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Institute: search.filters.UBSInstitut.Institut für MikrobiologiePublication Type: search.filters.UBSTyp.Zeitschriftenartikel

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    Die Spaltung von Arylether-Bindungen durch initiale Dioxygenierung: Grundlage des bakteriellen Dioxinabbaus
    (1991) Engesser, Karl-Heinrich; Strubel, Volker; Kirchner, S.; Schestag, S.; Schulte, P.; Knackmuss, Hans-Joachim
    Bei der Untersuchung des bakteriellen Abbaus von Arylether-Modellsubstraten wie 2-Alkoxybenzoat, Carboxybiphenylether und Dibenzofuran wurde ein grundlegender Mechanismus für die Spaltung von Aryletherbindungen aufgedeckt. Demnach bewirken Dioxygenase-Enzyme unter Einführung zweier Hydroxylgruppen die Überführung von Ether- in Hemiacetalbindungen. Diese instabilen Hemiacetale reagieren unter Rearomatisierung zu aliphatischen Alkoholen und/oder Phenolverbindungen ab. Enzyme dieses Typs sind auch in der Lage, Dioxine zu spalten.
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    Microbial metabolism of chlorosalicylates: effect of prolonged subcultivation on constructed strains
    (1986) Rubio, Miguel Angel; Engesser, Karl-Heinrich; Knackmuss, Hans-Joachim
    The hybrid strain Pseudomonas sp. WR4016 was subcultivated with increasing concentrations of 5-chlorosalicylate (5rarr10 mM) as sole carbon source over a period of 9 months. At intervals of approximately 3 months derivative strains WR4017, WR4018 and WR4019 were isolated which exhibited higher growth rates and increased substrate tolerance. Comparative analysis of the turnover rates of the key enzymes in chlorosalicylate degradation showed that the adaptation process did not result from structural modifications of these proteins. Instead, balanced over-production of the salicylate hydroxylase and catechol 1,2-dioxygenase prevented the accumulation of toxic chlorocatechols and accounted for the reduction of the doubling times with 4- or 5-chlorosalicylate. A comparative analysis of a genetically engineered chlorosalicylate degrader PL300-1 showed similar regulatory patterns as the most advanced isolate WR4019 from the adaptation series.
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    A universal polyphosphate kinase : PPK2c of Ralstonia eutropha accepts purine and pyrimidine nucleotides including uridine diphosphate
    (2020) Hildenbrand, Jennie C.; Teleki, Attila; Jendrossek, Dieter
    Polyphosphosphate kinases (PPKs) catalyse the reversible transfer of the γ-phosphate group of a nucleoside-triphosphate to a growing chain of polyphosphate. Most known PPKs are specific for ATP, but some can also use GTP as a phosphate donor. In this study, we describe the properties of a PPK2-type PPK of the β-proteobacterium Ralstonia eutropha. The purified enzyme (PPK2c) is highly unspecific and accepts purine nucleotides as well as the pyridine nucleotides including UTP as substrates. The presence of a polyP primer is not necessary for activity. The corresponding nucleoside diphosphates and microscopically detectable polyphosphate granules were identified as reaction products. PPK2c also catalyses the formation of ATP, GTP, CTP, dTTP and UTP from the corresponding nucleoside diphosphates, if polyP is present as a phosphate donor. Remarkably, the nucleoside-tetraphosphates AT(4)P, GT(4)P, CT(4)P, dTT(4)P and UT(4)P were also detected in substantial amounts. The low nucleotide specificity of PPK2c predestines this enzyme in combination with polyP to become a powerful tool for the regeneration of ATP and other nucleotides in biotechnological applications. As an example, PPK2c and polyP were used to replace ATP and to fuel the hexokinase-catalysed phosphorylation of glucose with only catalytic amounts of ADP.
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    Degradation of 2-bromo-, 2-chloro- and 2-fluorobenzoate by Pseudomonas putida CLB 250
    (1989) Engesser, Karl-Heinrich; Schulte, P.
    Pseudomonas putida strain CLB 250 (DSM 5232) utilized 2-bromo-, 2-chloro- and 2-fluorobenzoate as sole source of carbon and energy. Degradation is suggested to be initiated by a dioxygenase liberating halide in the first catabolic step. After decarboxylation and rearomatization catechol is produced as a central metabolite which is degraded via the ortho-pathway. After inhibition of ring cleavage activities with 3-chlorocatechol, 2-chlorobenzoate was transformed to catechol in nearly stoichiometric amounts. Other ortho-substituted benzoates like anthranilate and 2-methoxybenzoate seem to be metabolized via the same route.
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    Polyphosphat : ein unterschätztes Molekül
    (2022) Jendrossek, Dieter; Hildenbrand, Jennie C.
    Polyphosphate (polyP) is an inorganic biopolymer ubiquitously present in all species. It has a variety of functions ranging from that of a reservoir for phosphorous in many microorganisms to functions in blood coagulation and plays a role in neurogenerative diseases in humans. Here, we provide a summary of the structure and functions that have been addressed to polyP in microorganisms.
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    Assemblage of ortho cleavage route for simultaneous degradation of chloro- and methylaromatics
    (1987) Rojo, Fernando; Pieper, Dietmar H.; Engesser, Karl-Heinrich; Knackmuss, Hans-Joachim; Timmis, Kenneth N.
    Genetic engineering is a powerful means of accelerating the evolution of new biological activities and has considerable potential for constructing microorganisms that can degrade environmental pollutants. Critical enzymes from five different catabolic pathways of three distinct soil bacteria have been combined in patchwork fashion into a functional ortho cleavage route for the degradation of methylphenols and methylbenzoates. The new bacterium thereby evolved was able to degrade and grow on mixtures of chloro- and methylaromatics that were toxic even for the bacteria that could degrade the individual components of the mixtures. Except for one enzymatic step, the pathway was fully regulated and its component enzymes were only synthesized in response to the presence of pathway substrates.
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    Characterization of Agrobacterium tumefaciens PPKs reveals the formation of oligophosphorylated products up to nucleoside nona-phosphates
    (2020) Frank, Celina; Teleki, Attila; Jendrossek, Dieter
    Agrobacterium tumefaciens synthesizes polyphosphate (polyP) in the form of one or two polyP granules per cell during growth. The A. tumefaciens genome codes for two polyphosphate kinase genes, ppk1AT and ppk2AT, of which only ppk1AT is essential for polyP granule formation in vivo. Biochemical characterization of the purified PPK1AT and PPK2AT proteins revealed a higher substrate specificity of PPK1AT (in particular for adenine nucleotides) than for PPK2AT. In contrast, PPK2AT accepted all nucleotides at comparable rates. Most interestingly, PPK2AT catalyzed also the formation of tetra-, penta-, hexa-, hepta-, and octa-phosphorylated nucleosides from guanine, cytosine, desoxy-thymidine, and uridine nucleotides and even nona-phosphorylated adenosine. Our data - in combination with in vivo results - suggest that PPK1AT is important for the formation of polyP whereas PPK2AT has the function to replenish nucleoside triphosphate pools during times of enhanced demand. The potential physiological function(s) of the detected oligophosphorylated nucleotides await clarification.
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    The multiple roles of polyphosphate in Ralstonia eutropha and other bacteria
    (2021) Rosigkeit, Hanna; Kneißle, Lea; Obruča, Stanislav; Jendrossek, Dieter
    An astonishing variety of functions has been attributed to polyphosphate (polyP) in prokaryotes. Besides being a reservoir of phosphorus, functions in exopolysaccharide formation, motility, virulence and in surviving various forms of stresses such as exposure to heat, extreme pH, oxidative agents, high osmolarity, heavy metals and others have been ascribed to polyP. In this contribution, we will provide a historical overview on polyP, will then describe the key proteins of polyP synthesis, the polyP kinases, before we will critically assess of the underlying data on the multiple functions of polyP and provide evidence that - with the exception of a P-storage-function - most other functions of polyP are not relevant for survival of Ralstonia eutropha, a biotechnologically important beta-proteobacterial species.
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    Enrichment of dibenzofuran utilizing bacteria with high co-metabolic potential towards dibenzodioxin and other anellated aromatics
    (1989) Strubel, Volker; Rast, Hans G.; Fietz, Walter H.; Knackmuss, Hans-Joachim; Engesser, Karl-Heinrich
    Dibenzofuran degrading bacteria were enriched from various environmental sources. A mutualistic mixed culture of strain DPO 220 and strain DPO 230 was characterized. Strain DPO 220 alone showed limited growth with dibenzofuran as sole source of carbon and energy (td ≥ 4.5 h). A labile degradation product, C12H10O5, and salicylate were isolated from the culture fluid. Salicylate was found to be a central intermediate of DBF-degradation.Strain DPO 220 co-metabolized a wide range of anellated aromatics as well as heteroaromatics. High rates of co-oxidation of dibenzodioxin demonstrate analogue-enrichment to be a powerful technique for selecting enzymatic activities for otherwise non-degradable substrates.
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    Bacterial metabolism of side chain fluorinated aromatics: cometabolism of 4-trifluoromethyl(TFM)-benzoate by 4-isopropylbenzoate grown Pseudomonas putida JT strains
    (1988) Engesser, Karl-Heinrich; Rubio, Miguel Angel; Ribbons, Douglas W.
    Enzymes of the p-cymene pathway in Pseudomonas putida strains cometabolized the intermediate analogue 4-trifluoromethyl(TFM)benzoate. Three products, 4-TFM-2,3-dihydro-2,3-dihydroxybenzoate, 4-TFM-2,3-dihydroxy-benzoate and 2-hydroxy-6-oxo-7,7,7-trifluorohepta-2,4-dienoate (7-TFHOD) were identified chemically and by spectroscopic proterties.Certain TFM-substituted analogue metabolites of the p-cymene pathway were transformed at drastically reduced rates. Hammett type analysis of ring cleavage reactions of 4-substituted 2,3-dihydroxybenzoates revealed the negative inductive and especially mesomeric effect of substituents to be rate determining. Whereas decarboxylation of 3-carboxy-7-TFHOD was not affected by fluorine substitution the subsequent hydrolysis of 7-TFHOD proceeded very slowly. The negative inductive effect of the TFM-group probably inhibited heterolysis of the carbon bond between C5 and C6 of 7-TFHOD.