M. thermophila. MTD integrates comprehensive genome annotations, sequence-based predictions, transcriptome data, curated experimental descriptions, and bioinformatics analysis tools, offering a comprehensive, one-stop solution with a 'top-down' search strategy to streamline M. thermophila research. The platform supports data reproduction, rapid querying, and in-depth mining of existing transcriptome datasets. Based on analyses using data and tools in MTD, we identified shifts in metabolic allocation in a glucoamylase hyperproduction strain of M. thermophila, highlighting changes in fatty acid biosynthesis and amino acids biosynthesis pathways, which provide new insights into the underlying phenotypic alterations. As a pioneering resource, MTD marks a key advancement in M. thermophila research and sets the model for developing similar databases for other species.

Genetic, metabolic and toxicological diversity within Prymnesium parvum (Haptophyte) from Polish waterbodies

Toxic blooms of Prymnesium parvum pose one of the most serious environmental threats. This alga occurs worldwide and has devastating effects on gill-breathing organisms inhabiting inland waters. In 2022, Polish society was faced with the problem for the first time. A high biomass of P. parvum in the Gliwice Canal, the Odra River and the oxbow lakes resulted in large-scale fish kills and significant economic losses. Since then, the toxic alga has become a permanent component of the Gliwice Canal phytoplankton community. Studies on P. parvum from other geographical regions have revealed existence of genotypic and phenotypic variation between and within the populations. Therefore, it was important to examine the specific characteristics of P. parvum from Polish water bodies. Here, we present the results of studies on the dynamics of B-type prymnesins (PRMs) production by P. parvum in the Gliwice Canal in 2023. For the purpose of the study, three B-type PRM variants were isolated and used as standards for toxins quantification and toxicity assessment. Differences in cytotoxicity of three isolated B-type prymnesins against fish (RTgill-W1) and human cells (fibroblasts - HDFa and lung cancer cells - A549) were documented for the first time. The lack of a clear correlation between the number of P. parvum cells and PRMs concentration indicates the heterogeneity of the population. Molecular characterisation of P. parvum CCNP2001 strain from Polish waters was also performed. The genome of the strain was sequenced, and the organisation of the PKZILLA genes involved in the biosynthesis of PRMs was described. These genes were present in all analysed bloom samples and in the isolated P. parvum strain. Analysis of the 5.8S rRNA gene sequence yielded unexpected results which indicated that CCNP2001 belongs to a type A prymnesin-producing strain. Additionally, high-resolution mass spectrometry analyses revealed the presence of A-type prymnesin in CCNP2001, supporting the findings of the genetic studies. This study also represents the first investigation into the impact of environmental conditions on the expression of the PKZILLA-1 and PKZILLA-2 genes in P. parvum. The obtained results were compared to prymnesin production level. Our broad-scale studies provided new data on the dynamics, toxicity of PRMs, and molecular characteristics of P. parvum from Polish waterbodies. The results also highlighted existing gaps in knowledge regarding population diversity, the role of prymnesins, and potentially other metabolites, in harmful effects of P. parvum blooms.

Neonatal microbiota colonization primes maturation of goblet cell-mediated protection in the pre-weaning colon

Regulated host-microbe interactions are a critical aspect of lifelong health. Colonic goblet cells protect from microorganisms via the generation of a mucus barrier structure. Bacteria-sensing sentinel goblet cells provide secondary protection by orchestrating mucus secretion when microbes breach the mucus barrier. Mucus deficiencies in germ-free mice implicate a role for the microbiota in programming barrier generation, but its natural ontogeny remains undefined. We now investigate the mucus barrier and sentinel goblet cell development in relation to postnatal colonization. Combined in vivo and ex vivo analyses demonstrate rapid and sequential microbiota-dependent development of these primary and secondary goblet cell protective functions, with dynamic changes in mucus processing dependent on innate immune signaling via MyD88 and development of functional sentinel goblet cells dependent on the NADPH/dual oxidase family member Duox2. Our findings identify new mechanisms of microbiota-goblet cell regulatory interaction and highlight the critical importance of the pre-weaning period for the normal development of protective systems that are key legislators of host-microbiota interaction.

Metagenomic driven isolation of poorly culturable species in food

Although isolating microorganisms from food microbiota may appear less challenging than from the gut or environmental sources, recovering all representative species from food remains a difficult task. Here, we showed by metagenomic analysis that several abundant species had escaped isolation in a previous study of ten cheeses, including several previously uncharacterized species. This highlights the ongoing challenge of achieving a comprehensive recovery of microbes from food. To address this gap, we designed a novel strategy integrating metagenomics-based probes targeting the species of interest, coupled with an incremental culturing approach using pooled samples. As proof of concept, we applied this strategy to two cheeses containing species that were not isolated in our previous study, with the objective of isolating all species present at levels above 2% and, in particular, potential novel food species. Through this approach, we successfully performed the targeted isolation of two Psychrobacter and two Vibrio species from the first cheese, and four Halomonas and two Pseudoalteromonas species from the second one. Notably, P. undina and V. litoralis represented, as far as we know, the first cheese isolates characterized for these species. However, we were unable to isolate a novel species of Pseudoalteromonas, with no characterized representative to date, and Marinomonas foliarum, previously isolated from marine environment. Using metagenome-assembled genomes (MAGs) and metagenomic analysis, we discussed the possible reasons for their non-recovery. Finally, this strategy offers a promising approach for isolating a set of strains representative of the microbial diversity present in food ecosystems. These isolates can serve as a basis for investigating their roles in the communities, their impact on product development, safety implications and their potential in the development of starter cultures.

Spatio-temporal variability of nitrogen-cycling potentials in particle-attached and free-living microbial communities in the Yangtze River estuary and adjacent regions

Particle-attached (PA) and free-living (FL) microorganisms regulate coastal biogeochemical cycles, yet their roles in nitrogen transformation remain unclear. To address this knowledge gap, we seasonally sampled PA and FL from seawater along salinity gradients in the Yangtze River estuary (YRE) and adjacent regions to investigate the spatio-temporal variability of microbial communities, abundances of nitrogen-cycling genes, and key microbial groups affiliated with the nitrogen cycle in PA and FL. Compared to FL, the composition, structure and diversity of PA exhibited more pronounced variations in response to salinity and [NO3-]. Metagenomic analyses indicated a predominant role of denitrification in both PA and FL, with greater abundances of genes involved in most nitrogen transformation processes observed in the estuarine region. The potential for the nitrogen cycle in PA was relatively lower in May, while greater in FL, potentially due to competition for nitrogen substrates between PA and phytoplankton during spring. PERMANOVA and Mantel tests showed that gene abundances exhibited spatio-temporal dynamics and were associated with species and environmental factors. Gene-affiliated taxa identification and the Weighted Correlation Network Analysis revealed that the differences in environmental factors and taxa responsible for the nitrogen transformation drove spatio-temporal variations of the nitrogen cycle between PA and FL, and implied the significance of their interaction in nitrogen fates in coastal ecosystem. Gammaproteobacteria and Betaproteobacteria were highly affiliated with nitrogen-cycling genes, while Nitrososphaeria played an important role in nitrification and denitrification. This study offered practical insights for mitigating eutrophication through targeted regulation of microbial-mediated nitrogen fluxes.

Impact of highly pathogenic avian influenza virus (HPAIV) on Black-headed Gulls Chroicocephalus ridibundus population in Poland in 2023

The highly pathogenic avian influenza virus (HPAIV) A(H5N1) has caused the most extensive and severe epizootic event affecting both poultry and wild birds globally. This study investigated the impact of HPAIV on the breeding population of the Black-headed Gull Chroicocephalus ridibundus, the most abundant gull species in Poland. During the 2023 outbreak, this species was reported as the most frequently infected in the country. A higher-than-natural adult mortality rate (greater than 1.5% of the breeding individuals) was observed in 114 surveyed colonies across all regions of Poland. Laboratory tests confirmed the presence of HPAIV in all 17 colonies sampled, with average adult mortality estimated at 26.1%, and ranging from 1.7% to 77.8%. The estimated mortality rate across all surveyed colonies was 22.2%. Extrapolations across the entire Polish breeding population (at least 115,000 pairs according to the national census) indicated that approximately 51,000 adult Black-headed Gulls might have perished due to HPAIV in 2023. The number of adults found dead was positively correlated with colony size (r = 0.733, P < 0.001). The deaths were associated with a single HPAIV genotype (BB) across all confirmed cases. Understanding the spread and severity of HPAIV in colonially breeding waterbirds, such as gulls, is essential for assessing the full extent of the threats this virus poses to wild bird populations.

Multi-omics integration reveals the regulatory mechanisms of APC and CREB5 genes in lipid biosynthesis and fatty acid composition in pigs

The intramuscular fat (IMF), fatty acid and amino acid compositions of pork are intricately linked to meat quality, flavor profile, and nutritional composition, and have potential implications for human health. Lipid accumulation in pork is initiated by the biosynthesis of fatty acids and regulated by a complex network of genes. In this study, the IMF content and genotyping of large-scale slaughtered Yorkshire pigs were assessed. Transcriptome sequencing of muscles from 17 individuals and fatty and amino acid analyses of muscles from 28 individuals according to IMF content were conducted. Phenotypic analysis showed a high correlation between IMF and most fatty acids, and the composition ratio of different types of fatty acids varied with IMF content. A negative correlation between the n-6/n-3 polyunsaturated fatty acid (PUFA) ratio and increase in IMF content significantly enhanced the levels of essential fatty acids and ameliorated the n-6/n-3 PUFA ratio in pork, thereby elevating its nutritional value to better align with contemporary health standards. A comprehensive analysis that integrated a genome-wide association study, differential gene expression analysis, and weighted gene co-expression network analysis was employed to identify the regulatory mechanisms of lipids. PRLR, SEC11C, ALPK2, CPLX4, APC, and CREB5 were identified as key candidate genes that affect intramuscular lipids and fatty acids. Through molecular and cellular experiments, our results indicated that high APC and CREB5 gene expression significantly promotes lipogenesis in cells, where these genes play an important role in regulatory pathways related to lipid synthesis in animals, which may affect fat deposition and fatty acid composition in pork. Overall, these results lay the foundation for an in-depth analysis of the genetic regulation of pork lipids and nutrition, and also provide molecular regulatory markers for the primary selection of pigs with better meat quality.

Phylogenomic analyses revealed a new lineage of house mouse (Mus musculus) in Gyirong Basin of Xizang Autonomous Region, China

In the present study, we collected 20 individuals and 12 individuals of wild mice from the Gyirong Basin of Xizang Autonomous Region in China and Sudurpashchim in Nepal. Phylogeny and genetic structure inferred from different types of genomic markers suggest that these samples all belong to Mus musculus, among which individuals from Gyirong Basin represent a new genomic lineage (named as M. m. gyirongus), and samples from Sudurpashchim represent an intermediate population between the central population and M. m. castaneus. M. m. gyirongus, along with M. m. domesticus and M. m. musculus, differentiated from the central population compactly during ∼ 272,000-251,000 years ago in the interglacial period. Three lineages all experienced continuous population decline before ∼ 70,000 years ago. Then, they underwent population fluctuations at different periods that might have been impacted by climate changes, migration history, and human activities. Genes related to the structure and function of neural synapses, reproduction and development, regulation of cell cycle and carcinogenesis, and immune response have undergone positive selection in the genome of M. m. gyirongus. The discovery of M. m. gyirongus not only helps us to better understand the evolutionary history of M. musculus, but also provides new regional resources for breeding novel laboratory mouse strains.

Using a novel panel of drug-resistant triple-negative breast cancer cell lines to identify candidate therapeutic targets and biomarkers

Here, we introduce a novel set of triple-negative breast cancer (TNBC) cell lines consisting of MDA-MB-468, HCC38, and HCC1806 and their sublines adapted to cisplatin, doxorubicin, eribulin, paclitaxel, gemcitabine, or 5-fluorouracil. Whole exome sequencing combined with TCGA-derived patient data resulted in the identification of 682 biomarker candidates in a pan-cancer analysis. Thirty-five genes were considered the most promising candidates because they harbored resistance-associated variants in at least two resistant sublines, and their expression correlated with TNBC patient survival. Exome sequencing and response profiles to cytotoxic drugs and DNA damage response inhibitors identified revealed remarkably little overlap between the resistant sublines, suggesting that each resistance formation process follows a unique route. This reflects recent findings on cancer cell evolution in patients, supporting the relevance of drug-adapted cancer cell lines as preclinical models of acquired resistance. Moreover, all of the drug-resistant TNBC sublines remained sensitive or even displayed collateral sensitivity to a range of tested compounds. Cross-resistance levels were lowest for the CHK2 inhibitor CCT241533, the PLK1 inhibitor SBE13, and the RAD51 recombinase inhibitor B02, suggesting that CHK2, PLK1, and RAD51 are potential drug targets for therapy-refractory TNBC. In conclusion, we present novel preclinical models of acquired drug resistance in TNBC and the identification of novel candidate therapeutic targets and biomarkers for this disease.

C-terminal binding protein 2 interacts with JUNB to control macrophage inflammation

Although acute inflammatory responses are critical for survival, chronic inflammation is a leading cause of disease and mortality worldwide. Nevertheless, our mechanistic understanding of pathogenesis is still limited and precise treatment options are lacking. Here, we investigate the role of the transcriptional co-repressors C-terminal binding protein (CTBP) 1 and 2 in murine and human macrophage activation using loss-of-function models to show that CTBP2 but not CTBP1 controls inflammatory gene expression. We find that CTBP2 occupies cis-regulatory elements of inflammatory genes together with the transcription factors NF-κB and AP-1 and forms a co-repressor complex. Rescue of Ctbp1/2 double knockout cells with WT, oligomeric CTBP2 attenuates inflammatory responses, whereas a monomeric mutant does not. Differential profiling of CTBP2's WT and monomeric interactome confirms oligomer-specific interactions with multiple repressors. Conversely, monomers retain the ability to interact with AP-1 and RNA polymerase II, boosting gene expression. Our findings point to an important function for CTBP2 in fine-tuning inflammatory gene expression, potentially unveiling novel therapeutic targets for the treatment of inflammatory diseases.

Salinity as a key factor affects viral structure, function, and life strategies in lakes from arid and semi-arid regions

Salinity impacts lake microorganisms in arid and semiarid zones, affecting climate change. Viruses regulate community structure, facilitate gene transfer, and mediate nutrient cycling. However, studies on the diversity and functional differences of viruses in lakes of varying salinity are limited. Thus, we investigated metagenomic data from 20 lakes in Xinjiang Province, China, to determine viral distribution, virus-host linkage, function, and drivers in lakes of varying salinity. The results showed that salinity shaped the distribution of viral community composition, and Hafunaviridae was the dominant virus in high-salinity lakes. All the metagenome-assembled genomes (MAGs) belonging to Halobacteriota were predicted as hosts, with a lysogenic lifestyle predominating the life strategy, implying their potential protection in salt lakes. Moreover, some auxiliary metabolic genes (AMGs), such as cpeT and PTOX, were related to antioxidant and stress responses, which might help the host survive high salinity stress-induced peroxidation. Notably, the main antibiotic resistance genes (ARGs) carried by viruses, which conferred resistance to polymyxin and trimethoprim, related to the local use of veterinary antibiotics, suggesting that they are potential vehicles for the transmission of ARGs. Overall, these findings suggest that lake systems include unique viral varieties that may influence microbial ecosystems and host metabolism related to environmental adaptability.

Essential Roles of Conserved Pseudouridines in Helix 69 for Ribosome Dynamics in Translation

The widespread distribution of pseudouridine (Ψ), an isomer of the canonical uridine base, in RNA indicates its functional importance to the cell. In eukaryotes, it is estimated that around 2% of ribosomal RNA nucleotides are pseudouridines, most of which are located in functional regions of the ribosome. Defects in RNA pseudouridylation induce a range of detrimental effects from compromised cellular protein biosynthesis to disease phenotypes in humans. However, genome-wide changes to mRNA translation profiles by ribosomes lacking specific conserved pseudouridines have not been extensively studied. Here, using a new genomic method called 5PSeq and in vitro biochemistry, we investigated changes in ribosome dynamics and cellular translation profiles upon loss of Ψ2258 and Ψ2260 in helix 69, the two most conserved pseudouridines in the ribosome in yeast cells. We found that inhibiting the formation of these two pseudouridines challenges ribosomes to maintain the correct open reading frame and causes generally faster ribosome dynamics in translation. Furthermore, mutant ribosomes are more prone to pause while translating a subset of GC-rich codons, especially rare codons such as Arg (CGA) and Arg (CGG). These results demonstrate the presence of Ψ2258 and Ψ2260 contributes to the dynamics of the H69 RNA stem-loop, and helps to maintain functional interactions with the tRNAs as they move within the ribosome. The optimality of this ribosome-tRNA interaction is likely to be more critical for those limited tRNAs that decode rare codons. Consistent with the changes in ribosome dynamics, we observe that IRES-mediated translation is compromised in the mutant ribosome. These results explain the importance of Ψ2258 and Ψ2260 in H69 to maintain cellular fitness. The strong conservation of Ψ2258 and Ψ2260 in the ribosomes from bacteria to humans indicates their functional significance in modulating ribosome functions. It's likely that the identified functions of these covalent modifications are conserved across species.

Characterization of extrachromosomal circular DNA associated with genomic repeat sequences in breast cancer

Extrachromosomal circular DNA (eccDNA) has emerged as a potential biomarker for disease due to its stable closed circular structure. However, the diagnostic utility of eccDNA remains underexplored. In this study, we demonstrate that the characteristics of eccDNA associated with genomic repetitive elements change in breast cancer patient tissues and plasma. These changes can serve as signatures for accurate cancer classification. We profiled eccDNA annotated to repeat elements across the genome in tissues and plasma, aggregating each repeat element to the superfamily and subfamily level. Our findings indicate that eccDNA associated with repetitive elements in cancer exhibits regular patterns of enrichment or depletion in specific elements, particularly at the family level. Additionally, these repeat element changes are present in different subtypes of breast cancer, correlated with varying hormone receptor expression. Although there are differences in the landscapes of eccDNA on repetitive elements between cancer tissues and paired plasma, the unique characteristics of eccDNA associated with repetitive sequences in the plasma of cancer patients facilitate better differentiation from normal individuals. These analyses reveal that changes in eccDNA associated with repeat sequences in human cancers can be used as diagnostic biomarkers for cancer patients.

Role of PRC2 in the stochastic expression of Aire target genes and development of mimetic cells in the thymus

The transcriptional targets of Aire and the mechanisms controlling their expression in medullary thymic epithelial cells (mTECs) need to be clarified to understand Aire's tolerogenic function. By using a multi-omics single-cell approach coupled with deep scRNA-seq, we examined how Aire controls the transcription of a wide variety of genes in a small fraction of Aire-expressing cells. We found that chromatin repression by PRC2 is an important step for Aire to achieve stochastic gene expression. Aire unleashed the silenced chromatin configuration caused by PRC2, thereby increasing the expression of its functional targets. Besides this preconditioning for Aire's gene induction, we demonstrated that PRC2 also controls the composition of mTECs that mimic the developmental trait of peripheral tissues, i.e., mimetic cells. Of note, this action of PRC2 was independent of Aire and it was more apparent than Aire. Thus, our study uncovered the essential role of polycomb complex for Aire-mediated promiscuous gene expression and the development of mimetic cells.

Microglia and CD8+ T cell activation precede neuronal loss in a murine model of spastic paraplegia 15

In central nervous system (CNS) diseases characterized by late-onset neurodegeneration, the interplay between innate and adaptive immune responses remains poorly understood. This knowledge gap is exacerbated by the prolonged protracted disease course as it complicates the delineation of brain-resident and infiltrating cells. Here, we conducted comprehensive profiling of innate and adaptive immune cells in a murine model of spastic paraplegia 15 (SPG15), a complicated form of hereditary spastic paraplegia. Using fate-mapping of bone marrow-derived cells, we identified microgliosis accompanied by infiltration and local expansion of T cells in the CNS of Spg15-/- mice. Single-cell analysis revealed an expansion of disease-associated microglia (DAM) and effector CD8+ T cells prior to neuronal loss. Analysis of potential cell-cell communication pathways suggested bidirectional interactions between DAM and effector CD8+ T cells, potentially contributing to disease progression in Spg15-/- mice. In summary, we identified a shift in microglial phenotypes associated with the recruitment and expansion of T cells as a new characteristic of Spg15-driven neuropathology.

Anaerobic digestion at hyper-mesophilic temperatures: Microbiome and antibiotic resistome in full-scale agricultural biogas plants

Temperatures between 40°C and 50°C are increasingly implemented in full-scale agricultural anaerobic digestion (AD), yet the microbial diversity and antibiotic resistome dynamics within this temperature range remain poorly understood. Here, we defined this range as "hyper-mesophilic" and surveyed five full-scale sites. Significant differences were found in the bacterial community structure, potentially stemming from feedstock combination (high vs low/non-manure) and operating temperature. Sites operating at 44°C exhibited superior attenuation efficiency (81-92 %) for antibiotic resistance genes (ARGs) and mobile genetic elements (MGEs) than sites operating at 41°C (41-83 %). High-risk clinically important ARGs such as sul1, lnuA, tet(O), and tet(L) persisted in sites blending livestock manure. Potential hosts of ARGs were identified and included opportunistic human pathogens like Enterococcus faecalis, Staphylococcus aureus, and Clostridioides difficile. The tnpA transposon accounted for > 50 % of the total MGEs and frequently co-localised with ARGs, while the class 1 integrase, intI1, was only detected in manure-blended AD. Based on prevalence in plasmids, ARGs showed higher mobility potential in sites blending chicken manure. The results obtained here provided initial insights into hyper-mesophilic AD and reinforced the importance of conducting surveillance for crop AD, with or without manure, as part of wider efforts to mitigate antimicrobial resistance in agroecosystems.

Efficient transgenic system for the firebrat Thermobia domestica utilizing hyPBase and G0 founder prescreening

The firebrat, Thermobia domestica, is an apterygote model insect with favorable traits, including rapid generation turnover, high fecundity, and ease of laboratory rearing. We previously developed a method for embryo injection and CRISPR/Cas9-based genome editing in Thermobia. In the present study, we established a highly efficient transgenesis system using the hyperactive piggyBac transposase (hyPBase) to expand genetic manipulation techniques in Thermobia. By injecting embryos with a mixture of hyPBase mRNA and a donor plasmid expressing GFP under the control of an eye enhancer, we achieved the first successful transgenesis in Thermobia. Eye-specific GFP expression was observed in 5.7 % of G0 individuals hatched from injected eggs. Notably, these GFP-positive G0 founders exhibited significantly elevated germline transmission rates (53.3 %) compared with GFP-negative G0 founders (19.0 %). Additionally, a significant difference in the proportion of G1 transgenic progeny emerged between the GFP-positive and GFP-negative G0 groups (20.0 % vs. 2.7 %), highlighting the utility of GFP expression as a predictor of transgenic G1 offspring from injected G0 founders. Furthermore, multiple transgene insertions mediated by hyPBase contributed to the increased transformation efficiency observed in G0 founders with high transmission rates. Our findings offer valuable genetic toolkits for Thermobia that will facilitate advanced research on fundamental biological processes, such as the evolution of wings and metamorphosis.

Size over substance: Microplastic particle size drives gene expression and fitness loss in a freshwater insect

Microplastics (MP) are a diverse class of contaminants for which it is challenging to assess their effects on freshwater biota. As polyamide (PA) and polyvinyl chloride (PVC) are two of the most abundant microplastic materials in natural environments, the present study investigated whether their chronic presence, particle size (< 100 μm and > 100 μm) and their mixture influenced gene transcription patterns and inclusive fitness of C. riparius. Transcriptome data as the lowest phenotypic trait level suggested that MP exposure impacted a range of organismic processes like oxidative stress and inflammations, leading to an innate immune response, downregulation of metabolism in organs directly exposed to the particles and triggered premature molting, regardless of the MP material or their mixture. A life-cycle fitness assessment was performed using PA, PVC and a mixture of both in, respectively. The integration of the fitness components survival, developmental time and fertility into the daily population growth rate as comprehensive fitness parameter on the highest trait level showed that any chronic microplastic exposure led to a considerable fitness loss. Partitioning the effects of substance and size class showed that microplastic exposure as such and size played an important role, while the MP material was of minor importance. The observed decrease in daily population growth rates between 2.3 and 7.6 % upon chronic MP exposure suggested a dramatic reduction of the species' population size and thus for freshwater ecosystems.

The nature of complex structural variations in tomatoes

Structural variations (SVs) in repetitive sequences could only be detected within a broad region due to imprecise breakpoints, leading to classification errors and inaccurate trait analysis. Through manual inspection at 4532 variant regions identified by integrating 14 detection pipelines between two tomato genomes, we generated an SV benchmark at base-pair resolution. Evaluation of all pipelines yielded F1-scores below 53.77% with this benchmark, underscoring the urgent need for advanced detection algorithms in plant genomics. Analyzing the alignment features of the repetitive sequences in each region, we summarized four patterns of SV breakpoints and revealed that deviations in breakpoint identification were primarily due to copy misalignment. According to the similarities among copies, we identified 1635 bona fide SVs with precise breakpoints, including substitutions (223), which should be taken as a fundamental SV type, alongside insertions (780), deletions (619), and inversions (13), all showing preferences for SV occurrence within AT-repeat regions of regulatory loci. This precise resolution of complex SVs will foster genome analysis and crop improvement.

Biological methane removal by groundwater trickling biofiltration for emissions reduction

Methane removal is an essential step in drinking water production from methane-rich groundwaters. Conventional aeration-based stripping results in significant direct methane emissions, contributing up to one-third of a treatment plant's total carbon footprint. To address this, a full-scale trickling filter was operated for biological methane oxidation upstream of a submerged sand filter, and its performance was compared to a conventional aeration-submerged sand filtration set-up. Full-scale data were combined with ex-situ batch assays and metagenome-resolved metaproteomics to quantify the individual contribution of the main (a)biotic processes and characterize the enriched microbial communities. Both treatment setups fully removed methane, iron, ammonium, and manganese, yet the underlying mechanisms differed significantly. Methane was completely removed from the effluent after trickling filtration, with stripping and biological oxidation each accounting for half of the removal, thereby halving overall methane emissions. Methane-oxidizing bacteria not only outcompeted nitrifiers in the trickling filter, but also likely contributed directly to ammonia oxidation. In contrast to the submerged filter preceded by methane stripping, signatures of biological iron oxidation were almost completely absent in the trickling filter, suggesting that the presence of methane directly or indirectly promotes chemical iron oxidation. All systems had similar ex-situ manganese oxidation capacities, yet removal occurred only in the submerged filters but not the trickling filter. Ultimately, our results demonstrate that trickling filtration is effective in promoting biological methane oxidation at comparable produced drinking water quality, highlighting its potential for advancing sustainable drinking water production.

The activity annotation of peach glycosyltransferase PpUGT78B based on engineering bacterial anthocyanin biosynthesis

Glycosylation modification allows the formation of anthocyanin from anthocyanidin, which enhances the stability of anthocyanins and improves fruit coloration and anthocyanin availability as a human functional component. Flavonoid glycosyltransferases (UFGT) are responsible for catalyzing anthocyanidin glycosylation. In the present study, to better clarify peach (Prunus persica L.) UFGT (PpUGT78B) function, an engineering bacterial system was constructed, which used the anthocyanidin synthase (ANS) gene for producing cyanidin with the incorporation of (+)-catechin precursors and further synthesized cyanidin-3-O-glucoside (C3G) with UFGT co-expression. In addition, it was found that expression of fusion proteins with ANS and UFGT could improve C3G production by about 15 %-20 % in engineering bacterial systems. Furthermore, combining the molecular modeling prediction and targeted mutagenesis, this engineering bacterial system linked some residues in PpUGT78B to glycosylation capacity, which involved F210, L148, Q393, G391, and H230, whose mutation resulted in reduced enzyme activity or even loss and also involved F203 and S29 whose mutation resulted in the increased catalytic activity. Subsequently, a natural mutation of PpUGT78B was detected by analyzing 109 peach genome re-sequencing data, and two residue mutants (E82D, V276F) were found in two peach varieties. Further, these two natural mutation sites were confirmed to reduce PpUGT78B activity in engineering bacterial systems. This study demonstrates the effectiveness of the engineering bacteria system in anthocyanin biosynthesis. It offers valuable insights into the functional and structural roles of PpUGT78B, advancing our understanding of anthocyanin glycosylation.

Combinations of approved oral nucleoside analogues confer potent suppression of alphaviruses in vitro and in vivo

Alphaviruses, including chikungunya virus (CHIKV), pose a significant global health threat, yet specific antiviral therapies remain unavailable. We evaluated combinations of three oral directly acting antiviral drugs (sofosbuvir (SOF), molnupiravir (MPV), and favipiravir (FAV)), which are approved for other indications, against CHIKV, Semliki Forest virus (SFV), Sindbis virus (SINV), and Venezuelan Equine Encephalitis virus (VEEV) in vitro and in vivo. We assessed antiviral efficacy in human skin fibroblasts and liver cells, as well as in a mouse model of CHIKV-induced arthritis. In human skin fibroblasts, synergistic antiviral effects were observed for combinations of MPV + SOF and FAV + SOF against CHIKV, and for FAV + SOF against SFV. In human liver cells, FAV + MPV conferred additive to synergistic activity against VEEV and SINV, while SOF synergized with FAV against SINV. In mice, MPV improved CHIKV-induced foot swelling and reduced systemic infectious virus titres. Combination treatment with MPV and SOF significantly reduced swelling and infectious titres compared to monotherapies of each drug. Sequencing of CHIKV RNA from joint tissue revealed that MPV caused dose-dependent increases in mutations in the CHIKV genome. Upon combination therapy of MPV with SOF, the number of mutations was significantly lower compared to monotherapy with several higher doses of MPV. Combining these approved oral nucleoside analogues confers potent suppression of multiple alphaviruses in vitro and in vivo with enhanced control of viral genetic evolution in face of antiviral pressure. These drug combinations may ultimately lead to the development of potent combinations of pan-family alphavirus inhibitors.

Regulation of macrophage efferocytosis by the CLCF1/NF-κB pathway improves neurological and cognitive impairment following CO poisoning

Severe carbon monoxide (CO) poisoning can induce structural and functional damage to the nervous system, resulting in persistent cognitive impairments. Properly terminating inflammation caused by neuronal damage is essential for tissue repair. Macrophages clear cell corpses and fragments through efferocytosis and produce cytokines to coordinate the immune response, thus promoting neuronal repair and regeneration. However, within the microenvironment of the CO-affected nervous system, macrophage efferocytosis is disrupted. Our study found that macrophages regulate efferocytosis by releasing Cardiotrophin-like cytokine factor 1 (CLCF1), which modulates the NF-κB pathway in both macrophages and microglia, thereby controlling inflammation and promoting nervous system repair. Furthermore, efferocytosis regulates the secretion of cytokines such as TNF-α, IL-1β, and IL-10, promoting M2 polarization of macrophages, which aids in neuronal repair and regeneration. Regulating macrophage CLCF1 expression also leads to improvements in the memory, learning, and motor abilities of rats poisoned with CO.

The transcription factor IID subunit Taf13 is dispensable for TATA binding protein promoter recruitment and RNA polymerase II transcription

The multiprotein complex TFIID, comprising the TATA binding protein (TBP) and 13 TBP-associated factors (TAFs), is an essential component of the RNA polymerase II (Pol II) preinitiation complex (PIC). Cryo-electron microscopy studies suggested a critical role of the TAF11-TAF13 heterodimer in TBP promoter deposition upstream of the transcription start site. To investigate this hypothesis, we inactivated the gene encoding Taf13 in mice and embryonic stem cells (ESCs). Taf13-null embryos implant and survive until E6.5, but fail to undergo gastrulation, while Taf13-null ESCs are viable, but fail to form embryoid bodies and differentiate. Taf13 loss had little effect on TFIID integrity and led to only a mild reduction of TBP promoter recruitment, but led to altered PIC formation and globally reduced Pol II recruitment. Thus, the Taf11-Taf13 heterodimer is not essential for TBP/TFIID recruitment, revealing plasticity in the pathways of PIC formation.

IPMK depletion influences genome-wide DNA methylation

Inositol polyphosphate multikinase (IPMK) is emerging as a critical regulator of nuclear functions. While earlier studies in yeast and cell lines linked IPMK to gene expression, recent work reveals its role in modulating histone acetylation through the activation of histone deacetylases 1/3 (HDAC1/3). Interestingly, HDAC1/3 interact with DNA methyltransferase 1 (DNMT1), stabilizing DNMT1 and promoting DNA methylation. As an HDAC1/3 activator, IPMK may thereby influence DNA methylation dynamics. This study investigates how the genetic depletion of IPMK influences DNA methylation, though the role of its kinase activity remains untested. Using long-read Oxford nanopore sequencing, we conducted methylation analysis for >28 millions of CpG sites and discovered that IPMK deletion results in over 22,000 differentially methylated regions (DMRs). Integrating affected genes by DMRs and RNA-seq data, we found that 35 genes show an inverse correlation between methylation in promoter regions and gene expression. Pathway analysis revealed that genes related to tissue remodeling and hematopoiesis are affected. Notably, MMP14 and LIF showed significant methylation changes in promoter regions under IPMK deletion, resulting in decreased mRNA and protein expression. Collectively, this study identifies IPMK as a novel regulator of DNA methylation. While this study did not investigate the role of IPMK's kinase activity in regulating DNA methylation, future studies will determine whether IPMK's effects on DNA methylation are driven by its kinase activity or by kinase-independent mechanisms.

Catalyzing early ovarian cancer detection: Platelet RNA-based precision screening

Early detection of ovarian cancer is crucial for successful treatment, yet most cases are diagnosed at advanced stages due to a lack of effective screening. Recent advancements in RNA technology from platelets aid in early tumor detection. Here, we proposed our two-step method for assessing the existence of pelvic mass either located at ovaries or uterus with more than 99% specificity by utilizing exon-exon junction features with a sampling invariant normalization technique; then next our model finds the malignancy of detected mass with more than 99% negative predictive value for ovarian cancer to practically assist clinicians' further investigation via combined features of exon-exon junctions, and hematology parameters. We diverged from traditional methods by employing intron-spanning reads (ISR) counts rather than gene expression levels to use splice junctions as features in our models. If integrated with current screening methods, our algorithm holds promise for identifying ovarian or endometrial cancer in its early stages.

Flooding episodes and seed treatment influence the microbiome diversity and function in the soybean root and rhizosphere

Climate change-related events such as flooding have threatened crop productivity, agricultural sustainability, and global food security by causing hypoxic conditions. Such conditions impaire root development and nutrient acquisition, and alter root rhizospheric microbial communities that are vital for plant health and productivity. Seed treatment with pathogen protection have been key to maintaining early seed germination and plant productivity in field conditions. Still, their role in flooding stress and microbiome diversity and functionality in soybeans is poorly understood. Here, we performed field-based investigations to understand the impact of flooding episodes (0, 3, and 7 days after floodings; DAF) and seed treatment (Cruiser MAXX) on soybean plant growth and rhizosphere microbiome diversity and functionality. Flooding episodes significantly reduced seed yield (746 kg ha-1) compared to untreated control. However, the seed treatment increased plant height and pods per plant (3-DAF) and reduced flood injury by 33 % (7-DAF). The shotgun metagenomic analysis showed that seed treatment significantly enhanced the microbial community in rhizospheric soil. Flooding episodes impacted the microbial communities with higher abundance at 3-DAF than at 7-DAF. Flooding stress reduced the microbial diversity, although Proteobacteria increased as root endophytes. Seed treatment and flooding combinations decreased microbiome functionality and reduced gene counts for phytohormone biosynthesis, fermentation, nitrogen, symbiosis, and degradation pathways. Similarly, flooding stress shifted the carbohydrate synthesis to a more specialized substrate. These findings enhance understanding of soybean root and rhizosphere microbiome diversity and functionality dynamics during flooding stress and provide a platform to develop sustainable agricultural practices for enhancing soybean stress tolerance to flooding.

Genomic description of Microbacterium mcarthurae sp. nov., a bacterium collected from the International Space Station that exhibits unique antimicrobial-resistant and virulent phenotype

A novel bacterial strain, designated as 1F8SW-P5T, was isolated from the wall of the crew quarters on the International Space Station. Cells were Gram-staining-positive, strictly aerobic, non-spore-forming, chemoheterotrophic, and mesophilic rods exhibiting catalase-positive and oxidase-negative reactivity. Strain 1F8SW-P5T shared the highest 16S rRNA gene similarity with Microbacterium proteolyticum CECT 8356T (99.34%) and the highest gyrB gene similarity with Microbacterium algihabitans KSW2-21T (91.34%). Its strongest matches via average nucleotide identity and DNA-DNA hybridization were to Microbacterium hydrothermale CGMCC_1.12512T (84.36% and 25.80%, respectively). 1F8SW-P5T formed a distinct lineage during phylogenetic and phylogenomic analysis. The biochemical, phenotypic, chemotaxonomic, and phylogenomic features substantiated the affiliation to 1F8SW-P5T as a new species of Microbacterium, for which we propose the name Microbacterium mcarthurae, with the type strain 1F8SW-P5T (=DSM 115934T =NRRL B-65667T). Based on metagenomic data collected during the Microbial Tracking mission series, M. mcarthurae was identified from all surfaces (n = 8) over an 8-year period, with an increase in relative abundance over time. This is of potential concern, as we observed resistance to all tested fluoroquinolone antibiotics (n = 6), two β-lactam antibiotics, and one macrolide antibiotic, which was not predicted based on isolate or plasmid genotype alone. Furthermore, we found an increase in virulence, compared to Escherichia coli, when tested within a Caenorhabditis elegans model. This pathogenic profile highlights the importance of continued characterization of spacecraft-associated microbes, the characterization of previously unidentified antimicrobial resistance and virulence genes, and the implementation of targeted mitigation strategies during spaceflight.

IMPORTANCE

Crew members are at an increased risk for exposure to and infection by pathogenic microbes during spaceflight. Therefore, it is imperative to characterize the species that are able to colonize and persist on spacecraft, how those organisms change in abundance and distribution over time, and their genotypic potential for and phenotypic expression of pathogenic traits (i.e., whether they encode for or exhibit traits associated with antibiotic resistance and/or virulence). Here, we describe a novel species of Microbacterium collected from the crew quarters on the International Space Station (ISS), 1F8SW-P5T, for which we propose the name Microbacterium mcarthurae. M. mcarthurae was found to be distributed throughout the ISS with an increase in relative abundance over time. Additionally, this bacterium exhibits a unique antibiotic resistance phenotype that was not predicted from whole-genome sequencing, as well as increased virulence, suggesting the need for the identification of previously undescribed antimicrobial resistance genes and monitoring/mitigation during spaceflight.

The tumor suppressor HNRNPK induces p53-dependent nucleolar stress to drive ribosomopathies

The nucleolus is a membraneless organelle and an excellent stress sensor. Any changes in its architecture or composition lead to nucleolar stress, resulting in cell cycle arrest and interruption of ribosomal activity, critical factors in aging and cancer. In this study, we identified and described the pivotal role of the RNA-binding protein HNRNPK in ribosome and nucleolar dynamics. We developed an in vitro model of endogenous HNRNPK overexpression and an in vivo mouse model of ubiquitous HNRNPK overexpression. These models showed disruptions in translation as the HNRNPK overexpression caused alterations in the nucleolar structure, resulting in p53-dependent nucleolar stress, cell cycle arrest, senescence, and bone marrow failure phenotype, similar to what is observed in patients with ribosomopathies. Together, our findings identify HNRNPK as a master regulator of ribosome biogenesis and nucleolar homeostasis through p53, providing what we believe to be a new perspective on the orchestration of nucleolar integrity, ribosome function and cellular senescence.

Intratumoral heterogeneity of cancer driver genomic alterations in myxoid liposarcomas

BACKGROUND

Myxoid liposarcomas (MLS) are rare malignant mesenchymal tumors characterized by specific translocations t(12;16) and t(12;22) with limited additional driver mutations, most notably in PIK3CA and the TERT promoter. PIK3CA is considered a promising therapeutic target. However, effective treatments require the uniform presence of mutation throughout the tumor. Therefore, this study evaluated intratumoral heterogeneity of driver mutations in MLS.

METHODS

In total, 170 samples from 20 tumors (12 patients) were analyzed using an MLS-specific next-generation sequencing (NGS) panel. This included detecting the t(12;16) and t(12;22) translocations and known driver mutations.

RESULTS

Patient-specific t(12;16) or t(12;22) translocations were detected in all 20 tumors (159 of 170 samples; 94%) and remained identical in primary tumors, recurrences, and metastases. TERT promoter mutations were identified in 17 of 20 tumors (85%) and were distributed similarly across samples. In contrast, PIK3CA mutations were present in only 66 of 170 samples (39%), with these and the remaining driver mutations localized only in subclones within individual tumors.

CONCLUSIONS

Therapies that target PIK3CA are unlikely to succeed because of its limited subclonal distribution. In contrast, the ubiquitous presence of t(12;16), t(12;22), and TERT promoter mutations across MLS tumors suggests that these are more effective therapeutic targets for future treatment strategies.

Mineral types dominate microbiomes and biogeochemical cycling in acid mine drainage

Acid mine drainage (AMD) environments are typically used as models to study the crucial roles of acidophilic microbes in aquatic environments. Nevertheless, knowledge regarding microbial-driven biogeochemical cycling across mining regions remains limited. In this study, a metagenomics-based approach was employed to explore the diversity, composition, and ecological functions of microbiomes in global AMD environments with different mineral types. A total of 226 metagenomes, covering 12 mineral types of AMD, were analyzed. As a result, 2114 microbial metagenome-assembled genomes (MAGs) were obtained, representing members from 33 bacterial phyla and 8 archaeal phyla. The core taxa and functional groups in AMDs were identified. Additionally, twelve bacterial and two archaeal lineages were discovered for the first time in AMD environments. The specific metabolic potentials of these genomes were also determined. Our results revealed a high level of specialization in the diversity structures and ecological functions of AMD microbial communities based on mineral-type conditions. Mineral type significantly contributed to the dissimilarity in the AMD microbiomes, especially in water environments, underscoring the pivotal role of mineral types in shaping the microbial community in the AMD environment. Collectively, these findings provide novel perspectives on the ecology and metabolism of microbiomes in extreme AMD environments globally.

Effect of legacy and emerging pollutants on genome-wide methylation patterns in black hake (Merluccius polli) natural populations

Exposure to pollutants such as non-essential metals and microplastics can have harmful consequences for marine organisms. Detecting the impact of pollutants in wild populations can be especially challenging. Such environmental disturbances might prompt rapid responses in the affected organisms, generating changes in their gene expression mediated by epigenetic regulation. Here we use an epiRADseq approach to determine the effect of four non-essential metals (As, Cd, Hg, Pb) and microplastics (MP) on the methylation pattern of Benguela hake, Merluccius polli, captured in the FAO fishing area 34, along the coasts of Mauritania and Senegal. We analysed 49 hake specimens and generated 44,201 epigenetic loci. Despite moderate levels of pollution identified from tissue analysis, we found significant differentially methylated loci associated with the level of the five pollutants analysed (119 significant loci for As, 134 for Cd, 92 for Hg, 119 for Pb, and 159 for microplastics). Elevated Pb was significantly associated with a reduction in hake condition factor. Differentially methylated loci were associated with diverse pathways associated to responses for all pollutants (e.g. immune response, gene expression regulation), pointing to signs of stress within the population. It is worth noting that all pollutants were differentially methylated for a locus in NLRC3, previously associated with innate immune response in fishes. Overall, we found evidence of the effects of moderate concentration of pollutants in the methylation pattern in wild populations of M. polli.

Genetic evidence of female philopatry in a socially polyandrous shorebird

Sex-biased dispersal plays a key role in shaping population dynamics and genetic structure. Two main hypotheses have been proposed for how territoriality and mating competition impact sex-biased dispersal. Female-biased dispersal is expected in monogamous systems with male resource defense, whereas male-biased dispersal is expected in polygynous systems with male competition over mates. However, patterns of sex-biased dispersal in socially polyandrous species, where females compete for both territories and mates, remain poorly understood. We investigated sex-biased dispersal in 2 polyandrous Jacana species across Central America, the Northern Jacana (Jacana spinosa) and Wattled Jacana (J. jacana), which exhibit intense female-female competition for territories and mates and differ in the strength of sexual selection. We analyzed sex-biased dispersal by assessing genetic differentiation and individual assignment indices to determine the probability of an individual being a recent immigrant or philopatric in relation to its sampling location. Our findings reveal strong male-biased dispersal in Northern Jacanas, indicated by higher genetic structuring and philopatry in females. In contrast, Wattled Jacanas showed no significant dispersal bias between sexes. Furthermore, sexually selected traits in Northern Jacana females, such as larger body mass and wing spur length, were associated with philopatry, suggesting that larger females retain territories, whereas smaller females disperse. To our knowledge, this is the first genetic evidence of male-biased dispersal in a polyandrous species. Our findings reveal that sexually selected traits, in addition to territorial and mate competition, are important for understanding species and sex differences in dispersal evolution.

The Masc-PSI complex directly induces male-type doublesex splicing in silkworms

The WZ sex determination system is found in a diverse range of animals, including lepidopteran insects. In the silkworm Bombyx mori, the masculinizing protein Masculinizer (BmMasc) induces the production of the male-type Bombyx mori doublesex (BmdsxM), which is the master genetic switch of B. mori sex differentiation. However, the molecular mechanism through which BmMasc transduces the masculinizing signal to the BmdsxM production remains unknown. Here, we show that BmMasc physically interacts with Bombyx mori P-element somatic inhibitor (BmPSI), a RNA binding protein required for BmdsxM expression. Knockdown experiments indicate that BmPSI is essential for the masculinizing activity of BmMasc. RNA immunoprecipitation experiments also reveal that BmMasc-containing protein complex is associated with female-specific regions of Bmdsx pre-mRNA. Taken together, our findings show that the BmMasc-BmPSI protein complex binds to female-specific Bmdsx regions, inducing exon skipping, and thereby promoting BmdsxM expression in B. mori males.

Arabidopsis PRMT5 buffers pre-mRNA splicing and development against genetic variation in donor splice sites

Genetic variation at splice site signals significantly influences alternative splicing, leading to transcriptomic and proteomic diversity that enhances phenotypic plasticity and adaptation. However, novel splice variants can negatively impact gene expression and developmental stability. Canalization-the ability of an organism to maintain a consistent phenotype despite genetic or environmental variations-helps balance the effects of genetic variation on development and evolution. Protein arginine methyltransferase 5 (PRMT5) is a key splicing regulator in plants and animals. Most splicing changes in prmt5 mutants are linked to weak donor splice sites, suggesting that PRMT5 may buffer splicing against genetic variation. We examined PRMT5's effects on splicing and development in two genetically divergent Arabidopsis thaliana accessions with different single nucleotide polymorphisms affecting donor splice sites. We found that PRMT5 inactivation significantly increased splicing and phenotypic differences between the accessions. Our findings suggest that PRMT5 contributes to canalization, mitigating the impact of splice site polymorphisms and facilitating the evolution of adaptive splicing patterns.

Genomic analyses of Asiatic Mouflon in Iran provide insights into the domestication and evolution of sheep

BACKGROUND

Asiatic mouflon (Ovis gmelini) consists of several subspecies mainly distributed in Armenia, southern Azerbaijan, Cyprus, northern, southern, and western regions of Iran, and eastern and central regions of Turkey nowadays. Genome analyses of Asiatic mouflon in Iran revealed that they could have diverged from the direct ancestor of domestic sheep, and showed genetic introgression into domestic sheep after domestication. However, the impact of the Asiatic mouflon subspecies in Iran on sheep domestication remains unclear.

RESULTS

Here, we conducted a comprehensive population genomics analysis of Asiatic mouflon in Iran with 788 whole-genome sequences (including 40 from Asiatic mouflon), 1104 whole mitogenomes (105 from Asiatic mouflon), and 239 Y chromosomes (21 from Asiatic mouflon). Whole-genome sequence analyses revealed two subpopulations of Asiatic mouflon in Iran: O. gmelini_2 limited on Kaboodan Island in Urmia Lake National Park and O. gmelini_1 over a wide geographic area. Phylogenetic analyses of Asiatic mouflon in Iran based on uniparental variants revealed a monophyletic lineage with the mitochondrial haplogroups C/E, and clustered into a monophyletic with Y-chromosomal lineage HY2 of sheep. Additionally, introgression tests detected significant signals of genetic introgression from O. gmelini_2 to four sheep populations (e.g., Garut, Bangladeshi, Nellore, and Sumatra) in South and Southeast Asia. In the four sheep populations, selective tests and introgression signals revealed that the wild introgression could have contributed to their body size, fat metabolism and local adaptation to the hot and humid environments in the Indian Peninsula.

CONCLUSIONS

Our results clarified subpopulation structure of Asiatic mouflon in Iran, identifying two distinct groups: O. gmelini_1 and O. gmelini_2. Additionally, we suggest a potential genetic contribution to domestic sheep by introgression, with maternal haplogroup C and paternal lineage HY2 likely originating from the Asiatic mouflon populations in Iran. Our findings offer new insights into domestication of sheep and subsequent introgressions events from wild relatives to domestic populations.

Understanding Plasmodium vivax recurrent infections using an amplicon deep sequencing assay, PvAmpSeq, identity-by-descent and model-based classification

Plasmodium vivax infections are characterised by recurrent bouts of blood-stage parasitaemia. Understanding the genetic relatedness of recurrences can distinguish whether these are caused by relapse, reinfection, or recrudescence, which is critical to understand treatment efficacy and transmission dynamics. We developed PvAmpseq, an amplicon sequencing assay targeting 11 SNP-rich regions of the P. vivax genome. PvAmpSeq was validated on field isolates from a clinical trial in the Solomon Islands and a longitudinal observational cohort in Peru, and statistical models were applied for genetic classification of infection pairs. In the Solomon Islands trial, where participants received antimalarials at baseline, half of the recurrent infections were caused by parasites with >50% relatedness to the baseline infection, with statistical models classifying 25% and 25% as probable relapses and recrudescences, respectively. In the Peruvian cohort, 26% of recurrences were likely relapses. PvAmpSeq provides high-resolution genotyping to characterise P. vivax recurrences, offering insights into transmission and treatment outcomes.

Graphical abstract Created in https//BioRendercom

The drug-elicitable alternative splicing module for tunable vector expression in the heart

Adeno-associated viruses (AAVs) are commonly used for gene therapy, but a clinically relevant method to fine-tune AAV expression is lacking, restricting their therapeutic efficacy and safety. Here we develop the drug-elicitable alternative splicing module (DreAM), which is responsive to risdiplam, a Food and Drug Administration-approved alternative splicing modulator. Risdiplam activated DreAM-regulated AAV expression in a dose-dependent manner with a 2,000-fold inducible change, depending on the dose of risdiplam and the organ of interest. With a temporal resolution of 2 days, DreAM could transiently, reversibly and repeatedly activate AAV expression according to the frequency and duration of risdiplam administration. In this proof-of-concept study, we incorporated DreAM into the cardiomyocyte-specific, liver-detargeted AAV9-Tnnt2-miR122TS vector to transiently activate the cardiomyocyte regeneration factor YAP5SA. A dedifferentiation-proliferation-redifferentiation cycle was established in adult cardiomyocytes, improving cardiac regeneration after myocardial infarction while limiting animal death, AAV9-Tnnt2 expression in the liver and hepatic tumorigenesis. Therefore, DreAM may enhance the efficacy, safety and scope of gene therapy.

Senescence-resistant human mesenchymal progenitor cells counter aging in primates

Aging is characterized by a deterioration of stem cell function, but the feasibility of replenishing these cells to counteract aging remains poorly defined. Our study addresses this gap by developing senescence (seno)-resistant human mesenchymal progenitor cells (SRCs), genetically fortified to enhance cellular resilience. In a 44-week trial, we intravenously delivered SRCs to aged macaques, noting a systemic reduction in aging indicators, such as cellular senescence, chronic inflammation, and tissue degeneration, without any detected adverse effects. Notably, SRC treatment enhanced brain architecture and cognitive function and alleviated the reproductive system decline. The restorative effects of SRCs are partly attributed to their exosomes, which combat cellular senescence. This study provides initial evidence that genetically modified human mesenchymal progenitors can slow primate aging, highlighting the therapeutic potential of regenerative approaches in combating age-related health decline.

H2A.Z reinforces maternal H3K4me3 formation and is essential for meiotic progression in mouse oocytes

Mammalian oocytes establish a unique landscape of histone modifications, some of which are inherited by early embryos. How histone variants shape the maternal histone landscape remains unknown. Here we map histone H2A variants in mouse fully grown oocytes (FGOs) and find that H2A.Z forms broad domains across intergenic regions, along non-canonical H3K4me3 (ncH3K4me3). During oocyte growth, H2A.Z progressively transitions from an active promoter-rich, canonical distribution to a non-canonical broad distribution (ncH2A.Z). Depletion of H2A.Z in oocytes partially impairs ncH3K4me3 formation and causes severe defects in meiotic progression, which resemble Mll2-knockout oocytes. Conversely, depletion of ncH3K4me3 by Mll2 knockout also causes a reduction of ncH2A.Z in FGOs. Thus, our study suggests that ncH2A.Z and ncH3K4me3 reinforce each other to form functional oocytes.