npj Biofilms and Microbiomes

Biofilm formation likely plays an important role in the pathogenesis of implant-related infections caused by Cutibacterium acnes. Biofilms protect bacteria from antimicrobials and host defenses which makes biofilm-related infections difficult to treat. Here we demonstrate that the exopolysaccharide poly-N-acetylglucosamine (PNAG) contributes to C. acnes biofilm formation in vitro. By treating C. acnes cells and biofilms with the PNAG-degrading enzyme dispersin B, we found that PNAG mediates the attachment of C. acnes cells to polystyrene rods and the formation C. acnes biofilms in glass and polypropylene tubes. We further show that PNAG protects C. acnes biofilm cells from killing by tetracycline and benzoyl peroxide. PNAG may play an important role in biofilm formation, antibiotic tolerance, and virulence in this opportunistic pathogen.

Bacteria exhibit two lifestyles: planktonic free-floating individual cells or sessile multicellular aggregates known as biofilms. The biofilm lifecycle is characterised by three distinct stages: attachment, maturation and dispersal. Distinct adaptations occur in each stage, determining cellular behaviours such as surface attachment or synthesis and degradation of extracellular matrix components. Characterising stage-specific bacterial profiles therefore represents a valuable strategy for the development of novel antibiofilm therapies. Here, we used the model biofilm-forming bacterium Pseudomonas aeruginosa PAO1 to characterise the transcriptional profiles of each stage of the biofilm life cycle: attachment, biofilm maturation and spontaneous dispersal in closed cultures. We report that surface attachment was accompanied by the upregulation of genes comprising the Pil-Chp mechanosensory system, whereas biofilm maturation was characterised by the upregulation of genes involved in Pel polysaccharide synthesis, siaD and PA4396 diguanylate cyclases as well as pipA, fimX and PA5442. In contrast, dispersing cells upregulated genes responsible for the biosynthesis of alginate, rhamnolipid, and extracellular nucleases (eddA, eddB), as well as the transcriptional regulator of dispersal amrZ. Additionally, genes encoding the spontaneous dispersal molecule cis-2-decenoic acid (dspS and dspI), canonical phosphodiesterases (nbdA and rbdA), four non-canonical HD-GYP phosphodiesterases and seven other c-di-GMP-related enzymes were also upregulated during dispersal. Our comprehensive analysis of transcriptional changes across biofilm stages therefore provides benchmarking stage-specific transcriptional profiles for P. aeruginosa biofilms in closed culture systems. Furthermore, it allowed the identification of a subset of fourteen genes as transcriptional biomarkers of dispersal, which were used to build reporter plasmids as tools to determine the onset of dispersal. ImportanceBiofilm infections by P. aeruginosa are a major medical challenge due to the increased tolerance to antimicrobials displayed by bacteria living in sessile communities, which is reduced during spontaneous biofilm dispersal. Attachment, biofilm maturation and dispersal represent the main stages of a dynamic process known as the biofilm lifecycle. However, the global regulatory responses governing transitions between these stages remain understudied. Here, we combine live microscopy and biomass quantification to track the progression of P. aeruginosa cultures through the three main stages of the biofilm lifecycle. We show that cells from each stage recapitulate canonical, stage-specific transcriptional responses and identify a set of biomarkers associated with the onset of dispersal. These biomarkers may offer a practical tool for rapidly screening dispersal-inducing compounds, aiding in the discovery of the next generation of antibiofilm therapeutics.

Biofilms formed by Staphylococcus aureus contribute significantly to persistent infections and antibiotic resistance, driven by the unique composition of their extracellular matrix. While previous studies highlighted extracellular DNA, proteins, and polysaccharides as key components, the role of phospholipids in biofilm architecture remains underexplored. This study identifies extracellular phospholipids, including lysyl-phosphatidylglycerol (Lys-PG), phosphatidylglycerol, and cardiolipin (CL), as critical structural elements in S. aureus biofilms. Bacterial phospholipase A1 (PLA1) that cleaves the acyl ester bond at the sn-1 position of phospholipids effectively dispersed pre-formed biofilms and prevented new biofilm formation by hydrolyzing extracellular phospholipids, without affecting bacterial growth or exhibiting cytotoxicity. Microscopy analyses confirmed that PLA1 disrupts membranous nanostructures, including extracellular vesicles and nanofilaments, integral to biofilm stability. Lipidomic analysis revealed an enrichment of Lys-PG and CL in the biofilm matrix. Lys-PG promotes bacterial aggregation by acting as a molecular glue, mediated through electrostatic and hydrophobic interactions. Deletion of the mprF gene, responsible for Lys-PG synthesis, significantly impaired biofilm formation, confirming its essential role. These findings reveal a "moonlighting" function of phospholipids in biofilm architecture, providing insights into biofilm biology and presenting PLA1 as a promising tool for biofilm control. SignificanceBiofilms, dense bacterial communities, pose significant challenges across medical, industrial, and daily life contexts. Understanding their formation mechanisms is crucial for developing effective strategies against them. We investigated biofilm matrix components in S. aureus biofilms, focusing on phospholipids. Our study reveals the presence and significance of Lys-PG in the biofilm matrix, acting as a crucial factor in biofilm formation and maintenance. Through biochemical, lipidomic, and genetic analyses, we demonstrate the role of Lys-PG in facilitating cell-to-cell contacts, contributing to the robustness and thickness of S. aureus biofilms. These findings shed light on the physiological function of extracellular phospholipids in bacterial biofilms and suggest targeting Lys-PG and its synthetic mechanism as a promising strategy for biofilm control.

Polymicrobial biofilms play an important role in the development and pathogenesis of CAUTI. Proteus mirabilis and Enterococcus faecalis are common CAUTI pathogens that persistently co-colonize the catheterized urinary tract and form biofilms with increased biomass and antibiotic resistance. In this study, we uncover the metabolic interplay that drives biofilm enhancement and examine the contribution to CAUTI severity. Through compositional and proteomic biofilm analyses, we determined that the increase in biofilm biomass stems from an increase in the protein fraction of the polymicrobial biofilm matrix. We further observed an enrichment in proteins associated with ornithine and arginine metabolism in polymicrobial biofilms compared to single-species biofilms. We show that L-ornithine secretion by E. faecalis promotes arginine biosynthesis in P. mirabilis, and that disruption of this metabolic interplay abrogates the biofilm enhancement we see in vitro and leads to significant decreases in infection severity and dissemination in a murine CAUTI model.

Microbiome dysbiosis has largely been defined using compositional analysis of metagenomic sequencing data; however, differences in the spatial arrangement of bacteria between healthy and diseased microbiomes remain largely unexplored. In this study, we measured the spatial arrangement of bacteria in dental implant biofilms from patients with healthy implants, peri-implant mucositis, or peri-implantitis, an oral microbiome-associated inflammatory disease. We discovered that peri-implant biofilms from patients with mild forms of the disease were characterized by large single-genus patches of bacteria, while biofilms from healthy sites were more complex, mixed structures. Based on these findings, we propose a model of peri-implant dysbiosis where changes in biofilm spatial architecture allow the colonization of new community members. This model indicates that spatial structure could be used as a potential biomarker for community stability and has implications in diagnosis and treatment of peri-implant diseases. These results enhance our understanding of peri-implant disease pathogenesis and may be broadly relevant for spatially structured microbiomes.

The application of -omics technologies to study bacterial vaginosis (BV) has uncovered vast differences in composition and scale between the vaginal microbiomes of healthy and BV patients. Compared to amplicon sequencing and shotgun metagenomic approaches focusing on a single or few species, investigating the transcriptome of the vaginal microbiome at a system-wide level can provide insight into the functions which are actively expressed and differential between states of health and disease. We conducted a meta-analysis of vaginal metatran-scriptomes from three studies, split into exploratory (n = 44) and validation (n = 297) datasets, accounting for the compositional nature of sequencing data and differences in scale between healthy and BV microbiomes. Conducting differential abundance analyses on the exploratory dataset, we identified a multitude of strategies employed by microbes associated with states of health and BV to evade host cationic antimicrobial peptides (CAMPs); putative mechanisms used by BV-associated species to resist and counteract the low vaginal pH; and potential approaches to disrupt vaginal epithelial integrity so as to establish sites for adherence and biofilm formation. Moreover, we identified several distinct functional subgroups within the BV population, distinguished by genes involved in motility, chemotaxis, biofilm formation and co-factor biosynthesis. After defining molecular states of health and BV in the validation dataset using KEGG orthology terms rather than community state types, differential abundance analysis confirmed earlier observations regarding CAMP resistance and compromising epithelial barrier integrity in healthy and BV microbiomes, and also supported the existence of motile vs. non-motile subgroups in the BV population. Our findings highlight a need to focus on functional rather than taxonomic differences when considering the role of microbiomes in disease and identify pathways for further research as potential BV treatment targets.

Bacillus subtilis has been extensively used to study the molecular mechanisms behind the development and dispersal of surface bacterial multicellular communities. Well-structured spatially organised communities (colony, pellicle, and submerged biofilm) share some similarities, but also display considerable differences at the structural, chemical and biological levels. To unveil the spatial transcriptional heterogeneity between the different communities, we analysed by RNA-seq nine spatio-physiological populations selected from planktonic and spatially organised communities. This led to a global landscape characterisation of gene expression profiles uncovering genes specifically expressed in each compartmental population. From this mesoscale analysis and using fluorescent transcriptional reporter fusions, 17 genes were selected and their patterns of expression reported at single cell scale with time-lapse confocal laser scanning microscopy (CLSM). Derived kymographs allowed to emphasise spectacular mosaic gene expression patterns within a biofilm. A special emphasis on oppositely regulated carbon metabolism genes (gapA and gapB) permitted to pinpoint the coexistence of spatially segregated bacteria under either glycolytic or gluconeogenic regime in a same biofilm population. Altogether, this study gives novel insights on the development and dispersal of B. subtilis surface-associated communities.

Bacterial vaginosis (BV) affects approximately 29% of women in the U.S., with higher rates among certain demographics and up to 50% recurrence within a year. Besides complications like increased risk of sexually transmitted infections (STIs), pregnancy-related issues, it can negatively impact psychological well-being, leading to discomfort and reduced quality of life. While previous studies have provided insights into the overall metabolomic profile of healthy and diseased vaginal environments, the elucidation of individual microbial metabolite signatures remains limited. Furthermore, given that biofilms exhibit distinct metabolic requirements compared to planktonic cultures, a differential analysis of metabolites in both growth conditions could reveal potential therapeutic targets. This study presents a comprehensive metabolomic analysis and comparison of significant vaginal microbes including Lactobacillus crispatus, Gardenerella vaginalis, and Lactobacillus iners in both planktonic and biofilm growth conditions. Our analysis revealed distinct metabolite production and consumption patterns among different microbes and growth modes. In biofilm cultures, metabolite consumption is influenced by nutrient availability, which in turn regulates the profile of produced metabolites. G. vaginalis demonstrated the ability to form biofilms in various media types. Limited shared metabolic pathways in both biofilm types of G. vaginalis, highlights the unique metabolic processes involved in their formation. Despite L. crispatus suspension and biofilm cultures sharing 142 consumed and 104 produced metabolites, the biofilm culture demonstrated a remarkable metabolic shift. While comparing suspension and biofilm cultures of L. crispatus, L. iners, and G. vaginalis, we found convergence in nutrient utilization, but divergence in metabolic outputs reflecting growth-specific adaptations and underscore the importance of considering the state of existence when studying the vaginal microbiome. This study provides valuable insights into the growth mode-specific metabolic requirements of key vaginal microbes. The findings underscore the potential for leveraging metabolite-mediated microbial cross-talk as a novel therapeutic approach against BV. This avenue of research warrants further investigation, as it could lead to the development of targeted interventions that modulate the vaginal microbiome through metabolic manipulation, potentially offering more effective and personalized treatments for BV.

Spatial organization is a defining feature of multispecies biofilms and critically influences microbial interactions and emergent community properties. However, understanding and manipulating how microbes assemble into spatially structured biofilms remains challenging because most experimental frameworks emphasize species composition and pairwise interactions, while often overlooking the spatial constraints on biofilms imposed by the environment. In this study, we focus on how carbon substrate type, distinguishing between diffusible sugars and polymeric substrates, affects biofilm self-organization in a four-member synthetic bacterial community (SynCom). Across all tested conditions, the SynCom consistently formed more biofilm biomass than any of its subsets, indicating a robust synergistic phenotype. Using chemically defined, 3D-printed hydrogel substrates with consistent physical properties, we varied carbon source composition to identify its impact on biofilm assembly. Microscopic imaging showed that carbon substrate type strongly influenced biofilm self-organization with diffusible simple carbon substrates yielding relatively intermixed communities, whereas polymer-rich carbon substrates promoted a highly structured biofilm organization characterized by the dominance and peripheral localization of polymer-degrading species. Bioinformatic analyses of carbohydrate-active enzymes (CAZymes) annotation and genome-scale metabolic modeling suggested that metabolite exchange networks in the SynCom may drive more complex metabolic interactions beyond the commonly observed degrader-exploiter-scavenger relationship within planktonic microbial communities. Together, our findings demonstrate carbon substrate type as an important ecological determinant of biofilm self-organization, highlighting the need to integrate environmental factors alongside species composition and metabolic potential to fully understand and manipulate natural and engineered multispecies biofilms.

Streptococcus mutans is the major microbial etiological agent of dental caries and can adhere to surfaces such as type-I collagen, present in dentin and periodontal tissues. Recent studies have characterized planktonic S. mutans bacterial extracellular vesicles (bEVs) and demonstrated environmental-induced changes due to sugar presence or pH alterations. However, to date there are no studies exploring if surface-derived changes - such as tissue glycation - can modulate bEV production in the context of oral biofilm formation in the elderly. Therefore, the aim of this work was to determine the role of biofilm formation and collagen glycation on the morphology and composition of S. mutans bEVs. For this, bEVs from S. mutans biofilms on native and glycated collagen surfaces were isolated, characterized, and compared to bEVs from planktonic cells. Nanoparticle tracking analysis and microscopy confirmed bEV production and showed that bEVs from biofilms are smaller in size and less abundant than those from planktonic cells. Furthermore, proteome analysis revealed that S. mutans biofilm formation on native and glycated collagen led to the enrichment of several key virulence proteins such as Eno, LuxS, Tpx, and ScrB. Also, a shift towards proteins involved in metabolic processes was found in bEVs following biofilm formation on collagen surfaces, whereas glucan metabolism proteins were overexpressed in vesicles from the planktonic state. These results demonstrate that biofilm formation, as well as the glycation of collagen associated with aging and hyperglycemia, can modulate bEV characteristics and cargo and could play a central role in S. mutans virulence and the development of diseases such as dental caries and periodontal disease.

The marine bacterium, Pseudoalteromonas tunicata, is a useful model for studying mechanisms of biofilm development due to its ability to colonize and form biofilms on a variety of marine and eukaryotic host-associated surfaces. However, the pathways responsible for P. tunicata biofilm formation are still incompletely understood, in part due to a lack of functional information for a large proportion of its proteome. Here, we used comparative shotgun proteomics to examine P. tunicata biofilm development throughout the planktonic phase to three stages of biofilm development at 24, 48, and 72 h. Proteomic analysis identified 232 proteins that were up-regulated during different stages of biofilm development, including many hypothetical proteins as well as proteins known to be important for P. tunicata biofilm development such as the autocidal enzyme AlpP, violacein proteins, S-layer protein SLR4, and various pili proteins. We further investigated the top identified biofilm-associated protein (Bap), a previously uncharacterized 1600 amino acid protein (EAR30327), which we designated as "BapP". Based on AlphaFold modeling and genomic context analysis, we predicted BapP as a distinct Ca2+-dependent biofilm adhesin. Consistent with this prediction, a {Delta}bapP knockout mutant was defective in forming both pellicle and surface-associated biofilms, which was rescued by re-insertion of bapP into the genome. Similar to mechanisms of RTX adhesins, BapP-mediated biofilm formation was influenced by Ca2+ levels, and BapP is likely exported by a type 1 secretion system. Ultimately, our work not only provides a useful proteomic dataset for studying biofilm development in an ecologically relevant organism, but it also adds to our knowledge of bacterial adhesin diversity, emphasizing Bap-like proteins as widespread determinants of biofilm formation in bacteria.

1.Fermentable fibres such as inulin can support metabolic health but may exacerbate gastrointestinal symptoms in individuals with irritable bowel syndrome (IBS) due to rapid fermentation and gas production. The gel-forming fibre psyllium improves IBS symptoms, although the underlying mechanisms remain unclear. We hypothesised that fibre gelation alters fermentation by modulating microbial access to substrates. To test this, we compared psyllium with methylcellulose, a chemically modified, gel-forming fibre, to determine the effects of gelation on inulin fermentation. Inulin alone or combined with psyllium or methylcellulose was fermented for 48 hrs in a colonic fermentation model inoculated with healthy human faeces. Gas production, metabolite profiles, microbial community composition and microbial localisation within fibre gels were assessed. Bioactivity of fermentation products was evaluated in STC-1 cells. Psyllium co-fermentation significantly accelerated fermentation and enhanced production of metabolites, while methylcellulose had minimal effects. Psyllium maintained higher diversity and enriched polysaccharide-degrading taxa including Bacteroides and Phoecaeicola species, which were strongly associated with metabolic activity. Bacterial penetration into the psyllium matrix was observed but not into methylcellulose. Fermentation products from psyllium but not methylcellulose stimulated GLP-1 and 5-HT secretion in STC-1 cells. These findings demonstrate that delayed-onset fermentable gel-forming fibres enhance microbial access to entrapped substrates, driving metabolic and hormonal responses.

Although the microbial composition and functional attributes of kombucha have been extensively studied, the origins and mechanisms of the formation of their biofilm (Symbiotic Culture of Bacteria and Yeasts, or SCOBY) remain speculative. Based on historical reports and the concept of community coalescence, this study establishes a proof-of-concept, demonstrating how a kombucha-like biofilm can form spontaneously from microbes associated with plants, insects, and humans in a sweetened tea medium. Metagenomic analyses revealed microbial dynamics during fermentation, uncovering shifts in community composition driven by acetic acid bacteria, lactic acid bacteria, and yeasts. Comparative analyses with existing fermented beverages demonstrated microbial similarities to kombucha metagenomes. Pangenomic analyses focused on Fructobacillus evanidus, a species present in both the bee microbiome and our spontaneous fermentation. The MAGs of F. evanidus from the fermented beverage showed evidence of genetic streamlining, characterized by the loss of genes essential for survival in shifting and highly competitive environments, such as the bee gut, and adaptation to the more stable conditions of fermentation. This study offers insights into the origins of kombucha, integrating historical, microbiological, ecological and evolutionary perspectives to answer the question Is this a kombucha?, and gesturing toward further physical, chemical and sensory dimensions that could be explored.

Biofilm-associated diseases like peri-implant mucositis (PIM) and peri-implantitis (PI) are significant clinical challenges affecting millions of dental implant patients globally. Although studies have described the role of microbial, host, or environmental factors in disease development, their complex interplay, particularly during dysbiosis remains poorly understood. This cross-sectional study characterized the microbiome composition and metatranscriptomes of 125 peri-implant biofilms from 48 individuals uncovering molecular signatures linked to peri-implant health (PIH), PIM, and PI. Distinct variations were observed in biofilm amount, composition, activity, phage populations and host response. Biofilms were categorized into four community types (CTs) based on the bacterial transcriptional activity: one linked to PIH, one to PI, and two to PIM. PIH and PIM were primarily characterized by aerotolerant taxa with increased anabolic processes, while PI was dominated by obligate anaerobes with complex biofilm morphology, and heightened catabolic activity and virulence. PIM samples, relative to PIH were characterized by biofilm expansion with minimal functional changes, except for the Neisseria-rich PIM subtype showing higher pyruvate and lipoic acid metabolism. The phagome mirrored the bacterial compositional variations across disease states. Furthermore, human transcriptome responses varied indicating increased keratinization in PIH, enhanced expression of ribosome components in PIM, and inflammatory signaling and hypoxia in PI. Additionally, we identified complex species-enzyme, phage-bacteria, and host-microbe associations within the peri-implant ecosystem. Our integrative multi-omics approach provides a comprehensive view of microbial, biochemical, host, and ecological factors associated with dysbiosis, offering novel insights into peri-implant disease dynamics. ImportancePeri-implant mucositis and peri-implantitis are highly prevalent inflammatory conditions that compromise the long-term survival and success of dental implants, yet their underlying biological mechanisms are largely unresolved. While next-generation sequencing has advanced our understanding of microbial composition across health and peri-implant diseases, it falls short of capturing microbial activity and the broader molecular context of peri-implant dysbiosis. Metatranscriptomics overcomes this limitation by profiling actively transcribed genes within the biofilm, offering direct insights into microbial community functions. In this study, we integrated full-length 16S rRNA gene amplicon sequencing with metatranscriptomic profiling to simultaneously assess microbial taxonomy, functional activity, phage dynamics, and host gene expression in peri-implant biofilms. Importantly, we provide a systems-level view and report previously undescribed associations between different molecular signatures in peri-implant ecosystem.

Biofilm growth protects bacteria against harsh environments, antimicrobials, and immune responses. Helicobacter pylori is a bacterium that has a robust ability to maintain colonization in a challenging environment. Over the last decade, H. pylori biofilm formation has begun to be characterized, however, there are still gaps in our understanding about how this growth mode is defined and its impact on H. pylori physiology. To provide insights into H. pylori biofilm growth properties, we characterized the antibiotic susceptibility, gene expression, and genes required for biofilm formation of a strong biofilm-producing H. pylori. H. pylori biofilms developed complex 3D structures and were recalcitrant to multiple antibiotics. Disruption of the protein-based matrix decreased this antibiotic tolerance. Using both transcriptomic and genomic approaches, we discovered that biofilm cells demonstrated lower transcripts for TCA cycle enzymes but higher ones for hydrogenase and acetone metabolism. Interestingly, several genes encoding for the natural competence Type IV secretion system 4 (tfs4) were up-regulated during biofilm formation along with several genes encoding for restriction-modification (R-M) systems, suggesting DNA exchange activities in this mode of growth. Flagella genes were also discovered through both approaches, consistent with previous reports about the importance of these filaments in H. pylori biofilm. Together, these data suggest that H. pylori is capable of adjusting its phenotype when grown as biofilm, changing its metabolism and elevating specific surface proteins including those encoding tfs4 and flagella.

Mucosal biofilms play an important role in intestinal health; however, the mucosal bacterial community has been implicated in persistent infections. Clostridioides difficile is an important nosocomial pathogen, with an unacceptable high rate of recurrence following antibiotic treatment. As C. difficile is a known biofilm producer, a property which may contribute to this suboptimal therapeutic response, we have investigated the transcriptional changes and regulatory pathways during the transition from planktonic to biofilm mode of growth. Widespread metabolic reprogramming during biofilm formation was detected, characterised by an increased usage of glycine metabolic pathways to yield key metabolites, which are used for energy production and synthesis of short chain fatty acids. We detected the expression of 107 small non-coding RNAs that appear to, in some part, regulate these pathways; however, 25 of these small RNAs were specifically expressed during biofilm formation, indicating they may play a role in regulating biofilm-specific genes. Similar to Bacillus subtilis, biofilm formation is a multi-regulatory process and SinR negatively regulates biofilm formation independently of other known mechanisms. This comprehensive analysis furthers our understanding of biofilm formation in C. difficile, identifies potential targets for anti-virulence factors, and provides evidence of the link between metabolism and virulence traits.

Clostridioides difficile is a major cause of hospital-associated diarrhoea worldwide. The intricate interactions between C. difficile and the resident gut microbiota play a crucial role in determining the outcome of C. difficile infection (CDI), although the molecular mechanisms underlying many C. difficile-commensal interactions are not understood. Here we show that selected Bacteroides species can inhibit C. difficile growth within mixed biofilms. A transcriptomic analysis of C. difficile-Bacteroides biofilms showed significant metabolic shifts, with distinct changes in carbohydrate and amino acid metabolism and, interestingly, a downregulation of C. difficile toxin gene expression. A significant reduction in C. difficile toxin production was evident in C. difficile-Bacteroides cocultures, irrespective of the extent of C. difficile growth inhibition. Notably, Stickland fermentation of proline, which is known to repress toxin synthesis, was upregulated in C. difficile, while proline synthesis was induced in the cocultured species B. vulgatus and B. dorei. Furthermore, upregulation of proline reductase pathways and consequent toxin repression were evident within a synthetic 9-species gut commensal biofilm community containing multiple Bacteroides spp. Thus, leveraging multiomics approaches, we demonstrate a potential cross-feeding mechanism where proline produced by B. dorei and B. vulgatus is utilised by C. difficile through Stickland fermentation to drive toxin repression. Our study reveals a new mechanism of microbiota-mediated control of a key virulence factor involved in C. difficile pathogenesis while enabling pathogen co-existence within a polymicrobial commensal community. ImportanceC. difficile infection, characterised by severe diarrhoea and colitis, has a significant impact on healthcare settings globally due to the high rates of recurrence. CDI is closely associated with the gut microbiota status and the use of antibiotics, yet the mechanistic basis of interactions between the causative bacterium C. difficile and individual gut commensal species remains poorly defined. Here, we demonstrate inhibitory effects of Bacteroides species on C. difficile through nutrient competition and a cross-feeding mechanism between these abundant gut commensals and this pathogen which blocks expression of key C. difficile virulence factors. Our findings offer insights into the effective design of microbiota consortia to prevent and treat CDI.

Bacterial biofilms are surface-attached communities that are difficult to eradicate due to a high tolerance to antimicrobial agents. The use of non-biocidal surface-active compounds to prevent the initial adhesion and aggregation of bacterial pathogens is a promising alternative to antibiotic treatments and several antibiofilm compounds have been identified, including some capsular polysaccharides released by various bacteria. However, the lack of chemical and mechanistic understanding of the activity of these high-molecular-weight polymers limits their use for control of biofilm formation. Here, we screened a collection of 32 purified capsular polysaccharides and identified seven new compounds with non-biocidal activity against biofilms formed by Escherichia coli and/or Staphylococcus aureus. We analyzed the polysaccharide mobility under applied electric field conditions and showed that active and inactive polysaccharide polymers display distinct electrokinetic properties and that all active macromolecules shared high intrinsic viscosity features. Based on these characteristics, we identified two additional antibiofilm capsular polysaccharides with high density of electrostatic charges and their permeability to fluid flow. Our study therefore provides insights into key biophysical properties discriminating active from inactive polysaccharides. This characterization of a specific electrokinetic signature for polysaccharides displaying antibiofilm activity opens new perspectives to identify or engineer non-biocidal surface-active macromolecules to control biofilm formation in medical and industrial settings. Significance statementSome bacteria produce non-biocidal capsular polysaccharides that reduce the adhesion of bacterial pathogens to surfaces. Due to a lack of molecular and structural definition, the basis of their antiadhesion activity is unknown, thus hindering their prophylactic use for biofilm control. Here, we identified nine new active compounds and compared their composition, structure and biophysical properties with other inactive capsular polysaccharides. Despite the absence of specific molecular motif, we demonstrate that all active polysaccharides share common electrokinetic properties that distinguish them from inactive polymers. This characterization of the biophysical properties of antibiofilm bacterial polysaccharide provides key insights to engineer non-biocidal and bio-inspired surface-active compounds to control bacterial adhesion in medical and industrial settings.

ObjectiveGrowing evidence links bacterial dysbiosis with colorectal cancer (CRC) carcinogenesis, characterized by an increased presence of core pathogens such as Bacteroides fragilis and Fusobacterium nucleatum. Here, we characterized the in situ biogeography and transcriptional interactions between bacteria and the host in mucosal colon biopsies. DesignThe influence of CRC core pathogens and biofilms on the tumour microenvironment (TME) was investigated in biopsies from patients with and without CRC (paired normal tissue and healthy tissue biopsies) using fluorescence in situ hybridization and dual-RNA sequencing. ResultsTissue-invasive, mixed-species biofilms enriched for B. fragilis and F. nucleatum were observed in CRC tissue, especially in right-sided tumours. Fusobacterium spp. was associated with increased bacterial biomass and inflammatory response in CRC samples. CRC samples with high bacterial activity demonstrated increased expression of pro-inflammatory cytokines, defensins, matrix-metalloproteases, and immunomodulatory factors. In contrast, the gene expression profiles of CRC samples with low bacterial activity resembled healthy tissue samples. Moreover, immune cell profiling showed that B. fragilis and F. nucleatum modulated the TME and correlated with increased infiltration of neutrophils and CD4+ T-cells. Overall, bacterial activity was critical for the immune phenotype and correlated with the infiltration of several immune cell subtypes, including M2 macrophages and regulatory T-cells. ConclusionBiofilms and core pathogens shape the TME and immune phenotype in CRC. Our results support that Fusobacterium spp. may provide a future therapeutic target to reduce biofilms and the inflammatory response in the TME while highlighting the importance of widening the scope of bacterial pathogenesis in CRC beyond core pathogens.

Biofilms formed by Bacillus subtilis confer protection against environmental stressors through extracellular polysaccharides (EPS) and sporulation. This study investigates the roles of these biofilm components in resistance to hydrogen peroxide, a common reactive oxygen species source and disinfectant. Using wild-type and mutant strains deficient in EPS or sporulation, biofilm colonies were cultivated at various maturation stages and exposed to hydrogen peroxide. EPS-deficient biofilms exhibited reduced resilience, particularly in early stages, highlighting the structural and protective importance of the matrix. Mature biofilms demonstrated additional protective mechanisms, potentially involving TasA protein fibers. In contrast, sporulation showed limited contribution to hydrogen peroxide resistance, as survival was primarily matrix-dependent. These findings underscore the necessity of targeting EPS and other matrix components in anti-biofilm strategies, suggesting that hydrogen peroxide-based disinfection could be enhanced by combining it with complementary sporicidal treatments. This study advances our understanding of biofilm resilience, contributing to the development of more effective sterilization protocols.