SummaryThe Gram-negative metal ion-reducing bacterium Shewanella oneidensis MR-1 is motile by means of a single polar flagellum. We identified two potential stator systems, PomAB and MotAB, each individually sufficient as a force generator to drive flagellar rotation. Physiological studies indicate that PomAB is sodium-dependent while MotAB is powered by the proton motive force. Flagellar function mainly depends on the PomAB stator; however, the presence of both stator systems under low-sodium conditions results in a faster swimming phenotype. Based on stator homology analysis we speculate that MotAB has been acquired by lateral gene transfer as a consequence of adaptation to a low-sodium environment. Expression analysis at the single cell level showed that both stator systems are expressed simultaneously. An active PomB-mCherry fusion protein effectively localized to the flagellated cell pole in 70-80% of the population independent of sodium concentrations. In contrast, polar localization of MotB-mCherry increased with decreasing sodium concentrations. In the absence of the Pom stator, MotB-mCherry localized to the flagellated cell pole independently of the sodium concentration but was rapidly displaced upon expression of PomAB. We propose that selection of the stator occurs at the level of protein localization in response to sodium concentrations.
BackgroundBiofilm formation has been studied in much detail for a variety of bacterial species, as it plays a major role in the pathogenicity of bacteria. However, only limited information is available for the development of archaeal communities that are frequently found in many natural environments.MethodologyWe have analyzed biofilm formation in three closely related hyperthermophilic crenarchaeotes: Sulfolobus acidocaldarius, S. solfataricus and S. tokodaii. We established a microtitre plate assay adapted to high temperatures to determine how pH and temperature influence biofilm formation in these organisms. Biofilm analysis by confocal laser scanning microscopy demonstrated that the three strains form very different communities ranging from simple carpet-like structures in S. solfataricus to high density tower-like structures in S. acidocaldarius in static systems. Lectin staining indicated that all three strains produced extracellular polysaccharides containing glucose, galactose, mannose and N-acetylglucosamine once biofilm formation was initiated. While flagella mutants had no phenotype in two days old static biofilms of S. solfataricus, a UV-induced pili deletion mutant showed decreased attachment of cells.ConclusionThe study gives first insights into formation and development of crenarchaeal biofilms in extreme environments.
The thermoacidophilic crenarchaeote Sulfolobus acidocaldarius displays three distinct type IV pili-like structures on its surface: (i) the flagellum, (ii) the UV-induced pili and (iii) the adhesive pili. In bacteria, surface appendages play an important role in the spatial organization of cells from initial surface attachment to the development of mature community structures. To investigate the influence of the diverse set of type IV pili-like structures in S. acidocaldarius, single, double and triple mutants lacking the cell surface appendages were constructed and analysed for their behaviour in attachment assays and during biofilm formation. A heat stable green fluorescent protein was employed the first time in a hyperthermophilic archaeon. A codon adjusted eCGP123 was expressed to study mixed biofilms of different deletion mutants to understand the interplay of the surface structures during biofilm formation. During this process the deletion of the adhesive pili and UV-induced pili led to the most pronounced effects, either an increase in cell density or increased cluster formation respectively. However, all three cell surface appendages played a role in the colonization of surfaces and only the interplay of all three appendages leads to the observed wild-type biofilm phenotype.
Attachment of microorganisms to surfaces is a prerequisite for colonization and biofilm formation. The hyperthermophilic crenarchaeote Sulfolobus solfataricus was able to attach to a variety of surfaces, such as glass, mica, pyrite, and carbon-coated gold grids. Deletion mutant analysis showed that for initial attachment the presence of flagella and pili is essential. Attached cells produced extracellular polysaccharides containing mannose, galactose, and N-acetylglucosamine. Genes possibly involved in the production of the extracellular polysaccharides were identified.In microbiology, organisms are isolated from their natural habitats and typically cultivated in the laboratory as planktonic species. Though this method has been essential for understanding the concept of life, it remains unclear how microbial ecosystems operate. For bacteria, it is well known that they are able to form large cellular communities with highly complex cellular interactions and symbioses between different microbial or eukaryotic species. Biofilm formation is an essential component of such communities, and studies have shown that bacteria within biofilms are physiologically different from planktonic ones (20,21). They can exhibit extensive networks of pili on their surfaces and produce and secrete extracellular polysaccharides (EPS), their growth rate is decreased, and cells are much more resistant to physical stresses and antibiotics (19).The study of surface colonization and cellular communities of archaea is crucial for understanding their ecological properties. The only detailed study showed that the hyperthermophilic organism Archaeoglobus fulgidus produced biofilms when challenged with heavy metals and pentachlorophenol (10). Pyrococcus furiosus was able to adhere to different surfaces, such as mica and carbon-coated gold grids, and cells were connected via cable-like bundles of flagella (12). Methanopyrus kandleri was shown to adhere to glass, but P. furiosus could colonize only by attaching to M. kandleri cells, using flagella and direct cell contacts (16).Here we report on the function of cell surface appendages in initial attachment to surfaces of archaea, using directed gene inactivation mutants. The crenarchaeote Sulfolobus solfataricus P2 is a thermoacidophile which grows optimally at 80°C and pH values of 2 to 4 (22). S. solfataricus possesses cell surface structures such as flagella and UV-induced pili (1, 2). The flagellum operon of S. solfataricus encodes, in addition to the structural subunit FlaB, four proteins of unknown function, the ATPase FlaI, and the only integral membrane protein, FlaJ. Previously, we isolated a ⌬flaJ mutant which was nonflagellated and had lost its ability for surface motility on Gelrite plates (17). Recently, we described UV-inducible pili in S. solfataricus that directed cellular aggregation after UV stress (8). Deletion of the central ATPase UpsE, responsible for pilus assembly, rendered cells devoid of pili and defective in cellular aggregation after UV treatment (8). In this study, wild...
SUMMARY Conserved C-terminal domains (CTD) have been shown to act as a signal for the translocation of certain proteins across the outer membrane of Bacteroidetes via a type IX secretion system (T9SS). The genome sequence of the periodontal pathogen Tannerella forsythia predicts the presence of the components for a T9SS in conjunction with a suite of CTD proteins. T. forsythia is covered with a 2-dimensional crystalline surface (S-) layer composed of the glycosylated CTD proteins TfsA and TfsB. To investigate if T9SS is functional in T. forsythia, T9SS-deficient mutants were generated by targeting either TF0955 (putative C-terminal signal peptidase) or TF2327 (PorK ortholog), and the mutants were analyzed with respect to secretion, assembly and glycosylation of the S-layer proteins as well as to proteolytic processing of the CTD and biofilm formation. In either mutant, TfsA and TfsB were incapable of translocation, as evidenced by the absence of the S-layer in transmission electron microscopy of ultrathin-sectioned bacterial cells. Despite entrapped within the periplasm, mass spectrometry analysis revealed that the S-layer proteins were modified with the complete, mature glycan found on the secreted proteins, indicating that protein translocation and glycosylation are two independent processes. Further, the T9SS mutants showed a denser biofilm with less voids compared to the wild-type. This study demonstrates the functionality of T9SS and the requirement of CTD for the outer membrane passage of extracellular proteins in T. forsythia, exemplified with the two S-layer proteins. In addition, T9SS protein translocation is decoupled from O-glycan attachment in T. forsythia.
Optical probes for monitoring, imaging, and sensing of pH are of great interest for the scientific community as pH is a crucial marker for many processes in biotechnology, biology, medical diagnostics, biomedical research, and material corrosion. Thereby, optical pH sensors based on fluorescence have attracted interest in particular as fluorescence offers a high sensitivity down to the single molecule level, can be read out with relatively simple and readily miniaturized instrumentation, and allows online in situ measurements. Also the versatility ranging from molecular and nanosensor formats to planar optodes and fiber-optic sensors, and the non-invasive, non-destructive, and contactless nature of the measurement are application-friendly features. The information content, which is offered by a fluorescence intensity-based sensor, is usually unspecific and limited on the presence or the absence of the chromophore or analyte and can additionally be hampered by fluctuation of the excitation light intensity and changes in fluorophore concentration, e.g., due to photobleaching. Therefore, many fluorescence sensors are utilized in referenced systems, which enable twowavelength ratiometric measurements of the fluorescence intensity by the introduction of an analyte-inert reference with a spectrally distinguishable emission. This work presents the rational design of a versatile, modular, multi-component-based platform for ratiometric optical analyte sensing that can be simply adapted to different formats and measurement geometries. Therefore, readily available analyte-responsive fluorescent boron-dipyrromethene (BODIPY) dyes and near infrared (NIR)-excitable multicolour-Partikelgrößen wurden dafür via Transmissionselektronenmikroskopie (TEM) und Kleinwinkel-Röntgenstreuung (SAXS) bestimmt. Neben der Partikelgröße konnten durch die TEM-Messungen auch Informationen über die Kristallphasen der Nanopartikel erhalten werden. Neben der Erfassung des Partikelwachstums wurde die UCL der UCNPs für die ratiometrische Sensorplattform als Nanolampe und gleichzeitig als Referenzsignal verwendet. Die blaue Upconversion(UC)-Emission der NaYF 4 :Yb 3+ /Tm 3+ UCNPs wurde dabei zur Anregung der pH-sensitiven BODIPY-Farbstoffe verwendet, während die rote UC-Emission als inertes Referenzsignal verwendet wurde. Die Berechnung des Verhältnisses der Emissionsintensitäten der grünen Fluoreszenz des Farbstoffs und der roten UC-Emission des Partikels ermöglicht eine Bestimmung des pH-Werts. Das Potenzial dieser Strategie zur Erfassung des pH-Werts wurde beispielhaft für die Bestimmung der zeitabhängigen Änderungen des pH-Werts einer metabolisierenden Escherichia coli (E. coli)-Suspension gezeigt.
SummaryNeisseria gonorrhoeae is an obligate human pathogen that colonizes the genital tract and causes gonorrhoea. Neisseria gonorrhoeae can form biofilms during natural cervical infections, on glass and in continuous flow-chamber systems. These biofilms contain large amounts of extracellular DNA, which plays an important role in biofilm formation. Many clinical isolates contain a gonococcal genetic island that encodes a type IV secretion system (T4SS). The T4SS of N. gonorrhoeae strain MS11 secretes ssDNA directly into the medium. Biofilm formation, studied in continuous flow-chamber systems by confocal laser scanning microscopy (CLSM), was strongly reduced, especially in the initial phases of biofilm formation, in the presence of Exonuclease I, which specifically degrades ssDNA or in a ΔtraB strain that does not secrete ssDNA. To specifically detect ssDNA in biofilms using CLSM, a novel method was developed in which thermostable fluorescently labelled ssDNAand ss/dsDNA-binding proteins were used to visualize ssDNA and total DNA in biofilms and planktonic cultures. Remarkably, mainly dsDNA was detected in biofilms of the ssDNA secreting strain. We conclude that the secreted ssDNA facilitates initial biofilm formation, but that the secreted ssDNA is not retained in mature biofilms.
Microorganisms in nature often live in surface-associated sessile communities, encased in a self-produced matrix, referred to as biofilms. Biofilms have been well studied in bacteria but in a limited way for archaea. We have recently characterized biofilm formation in three closely related hyperthermophilic crenarchaeotes: Sulfolobus acidocaldarius, S. solfataricus, and S. tokodaii. These strains form different communities ranging from simple carpet structures in S. solfataricus to high density tower-like structures in S. acidocaldarius under static condition. Here, we combine spectroscopic, proteomic, and transcriptomic analyses to describe physiological and regulatory features associated with biofilms. Spectroscopic analysis reveals that in comparison to planktonic life-style, biofilm life-style has distinctive influence on the physiology of each Sulfolobus spp. Proteomic and transcriptomic data show that biofilm-forming life-style is strain specific (eg ca. 15% of the S. acidocaldarius genes were differently expressed, S. solfataricus and S. tokodaii had ∼3.4 and ∼1%, respectively). The -omic data showed that regulated ORFs were widely distributed in basic cellular functions, including surface modifications. Several regulated genes are common to biofilm-forming cells in all three species. One of the most striking common response genes include putative Lrs14-like transcriptional regulators, indicating their possible roles as a key regulatory factor in biofilm development.
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