PslG,a self-produced glycosyl hydrolase,triggers biofilm disassembly by disrupting exopolysaccharide matrix

Biofilms are surface-associated communities of microorganism embedded in extracellular matrix. Exopolysaccharide is a critical component in the extracellular matrix that maintains biofilm architecture and protects resident biofilm bacteria from antimicrobials and host immune attack. However, self-produced factors that target the matrix exopolysaccharides, are still poorly understood. Here, we show that PslG, a protein involved in the synthesis of a key biofilm matrix exopolysaccharide Psl in Pseudomonas aeruginosa, prevents biofilm formation and disassembles existing biofilms within minutes at nanomolar concentrations when supplied exogenously. The crystal structure of PslG indicates the typical features of an endoglycosidase. PslG mainly disrupts the Psl matrix to disperse bacteria from biofilms. PslG treatment markedly enhances biofilm sensitivity to antibiotics and macrophage cells, resulting in improved biofilm clearance in a mouse implant infection model. Furthermore, PslG shows biofilm inhibition and disassembly activity against a wide range of Pseudomonas species, indicating its great potential in combating biofilm-related complications.     

Extracellular nucleases and extracellular DNA play important roles in Vibrio cholerae biofilm formation

Biofilms are a preferred mode of survival for many microorganisms including Vibrio cholerae, the causative agent of the severe secretory diarrhoeal disease cholera. The ability of the facultative human pathogen V. cholerae to form biofilms is a key factor for persistence in aquatic ecosystems and biofilms act as a source for new outbreaks. Thus, a better understanding of biofilm formation and transmission of V. cholerae is an important target to control the disease. So far the Vibrio exopolysaccharide was the only known constituent of the biofilm matrix. In this study we identify and characterize extracellular DNA as a component of the Vibrio biofilm matrix. Furthermore, we show that extracellular DNA is modulated and controlled by the two extracellular nucleases Dns and Xds. Our results indicate that extracellular DNA and the extracellular nucleases are involved in diverse processes including the development of a typical biofilm architecture, nutrient acquisition, detachment from biofilms and the colonization fitness of biofilm clumps after ingestion by the host. This study provides new insights into biofilm development and transmission of biofilm-derived V. cholerae.     

Extracellular DNA is essential for maintaining Bordetella biofilm integrity on abiotic surfaces and in the upper respiratory tract of mice

Bacteria form complex and highly elaborate surface adherent communities known as biofilms which are held together by a self-produced extracellular matrix. We have previously shown that by adopting a biofilm mode of existence in vivo, the gram negative bacterial pathogens Bordetella bronchiseptica and Bordetella pertussis are able to efficiently colonize and persist in the mammalian respiratory tract. In general, the bacterial biofilm matrix includes polysaccharides, proteins and extracellular DNA (eDNA). In this report, we investigated the function of DNA in Bordetella biofilm development. We show that DNA is a significant component of Bordetella biofilm matrix. Addition of DNase I at the initiation of biofilm growth inhibited biofilm formation. Treatment of pre-established mature biofilms formed under both static and flow conditions with DNase I led to a disruption of the biofilm biomass. We next investigated whether eDNA played a role in biofilms formed in the mouse respiratory tract. DNase I treatment of nasal biofilms caused considerable dissolution of the biofilm biomass. In conclusion, these results suggest that eDNA is a crucial structural matrix component of both in vitro and in vivo formed Bordetella biofilms. This is the first evidence for the ability of DNase I to disrupt bacterial biofilms formed on host organs.     

The Extracellular Matrix Component Psl Provides Fast-Acting Antibiotic Defense in Pseudomonas aeruginosa Biofilms

Bacteria within biofilms secrete and surround themselves with an extracellular matrix, which serves as a first line of defense against antibiotic attack. Polysaccharides constitute major elements of the biofilm matrix and are implied in surface adhesion and biofilm organization, but their contributions to the resistance properties of biofilms remain largely elusive. Using a combination of static and continuous-flow biofilm experiments we show that Psl, one major polysaccharide in the Pseudomonas aeruginosa biofilm matrix, provides a generic first line of defense toward antibiotics with diverse biochemical properties during the initial stages of biofilm development. Furthermore, we show with mixed-strain experiments that antibiotic-sensitive “non-producing” cells lacking Psl can gain tolerance by integrating into Psl-containing biofilms. However, non-producers dilute the protective capacity of the matrix and hence, excessive incorporation can result in the collapse of resistance of the entire community. Our data also reveal that Psl mediated protection is extendible to E. coli and S. aureus in co-culture biofilms. Together, our study shows that Psl represents a critical first bottleneck to the antibiotic attack of a biofilm community early in biofilm development.     

酶制剂清除食源性致病菌生物被膜的研究进展

食源性致病菌对人类健康与公众安全造成了极大的危害,形成生物被膜加剧了它们的致病与耐药风险。酶具有高度专一性,可靶向作用于生物被膜中的特殊物质,从而清除食源性致病菌的生物被膜,具有重要的科研价值和广泛的应用前景。因此,文中系统地综述了相关酶制剂清除食源性致病菌生物被膜的研究进展。根据酶制剂的不同作用靶点,着重介绍了群体感应抑制酶、环二鸟苷酸代谢酶、胞外基质水解酶等酶制剂的研究现状。文中还针对抗生物被膜酶制剂的未来研究方向进行了展望,旨在为食源性致病菌生物被膜的有效控制提供新的技术与策略。     

The roles of biofilm matrix polysaccharide Psl in mucoid Pseudomonas aeruginosa biofilms

The opportunistic pathogen Pseudomonas aeruginosa causes life-threatening, persistent infections in patients with cystic fibrosis (CF). Persistence is attributed to the ability of these bacteria to form structured communities (biofilms). Biofilms rely on an extracellular polymeric substances matrix to maintain structure. Psl exopolysaccharide is a key matrix component of nonmucoid biofilms, yet the role of Psl in mucoid biofilms is unknown. In this report, using a variety of mutants in a mucoid P.?aeruginosa background, we found that deletion of Psl-encoding genes dramatically decreased their biofilm formation ability, indicating that Psl is also a critical matrix component of mucoid biofilms. Our data also suggest that the overproduction of alginate leads to mucoid biofilms, which occupy more space, whereas Psl-dependent biofilms are densely packed. These data suggest that Psl polysaccharide may have significant contributions in biofilm persistence in patients with CF and may be helpful for designing therapies for P.?aeruginosa CF infection.     

Prophage spontaneous activation promotes DNA release enhancing biofilm formation in Streptococcus pneumoniae

Streptococcus pneumoniae (pneumococcus) is able to form biofilms in vivo and previous studies propose that pneumococcal biofilms play a relevant role both in colonization and infection. Additionally, pneumococci recovered from human infections are characterized by a high prevalence of lysogenic bacteriophages (phages) residing quiescently in their host chromosome. We investigated a possible link between lysogeny and biofilm formation. Considering that extracellular DNA (eDNA) is a key factor in the biofilm matrix, we reasoned that prophage spontaneous activation with the consequent bacterial host lysis could provide a source of eDNA, enhancing pneumococcal biofilm development. Monitoring biofilm growth of lysogenic and non-lysogenic pneumococcal strains indicated that phage-infected bacteria are more proficient at forming biofilms, that is their biofilms are characterized by a higher biomass and cell viability. The presence of phage particles throughout the lysogenic strains biofilm development implicated prophage spontaneous induction in this effect. Analysis of lysogens deficient for phage lysin and the bacterial major autolysin revealed that the absence of either lytic activity impaired biofilm development and the addition of DNA restored the ability of mutant strains to form robust biofilms. These findings establish that limited phage-mediated host lysis of a fraction of the bacterial population, due to spontaneous phage induction, constitutes an important source of eDNA for the S. pneumoniae biofilm matrix and that this localized release of eDNA favors biofilm formation by the remaining bacterial population.     

How to build a biofilm: a fungal perspective

Biofilms are differentiated masses of microbes that form on surfaces and are surrounded by an extracellular matrix. Fungal biofilms, especially those of the pathogen Candida albicans, are a cause of infections associated with medical devices. Such infections are particularly serious because biofilm cells are relatively resistant to many common antifungal agents. Several in vitro models have been used to elucidate the developmental stages and processes required for C. albicans biofilm formation, and recent studies have begun to define biofilm genetic control. It is clear that cell-substrate and cell-cell interactions, hyphal differentiation and extracellular matrix production are key steps in biofilm development. Drug resistance is acquired early in biofilm formation, and appears to be governed by different mechanisms in early and late biofilms. Quorum sensing might be an important factor in dispersal of biofilm cells. The past two years have seen the emergence of several genomic strategies to uncover global events in biofilm formation and directed studies to understand more specific events, such as hyphal formation, in the biofilm setting.     

细菌生物被膜基质的研究进展

细菌生物被膜(biofilm)附着在生物或者非生物表面,由细菌及其分泌的糖、蛋白质和核酸等多种基质组成的细菌群落,是造成病原细菌持续性感染、毒力和耐药性的重要原因之一.细菌的生物被膜基质由复杂的胞外聚合物(extracellular polymeric substances,EPS)构成,影响生物被膜的结构和功能.本文...     

Functional Amyloid and Other Protein Fibers in the Biofilm Matrix

Biofilms are ubiquitous in the natural and man-made environment. They are defined as microbes that are encapsulated in an extracellular, self-produced, biofilm matrix. Growing evidence from the genetic and biochemical analysis of single species biofilms has linked the presence of fibrous proteins to a functional biofilm matrix. Some of these fibers have been described as functional amyloid or amyloid-like fibers. Here we provide an overview of the biophysical and biological data for a wide range of protein fibers found in the biofilm matrix of Gram-positive and Gram-negative bacteria.     

Microbial Exopolymers Link Predator and Prey in a Model Yeast Biofilm System

Protistan grazing on biofilms is potentially an important conduit enabling energy flow between microbial trophic levels. Contrary to the widely held assumption that protistan feeding primarily involves ingestion of biofilm cells, with negative consequences for the biofilm, this study demonstrated preferential grazing on the noncellular biofilm matrix by a ciliate, with selective ingestion of yeast and bacterial cells of planktonic origin over attached and biofilm-derived planktonic cells. Introducing a ciliate to two biofilm-forming Cryptococcus species, as well as two bacterial species in a model biofilm system, fluorescent probes were applied to determine ingestion of cellular and noncellular biofilm fractions. Fluoromicroscopy, as well as photometric quantification, confirmed that protistan grazing enhanced yeast biofilm metabolism, and an increase in biofilm biomass and viability. We propose that the extracellular polymeric matrix of biofilms may act as an interface regulating interaction between predator and prey, while serving as source of nutrients and energy for protists.     

Effects of carbon and oxygen limitations and calcium concentrations on biofilm removal processes

Bacterial biofilm removal processes due to shear and catastrophic sloughing have been investigated in a turbulent flow system under conditions of carbon versus oxygen substrate limitations and varying aqueous phase calcium concentrations. Biofilm cellular and extracellular polymer carbon, total biofilm carbon and mass, and biofilm calcium concentrations are measured for pure culture biofilms of the facultative aerobe, Pseudomonas putida ATCC 11172. Results indicate oxygen-limited biofilms reach a higher steady-state biofilm organic carbon level than carbon-limited biofilms. Oxygen-limited biofilms also exhibit (1) a higher extracellular polymer-carbon: cell-carbon ratio throughout biofilm development and (2) a higher biofilm calcium content than carbon-limited biofilms. Increasing aqueous phase calcium concentrations increase the amount of biofilm calcium in both cases; the rate of calcium accumulation in oxygen-limited biofilms increases with increasing liquid phase calcium concentrations over the entire range studied while the rates of calcium accumulation in carbon-limited biofilms appear independent of aqueous phase calcium concentrations above 11.0 mg/L. Oxygen-limited biofilms with their higher extracellular polymer and calcium content exhibit shear removal rates that are 20-40% of those observed for carbon-limited biofilms. However, it is the oxygen-limited biofilms that experience catastrophic sloughing events. The carbon-limited biofilms studied here never sloughed even if subjected to intentional long-term deprivation of all nutrients. Reduced shear removal and the susceptibility to sloughing of the oxygen-limited biofilms are attributed to their more cohesive structure bought about by their relatively greater extracellular polymer production.     

Relevance of Polymeric Matrix Enzymes During Biofilm Formation

Extracellular polymeric substances (EPS) contribute to biofilm stability and adhesion properties. The EPS matrix might also be a site for free extracellular enzyme activity; however, little is known about participation of enzyme activity in EPS during biofilm formation. In this study, we analyzed the activities of beta-glucosidase, leu-aminopeptidase, and beta-glucosaminidase during the colonization of artificial substrata (glass tiles) in a stream distinguishing enzyme activity in EPS matrix (matrix-enzymes) and total biofilm extracellular enzyme activity. The 1-h incubation of a biofilm suspension and cation-exchange resin followed by centrifugation seems appropriate to extract the matrix fraction (supernatant) and measure matrix enzymes (including free and linked to EPS) in freshwater biofilms, although there is a methodological limitation for using a biofilm suspension instead of an undisrupted biofilm. Total biofilm activities and matrix-enzyme activities showed similar capabilities to decompose organic matter compounds, with a greater capacity for peptide decomposition (leu-aminopeptidase) than for polysaccharides (beta-glucosidase), and a low decomposition of chitin and peptidoglycan (beta-glucosaminidase). Matrix-enzyme activity increased with colonization time, but more slowly than that of total enzyme activity. At the beginning of the colonization experiment (days 1-4) matrix enzymes accounted for 65-81% of total biofilm enzyme activity. Higher proportion of polysaccharides in EPS versus total biofilm, and higher matrix-enzyme activities per microgram of polysaccharides in the EPS were measured during the first 1-3 days of biofilm formation, indicating a high rate of enzyme release into the matrix during this period. Relative contribution of matrix-enzyme activities decreased as biofilm matures, but was maintained at 13-37% of total enzyme activity at the 42- to 49-day-old biofilm. These enzymes, retained and conserved in the EPS, may contribute to community metabolism. When analyzing extracellular enzymes in biofilms, the contribution of matrix enzymes must be considered, especially for young biofilms.     

Inhibitory effect of the human liver-derived antimicrobial peptide hepcidin 20 on biofilms of polysaccharide intercellular adhesin (PIA)-positive and PIA-negative strains of Staphylococcus epidermidis

Staphylococcus epidermidis plays a major role in biofilm-related medical device infections. Herein the anti-biofilm activity of the human liver-derived antimicrobial peptide hepcidin 20 (hep20) was evaluated against polysaccharide intercellular adhesin (PIA)-positive and PIA-negative clinical isolates of S. epidermidis. Hep20 markedly inhibited biofilm formation and bacterial cell metabolism of PIA-positive and PIA-negative strains, but the decrease in biofilm biomass only partially correlated with a decrease in viable bacteria. Confocal microscope images revealed that, in the presence of hep20, both PIA-positive and PIA-negative strains formed biofilms with altered architectures and reduced amounts of extracellular matrix. Co-incubation of hep20 with vancomycin produced no synergistic effect, evaluated as number of viable cells, both in preventing biofilm formation and in treating preformed biofilms. In contrast, biofilms obtained in the presence of hep20, and then exposed to vancomycin, displayed an increased susceptibility to vancomycin. These results suggest that hep20 may inhibit the production/accumulation of biofilm extracellular matrix.     

Candida albicans biofilm development, modeling a host-pathogen interaction

Medical device-associated infections involve the attachment of cells to a surface, production of an extracellular matrix and development of a mature biofilm. Many Candida albicans disease states involve biofilm growth. These infections have great impact on public health because organisms in biofilms exhibit dramatically reduced susceptibility to antifungal therapy. Progression to a mature biofilm is dependent on cell adhesion, extracellular matrix production and the yeast-to-hyphae transition. Numerous in vitro biofilm model systems have been successfully used to examine biofilm architecture, development, cell phenotypes and drug resistance. Although these studies have included a number of experimental variables to mimic infections in patients, it is difficult to accurately account for the multitude of host and infection-site variables that are probably important in humans. Recent studies have begun to explore C. albicans biofilms using animal biofilm infection models in order to more completely reflect the complexity of this host-fungal interaction.     

The hmsHFRS operon of Xenorhabdus nematophila is required for biofilm attachment to Caenorhabditis elegans

The bacterium Xenorhabdus nematophila is an insect pathogen and an obligate symbiont of the nematode Steinernema carpocapsae. X. nematophila makes a biofilm that adheres to the head of the model nematode Caenorhabditis elegans, a capability X. nematophila shares with the biofilms made by Yersinia pestis and Yersinia pseudotuberculosis. As in Yersinia spp., the X. nematophila biofilm requires a 4-gene operon, hmsHFRS. Also like its Yersinia counterparts, the X. nematophila biofilm is bound by the lectin wheat germ agglutinin, suggesting that beta-linked N-acetyl-D-glucosamine or N-acetylneuraminic acid is a component of the extracellular matrix. C. elegans mutants with aberrant surfaces that do not permit Yersinia biofilm attachment also are resistant to X. nematophila biofilms. An X. nematophila hmsH mutant that failed to make biofilms on C. elegans had no detectable defect in symbiotic association with S. carpocapsae, nor was virulence reduced against the insect Manduca sexta.     

Biofilms and their impact on the food industry

Biofilm could be defined as a complex communities of microorganisms seen affixed to surfaces, they form clusters without sticking to any surface and buried firmly in an extracellular matrix (ECM). This matrix is formed by microorganisms in the formation of either extracellular polymeric substances (EPSS) or extracellular polymer. Many reviews have addressed the negative consequences of biofilm production in the food industry, among which we talk about biofilms being responsible for spoilage microorganisms and foodborne pathogens such as Listeria monocytogenes, Bacillus cereus etc. These contamination could be linked to biofilms presence in the processing plant. Although researches have tried conferring solutions to these challenges in the food industry, however, in this review we have tried to focus on the positive impact of biofilms formed in the food industry. It is critically expedient while trying to find the solution to the challenges of biofilm in the food industry to develop and give a major focus on the advantages and positive impact biofilm has in the food industry, which has been greatly neglected. Hence in this article, we have highlighted some positive impacts of biofilms formed in the food industry, like enhancing plant health and productivity of food products, as an agent of water and wastewater treatment in the food industry, as a tool in reducing the amount of excess sludge in the wastewater treatment plant. The development of edible biofilms, fermented food products and the production of biodegradable food packaging are also part of biofilms beneficial roles in the food industries.     

Rapid metabolic profiling of developing Pseudomonas aeruginosa biofilms by high-resolution mass spectrometry fingerprinting

Biofilms are single- or multi-species communities of bacteria that are enclosed in an extracellular matrix. These cells generally exhibit phenotypes that are significantly different from those of planktonic cells, yet detailed elucidation of the causality and the exact nature of this metabolic shift remains challenging. Considering the strong correlation of biofilms with pathogenicity and disease in the clinic, as well as the veritable economic impact of biofilms in other areas, a methodology for in-vivo monitoring of biofilm development is necessary. Here, we present high-resolution mass spectrometry fingerprinting as a rapid, sensitive, and generic technique for online, non-invasive monitoring of developing biofilms. The opportunistic pathogen Pseudomonas aeruginosa is used as a model system, and it is demonstrated that strain- and time-dependent changes in biofilm extracellular metabolites are easily detected.     

Extracellular polymeric substances from Shewanella sp. HRCR-1 biofilms: characterization by infrared spectroscopy and proteomics

The composition of extracellular polymeric substances (EPS) from Shewanella sp. HRCR-1 biofilms was investigated using infrared spectroscopy and proteomics to provide insight into potential ecophysiological functions and redox activity of the EPS. Both bound and loosely associated EPS were extracted from Shewanella sp. HRCR-1 biofilms prepared using a hollow-fibre membrane biofilm reactor. Fourier transform infrared spectra revealed the presence of proteins, polysaccharides, nucleic acids, membrane lipids and fatty acids in the EPS fractions. Using a global proteomic approach, a total of 58 extracellular and outer membrane proteins were identified in the EPS. These included homologues of multiple Shewanella oneidensis MR-1 proteins that potentially contribute to key physiological biofilm processes, such as biofilm-promoting protein BpfA, surface-associated serine protease, nucleotidases (CpdB and UshA), an extracellular lipase, and oligopeptidases (PtrB and a M13 family oligopeptidase lipoprotein). In addition, 20 redox proteins were found in extracted EPS. Among the detected redox proteins were the homologues of two S. oneidensis MR-1 c-type cytochromes, MtrC and OmcA, which have been implicated in extracellular electron transfer. Given their detection in the EPS of Shewanella sp. HRCR-1 biofilms, c-type cytochromes may contribute to the possible redox activity of the biofilm matrix and play important roles in extracellular electron transfer reactions.