Characterization of adhesion threads of Deinococcus geothermalis as type IV pili

Deinococcus geothermalis E50051 forms tenuous biofilms on paper machine surfaces. Field emission electron microscopy analysis revealed peritrichous appendages which mediated cell-to-surface and cell-to-cell interactions but were absent in planktonically grown cells. The major protein component of the extracellular extract of D. geothermalis had an N-terminal sequence similar to the fimbrial protein pilin annotated in the D. geothermalis DSM 11300 draft sequence. It also showed similarity to the type IV pilin sequence of D. radiodurans and several gram-negative pathogenic bacteria. Other proteins in the extract had N-terminal sequences identical to D. geothermalis proteins with conservative motifs for serine proteases, metallophosphoesterases, and proteins whose function is unknown. Periodic acid-Schiff staining for carbohydrates indicated that these extracellular proteins may be glycosylated. A further confirmation for the presence of glycoconjugates on the cell surface was obtained by confocal laser scanning imaging of living D. geothermalis cells stained with Amaranthus caudatus lectin, which specifically binds to galactose residues. The results indicate that the thread-like appendages of D. geothermalis E50051 are glycosylated type IV pili, bacterial attachment organelles which have thus far not been described for the genus Deinococcus.     

Engineering Deinococcus geothermalis for bioremediation of high-temperature radioactive waste environments

Deinococcus geothermalis is an extremely radiation-resistant thermophilic bacterium closely related to the mesophile Deinococcus radiodurans, which is being engineered for in situ bioremediation of radioactive wastes. We report that D. geothermalis is transformable with plasmids designed for D. radiodurans and have generated a Hg(II)-resistant D. geothermalis strain capable of reducing Hg(II) at elevated temperatures and in the presence of 50 Gy/h. Additionally, D. geothermalis is capable of reducing Fe(III)-nitrilotriacetic acid, U(VI), and Cr(VI). These characteristics support the prospective development of this thermophilic radiophile for bioremediation of radioactive mixed waste environments with temperatures as high as 55 degrees C.     

Engineering Deinococcus geothermalis for Bioremediation of High-Temperature Radioactive Waste Environments

Deinococcus geothermalis is an extremely radiation-resistant thermophilic bacterium closely related to the mesophile Deinococcus radiodurans, which is being engineered for in situ bioremediation of radioactive wastes. We report that D. geothermalis is transformable with plasmids designed for D. radiodurans and have generated a Hg(II)-resistant D. geothermalis strain capable of reducing Hg(II) at elevated temperatures and in the presence of 50 Gy/h. Additionally, D. geothermalis is capable of reducing Fe(III)-nitrilotriacetic acid, U(VI), and Cr(VI). These characteristics support the prospective development of this thermophilic radiophile for bioremediation of radioactive mixed waste environments with temperatures as high as 55°C.     

Physiology of resistant Deinococcus geothermalis bacterium aerobically cultivated in low-manganese medium

This dynamic proteome study describes the physiology of growth and survival of Deinococcus geothermalis, in conditions simulating paper machine waters being aerobic, warm, and low in carbon and manganese. The industrial environment of this species differs from its natural habitats, geothermal springs and deep ocean subsurfaces, by being highly exposed to oxygen. Quantitative proteome analysis using two-dimensional gel electrophoresis and bioinformatic tools showed expression change for 165 proteins, from which 47 were assigned to a function. We propose that D. geothermalis grew and survived in aerobic conditions by channeling central carbon metabolism to pathways where mainly NADPH rather than NADH was retrieved from the carbon source. A major part of the carbon substrate was converted into succinate, which was not a fermentation product but likely served combating reactive oxygen species (ROS). Transition from growth to nongrowth resulted in downregulation of the oxidative phosphorylation observed as reduced expression of V-type ATPase responsible for ATP synthesis in D. geothermalis. The battle against oxidative stress was seen as upregulation of superoxide dismutase (Mn dependent) and catalase, as well as several protein repair enzymes, including FeS cluster assembly proteins of the iron-sulfur cluster assembly protein system, peptidylprolyl isomerase, and chaperones. Addition of soluble Mn reinitiated respiration and proliferation with concomitant acidification, indicating that aerobic metabolism was restricted by access to manganese. We conclude that D. geothermalis prefers to combat ROS using manganese-dependent enzymes, but when manganese is not available central carbon metabolism is used to produce ROS neutralizing metabolites at the expense of high utilization of carbon substrate.     

Novel thermostable single-stranded DNA-binding protein (SSB) from Deinococcus geothermalis

To study the biochemical properties of single-stranded DNA-binding (SSB) protein from Deinococcus geothermalis (DgeSSB), we have cloned the ssb gene obtained by PCR and developed an overexpression system. The gene consists of an open reading frame of 900 nucleotides encoding a protein of 300 amino acids with a calculated molecular weight of 32.45 kDa. The amino acid sequence exhibits 43, 44 and 75% identity with Thermus aquaticus, Thermus thermophilus and Deinococcus radiodurans SSBs, respectively. We show that DgeSSB is similar to Thermus/Deinococcus SSB in its biochemical properties. DgeSSB includes two oligonucleotide/oligosaccharide-binding folds per monomer and functions as a homodimer. In fluorescence titrations with poly(dT), DgeSSB bound about 30 nt independent of the salt concentration, and the fluorescence was quenched by about 65%. In a complementation assay in Escherichia coli, DgeSSB took over the in vivo function of EcoSSB. DgeSSB is thermostable with half-lives of 50 min at 70°C and 5 min at 90°C. Hence, DgeSSB offers an attractive alternative for TaqSSB and TthSSB in their applications for molecular biology methods and for analytical purposes.     

Cloning, purification and characterization of a thermostable amylosucrase from Deinococcus geothermalis

Amylosucrase is a transglucosidase that catalyses the synthesis of an amylose-type polymer from sucrose, an abundant agro-resource. Here we describe a novel thermostable amylosucrase from the moderate thermophile Deinococcus geothermalis (DGAS). The dgas gene was cloned and expressed in Escherichia coli . The encoded enzyme was purified and characterized. DGAS displays a specific activity of 44 U mg⁻¹, an optimal temperature of 50 °C and a half-life of 26 h at 50 °C. Moreover, it produces an α-glucan at 50 °C, with an average degree of polymerization of 45 and a polymerization yield of 76%. DGAS is thus the most active and thermostable amylosucrase known to date.     

Architecture of Deinococcus geothermalis biofilms on glass and steel: a lectin study

Deinococcus geothermalis is resistant to chemical and physical stressors and forms tenuous biofilms in paper industry. The architecture of its biofilms growing on glass and on stainless acid proof steel was studied with confocal laser scanning microscopy and fluorescent lectins and nanobeads as in situ probes. Hydrophobic nanobeads adhered to the biofilms but did not penetrate to biofilm interior. In contrast, the biofilms were readily permeable towards many different lectins. A skeletal network of glycoconjugates, reactive with Dolichos biflorus and Maclura pomifera lectins, was prominent in the space inside the biofilm colony core but absent on the exterior. Cells in the core space of the biofilm were interconnected by a network of adhesion structures, reactive with Amaranthus caudatus lectin but with none of the 65 other tested lectins. The glycoconjugates connecting the individual cells to steel reacted with Phaseolus vulgaris lectin whereas those connecting to glass mainly reacted with A. caudatus lectin. Envelopes of all cells in the D. geothermalis biofilm reacted with several other lectins, with many different specificities. We conclude that numerous different glycoconjugates are involved in the adhesion and biofilm formation of D. geothermalis , possibly contributing its unique survival capacity when exposed to dehydration, biocidal chemicals and other extreme conditions.     

Biosynthesis of (+)-catechin glycosides using recombinant amylosucrase from Deinococcus geothermalis DSM 11300

Amylosucrase (ASase, EC 2.4.1.4) is a glucosyltransferase that hydrolyzes sucrose into glucose and fructose and produces amylose-like glucan polymers from the released glucose. (+)-Catechin is a plant polyphenolic metabolite having skin-whitening and antioxidant activities. In this study, the ASase gene from Deinococcus geothermalis (dgas) was expressed in Escherichia coli, while the recombinant DGAS enzyme was purified using a glutathione S-transferase fusion system. The (+)-catechin glycoside derivatives were synthesized from (+)-catechin using DGAS transglycosylation activity. We confirmed the presence of two major transglycosylation products using TLC. The (+)-catechin transglycosylation products were isolated using silica gel open column chromatography and recycling-HPLC. Two (+)-catechin major transfer products were determined through ¹H and ¹³C NMR to be (+)-catechin-3′-O-α-d-glucopyranoside with a glucose molecule linked to (+)-catechin and (+)-catechin-3′-O-α-D-maltoside with a maltose linked to (+)-catechin. The presence of (+)-catechin maltooligosaccharides in the DGAS reaction was also confirmed via recycling-HPLC and enzymatic analysis. The effects of various reaction conditions (temperature, enzyme concentration, and molar ratio of acceptor and donor) on the yield and type of (+)-catechin glycosides were investigated.     

Destruction of Deinococcus geothermalis biofilm by photocatalytic ALD and sol-gel TiO2 surfaces

The aim of the present work was to explore possibilities of photocatalytic TiO₂ coating for reducing biofilms on non-living surfaces. The model organism, Deinococcus geothermalis, known to initiate growth of durable, colored biofilms on machine surfaces in the paper industry, was allowed to form biofilms on stainless steel, glass and TiO₂ film coated glass or titanium. Field emission electron microscopy revealed that the cells in the biofilm formed at 45°C under vigorous shaking were connected to the surface by means of numerous adhesion threads of 0.1--0.3 μm in length. Adjacent cells were connected to one another by threads of 0.5--1 μm in length. An ultrastructural analysis gave no indication for the involvement of amorphous extracellular materials (e.g., slime) in the biofilm. When biofilms on photocatalytic TiO₂ surfaces, submerged in water, were exposed to 20 W h m⁻² of 360 nm light, both kinds of adhesion threads were completely destroyed and the D. geothermalis cells were extensively removed (from >10⁷ down to below 10⁶ cells cm⁻²). TiO₂ films prepared by the sol-gel technique were slightly more effective than those prepared by the ALD technique. Doping of the TiO₂ with sulfur did not enhance its biofilm-destroying capacity. The results show that photocatalytic TiO₂ surfaces have potential as a self-cleaning technology for warm water using industries.     

Structural investigation of the thermostability and product specificity of amylosucrase from the bacterium Deinococcus geothermalis

Amylosucrases are sucrose-utilizing α-transglucosidases that naturally catalyze the synthesis of α-glucans, linked exclusively through α1,4-linkages. Side products and in particular sucrose isomers such as turanose and trehalulose are also produced by these enzymes. Here, we report the first structural and biophysical characterization of the most thermostable amylosucrase identified so far, the amylosucrase from Deinoccocus geothermalis (DgAS). The three-dimensional structure revealed a homodimeric quaternary organization, never reported before for other amylosucrases. A sequence signature of dimerization was identified from the analysis of the dimer interface and sequence alignments. By rigidifying the DgAS structure, the quaternary organization is likely to participate in the enhanced thermal stability of the protein. Amylosucrase specificity with respect to sucrose isomer formation (turanose or trehalulose) was also investigated. We report the first structures of the amylosucrases from Deinococcus geothermalis and Neisseria polysaccharea in complex with turanose. In the amylosucrase from N. polysaccharea (NpAS), key residues were found to force the fructosyl moiety to bind in an open state with the O3' ideally positioned to explain the preferential formation of turanose by NpAS. Such residues are either not present or not similarly placed in DgAS. As a consequence, DgAS binds the furanoid tautomers of fructose through a weak network of interactions to enable turanose formation. Such topology at subsite +1 is likely favoring other possible fructose binding modes in agreement with the higher amount of trehalulose formed by DgAS. Our findings help to understand the inter-relationships between amylosucrase structure, flexibility, function, and stability and provide new insight for amylosucrase design.     

Quantitative contributions of bacteria and of Deinococcus geothermalis to deposits and slimes in paper industry

Deinococcus geothermalis has frequently been isolated from pink colored deposits of paper industry processes. Laboratory studies have shown that D. geothermalis is capable of forming on nonliving surfaces patchy biofilms that are resistant to adverse agents such as extreme pH, desiccation, solubilising detergents and biocides. This study was done to quantitatively assess the role of D. geothermalis as a biofouler in paper industry. Colored deposits were collected from 24 European and North American paper and board machines and the densities of the bacterial 16S rRNA genes and those of the red slime producers D. geothermalis and Meiothermus spp. were measured by QPCR (quantitative real time PCR). D. geothermalis was found at nine machines, usually from splash area deposits, but its contribution was minor, 0.001–1%, to the total bacterial burden of 8.3 to log 10.5 log units per gram wet-weight of the deposits. When D. geothermalis was found in a measurable quantity, Meiothermus spp. also was found, often in bulk quantity (7–100% of the total bacteria). The data are in line with the properties of D. geothermalis known from laboratory biofilm studies, indicating this species is a pioneer coloniser of machine surfaces and may help other bacteria to adhere and grown into biofilms, rather than competing with them.     

Mechanisms of biofilm formation in paper machine by Bacillus species: the role of Deinococcus geothermalis

Mechanisms for the undesired persistence of Bacillus species in paper machine slimes were investigated. Biofilm formation was measured for industrial Bacillus isolates under paper machine wet-end-simulating conditions (white water, pH 7, agitated at 45°C for 1–2 days). None of the 40 tested strains of seven Bacillus species formed biofilm on polished stainless steel or on polystyrene surfaces as a monoculture. Under the same conditions, Deinococcus geothermalis E50051 covered all test surfaces as a patchy thick biofilm. The paper machine bacilli, however, formed mixed biofilms with D. geothermalis E50051 as revealed by confocal microscopy. Biofilm interactions between the bacilli and the deinococci varied from synergism to antagonism. Synergism in biofilm formation of D. geothermalis E50051 was strongest with Bacillus coagulans D50192, and with the type strains of B. coagulans, B. amyloliquefaciens or B. pumilus. Two B. licheniformis, one B. amyloliquefaciens, one B. pumilus and four B. cereus strains antagonized biofilm production by D. geothermalis. B. licheniformis D50141 and the type strain of B. licheniformis were the strongest antagonists. These bacteria inhibited deinococcal growth by emitting heat-stable, methanol-soluble metabolite(s). We conclude that the persistence of Bacillus species in paper machine slimes relates to their ability to conquer biofilms formed by primary colonizers, such as D. geothermalis. Journal of Industrial Microbiology & Biotechnology (2001) 27, 343–351. Received 17 April 2001/ Accepted in revised form 16 July 2001     

Experimental and statistical analysis of nutritional requirements for the growth of the extremophile Deinococcus geothermalis DSM 11300

Few studies concerning the nutritional requirements of Deinococcus geothermalis DSM 11300 have been conducted to date. Three defined media compositions have been published for the growth of this strain but they were found to be inadequate to achieve growth without limitation. Furthermore, growth curves, biomass concentration and growth rates were generally not available. Analysis in Principal Components was used in this work to compare and consequently to highlight the main compounds which differ between published chemically defined media. When available, biomass concentration, and/or growth rate were superimposed to the PCA analysis. The formulations of the media were collected from existing literature; media compositions designed for the growth of several strains of Deinococcaceae or Micrococcaceae were included. The results showed that a defined medium adapted from Holland et al. (Appl Microbiol Biotechnol 72:1074–1082, 2006) was the best basal medium and was chosen for further studies. A growth rate of 0.03 h^?1 and a final OD_600nm of 0.55 were obtained, but the growth was linear. Then, the effects of several medium components on oxygen uptake and biomass production by Deinococcus geothermalis DSM 11300 were studied using a respirometry-based method, to search for the nutritional limitation. The results revealed that the whole yeast extract in the medium with glucose is necessary to obtain a non-limiting growth of Deinococcus geothermalis DSM 11300 at a maximum growth rate of 0.64 h^?1 at 45 °C.     

Two‐dimensional proteome reference map for the radiation‐resistant bacterium Deinococcus geothermalis

2‐DE reference maps for Deinococcus geothermalis cytosolic and cell envelope proteomes were constructed. In total, 403 spots were identified as 299 different proteins. Unique in the proteomes were four subunits of V‐type ATPase and Deinococcus specific proteins constituting one‐fourth of cell envelope proteome. The cytoplasmic proteome included enzymes of the central carbon metabolism, chaperones, enzymes of protein and DNA repair, and oxidative stress. A total of 34 abundant proteins with unknown function may relate to the extreme stress tolerance of D. geothermalis.     

High-temperature cultivation and 5' mRNA optimization are key factors for the efficient overexpression of thermostable Deinococcus geothermalis purine nucleoside phosphorylase in Escherichia coli

Overexpression of genes from thermophiles in Escherichia coli is an attractive approach towards the large-scale production of thermostable biocatalysts. However, various factors can challenge efficient heterologous protein expression--one example is the formation of stable 5' mRNA secondary structures that can impede an efficient translation initiation. In this work, we describe the expression optimization of purine nucleoside phosphorylase from the thermophilic microbe Deinococcus geothermalis in E. coli. Poor expression levels caused by stable secondary 5' mRNA structure formation were addressed by two different approaches: (i) increasing the cultivation temperature above the range used typically for recombinant protein expression and (ii) optimizing the 5' mRNA sequence for reduced secondary structures in the translation initiation region. The increase of the cultivation temperature from 30°C to 42°C allowed a more than 10-fold increase of activity per cell and optimizing the 5' mRNA gene sequence further increased the activity per cell 1.7-fold at 42°C. Thus, the combination of high-temperature cultivation and 5' sequence optimization is described as an effective approach to overcome poor expression levels resulting from stable secondary 5' mRNA structure formation. We suggest that this method is especially suitable for improving the expression of proteins derived from thermophiles in E. coli.     

Isolation and characterization of Deinococcus geothermalis T27, a slightly thermophilic and organic solvent-tolerant bacterium able to survive in the presence of high concentrations of ethyl acetate

A solvent-tolerant, slightly thermophilic bacterium was isolated at 45 degrees C in the presence of toluene vapor provided as the sole carbon source. Strain T27 was identified as Deinococcus geothermalis T27. It could tolerate high concentrations of solvent provided as a nonaqueous layer (5% and 20%, v/v) to a cell suspension and had a remarkable ability to tolerate a broad range of solvents having log P(ow) values ranging from 5.6 of n-decane to as low as 0.7 of ethyl acetate. It was also able to utilize some of the solvents tested as a growth substrate at 45 degrees C. The addition of Ca(2+) ion, glucose and fructose partially promoted solvent tolerance. Cells exposed to ethyl acetate appeared to have a smaller size; however, the cell structure was not altered and was apparently well defined even after solvent shock. The tolerance of D. geothermalis T27 in the presence of high levels of toxic solvent stress at a comparatively high temperature indicated its potential use in biotechnological applications as well as bioremediation of xenobiotics.     

Deinococcus misasensis and Deinococcus roseus, novel members of the genus Deinococcus, isolated from a radioactive site in Japan

Two gamma- and UV-radiation resistant, Gram-positive, red- or pink-pigmented, rod-shaped, strictly aerobic, oxidase- and catalase-positive bacterial strains, TDMA-25^T and TDMA-uv51^T, were isolated from fresh water collected at Misasa, a radioactive site in Japan. Phylogenetic analysis based on 16S rRNA gene sequences placed both in a distinct lineage in the family Deinococcaceae, and the highest degrees of sequence similarity determined belonged to Deinococcus maricopensis LB-34^T (88.8–89.3%), Deinococcus pimensis KR-235^T (86.4–86.7%) and Deinococcus yavapaiensis KR-236^T (86.1%). The DNA G+C content of the strains was 53–58 mol%. The major respiratory quinone was MK-8. The predominant fatty acids were C_15:0 iso, C_16:0 iso, C_13:0 iso, C_17:0 iso, C_16:0, C_13:0 anteiso, C_15:0 and C_12:0 iso. The strains degraded gelatin, casein, starch and Tween 80. Unique physiological characteristics, differences in their fatty acid profiles, and genotypic and phylogenetic features, differentiated strains TDMA-25^T and TDMA-uv51^T from closely related Deinococcus species. Hence, the two strains are described as novel species of the genus Deinococcus. The names Deinococcus misasensis sp. nov. (type strain TDMA-25^T=JCM 14369=NBRC 102116=CCUG 53610) and Deinococcus roseus sp. nov. (type strain TDMA-uv51^T=JCM 14370=NBRC 102117=CCUG 53611) are proposed.     

Isolation of cloned variants of a rat hepatoma cell line with altered attachment to collagen, but normal attachment to fibronectin

Cloned variants of a rat hepatoma cell line have been isolated which exhibit normal attachment and spreading behavior on fibronectin substrata, but which are defective in their ability to attach to native collagen films. These clones should be useful for identifying specific macromolecules involved in the cell-to-collagen interaction.     

Quantification of RecA protein in Deinococcus radiodurans reveals involvement of RecA,but not LexA,in its regulation

RecA protein is essential for the very high level of resistance of Deinococcus radiodurans to DNA damage induced by ionizing radiation or other DNA-damaging agents. Since the mechanism(s) involved in the control of recA expression and the extent of RecA induction following DNA damage in this species are still unclear, we have performed a genetic analysis of the recA locus and quantified the basal and induced levels of RecA protein in wild type, recA, and lexA mutants. We found that the two genes upstream of recA in the predicted cinA ligT recA operon appear to have no role in the regulation of recA expression or function, despite the fact that the reading frames in the operon overlap. By using a translational fusion of recA to a lacZ reporter gene, we showed that induction began with no delay following exposure to gamma-radiation or treatment with mitomycin, and continued at a constant rate until it reached a plateau. The induction efficiency increased linearly with inducer dose, levelling off at a concentration fourfold above the background. The basal concentration of RecA protein measured by Western blotting corresponded to approximately 11,000 monomers per cell, and the induced concentration to around 44,000 monomers per cell. These levels remained unchanged upon disruption of the lexA gene, indicating that LexA does not plays a role in recA regulation. However, inactivation of lexA caused cells to aggregate, suggesting that LexA may control the activity or expression of as yet undefined membrane functions. Cells bearing the recA670 mutation showed an elevated constitutive expression of recA in the absence of DNA damage. This phenotype did not result from the defect in DNA repair associated with the RecA670 protein, since the increased basal level of recA expression was also found in recA670/ recA(+) diploid cells that are proficient in DNA repair. These results suggest that RecA may be involved in regulating its own expression, possibly by stimulating proteolytic modification of other regulatory proteins.