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Reactive oxygen species (ROS) can damage all cellular macromolecules and also produce secondary reactive intermediates, like reactive electrophilic species (RES) that include quinones or aldehydes. Low molecular weight (LMW) thiols are small thiol-containing compounds that play essential roles in the defense against ROS and RES in all organisms. The best studied LMW thiol is the tripeptide glutathione (GSH). Firmicutes bacteria including Bacillus und Staphylococcus species have been recently discovered to utilize the redox buffer bacillithiol (BSH). LMW thiols function as redox buffers to maintain the reduced state of the cytoplasm. Under conditions of oxidative stress, LMW thiols also react with protein thiols to form mixed LMW thiol – protein disulfides, termed S-thiolations, as major protection mechanism. Investigating the role of BSH in oxidative stress response and ROS-induced S-thiolations in Firmicutes bacteria was one subject of this PhD thesis. Specifically, the regulatory mechanisms and post-translational thiol-modifications in response to NaOCl stress were studied in the model bacterium for low-GC Gram-positive bacteria Bacillus subtilis. The transcriptome profile after NaOCl stress was indicative of disulfide stress and overlapped strongly with the response to diamide. NaOCl stress caused induction of the thiol- and oxidative stress-specific Spx, CtsR, PerR and OhrR regulons. Thiol redox proteomics identified only few NaOCl-sensitive proteins with reversible thiol-oxidations. Using mass spectrometry, eleven proteins were identified that were oxidized to mixed BSH protein disulfides (S-bacillithiolated) in B. subtilis cells after NaOCl-exposure. Methionine synthase MetE is the most abundant S-bacillithiolated protein in B. subtilis and other Bacillus species after NaOCl exposure. S-bacillithiolation of OhrR repressor leads to upregulation of the OhrA peroxiredoxin that confers together with BSH specific protection against NaOCl. S-bacillithiolation of MetE, YxjG, PpaC, and SerA causes hypochlorite-induced methionine starvation as supported by the induction of the S-box regulon. To further assess the conservation of targets for S-bacillithiolations in other Firmicutes bacteria, we studied the S-bacillithiolomes of Bacillus megaterium, Bacillus pumilus, Bacillus amyloliquefaciens, and Staphylococcus carnosus under NaOCl stress conditions. In total, 54 S-bacillithiolated proteins were identified, including 29 unique proteins and 8 conserved proteins involved in amino acid and cofactor biosynthesis, nucleotide metabolism, translation, protein quality control, redox and antioxidant functions. Together our data support a major role of BSH redox buffer in redox control and thiol protection of conserved and essential proteins against irreversible oxidation by S-bacillithiolations in Firmicutes bacteria. In response to ROS and RES, bacteria also activate the expression of antioxidant and detoxification enzymes, such as catalases, peroxidases, thiol-dependent peroxiredoxins and other specific oxidoreductases to detoxify ROS and RES. These defense mechanisms are often controlled by redox-sensitive transcription factors. B. subtilis encodes redox-sensing MarR-type regulators belonging to the OhrR and DUF24-families that are conserved among bacteria. Hence, we were further interested in this PhD thesis to study at the molecular and structural level the redox-sensing mechanisms of novel redox-sensing MarR/DUF24-type regulators in B. subtilis. We have characterized the regulatory mechanisms of HypR, YodB and CatR that sense and respond to hypochlorite, diamide and quinones stress. HypR is the first DUF24-family regulator whose crystal structure was resolved. HypR senses specifically disulfide stress and controls positively expression of the flavin oxidoreductase HypO after NaOCl and diamide stress. HypR resembles a 2-Cys-type regulator with a reactive nucleophilic N-terminal Cys14 and a second C-terminal Cys49. Besides HypR, B. subtilis encodes further MarR/DUF24-family members including the paralogous YodB and CatR repressors that sense quinones and diamide. YodB controls the azoreductase AzoR1, the nitroreductase YodC, and the Spx regulator. YodB resembles a 2-Cys-type MarR/DUF24-family regulator with three Cys residues (Cys6, Cys101, and Cys108) that form intermolecular disulfides in vivo under oxidative stress. YodB and its paralog CatR were further identified as repressors of the catDE operon encoding a catechol-2,3-dioxygenase that also contributes to quinone resistance. Although CatR is a 1-Cys-type regulator, our data showed that CatR also forms intermolecular disulfide in response to diamide and quinones in vitro. Thus, HypR, YodB and CatR are controlled by 2-Cys-type thiol-disulfide redox switches to sense disulfide and RES stress conditions, and to control specific RES detoxification enzymes.
Bacteria are an integral part of modern biotechnology. They are used to make a variety of products, such as foods, drugs, as well as a multitude of chemicals. In order to increase their production rates molecular biotechnology offers many tuning points, starting from the selection of an applicable host, over its geno- and phenotypical characterization, followed by genetic manipulations for an optimized metabolism and stabilisation of production processes. This work comprises the optimization of Bacillus subtilis as an expression system. It describes the steps taken for selection and genomic characterization of the B. subtilis wild type strain ATCC 6051, the subsequent optimizations of the strain in respect to growth and productivity, as well as the characterization of its behaviour in a variety of cultivation conditions. The B. subtilis strain most commonly found in laboratories around the world is the first sequenced Gram-positive organism B. subtilis 168. Zeigler et al. showed that strain 168 is not a real wild type. Instead it was created through random mutagenesis with X-rays and selected for transformability. This strain has been used as the basis for popular B. subtilis strains in heterologous gene expression such as the extracellular protease deficient WB strains. Growth experiments showed the real wild type strain ATCC 6051 to be superior to its mutated ancestor 168, making it a solid basis for the construction of an optimized B. subtilis expression system. In order to gain a full understanding of the genomic and corresponding physiological differences between the two systems, B. subtilis ATCC 6051 was sequenced and compared to the genome of B. Subtilis 168. Several variations on geno- and phenotypic level could be revealed, that resulted in particular from genes involved in natural competency, the metabolism of amino acids and chemotaxis. This genomically well characterized B. subtilis ATCC 6051 was improved in respect to its application as an expression host. Improvements were achieved through the inactivation of both sporulation and reduction of autolysis, leading to a more robust behaviour during the overproduction and secretion of a reporter enzyme. A positive effect on the activity of an acetoin induced promoter by the addition of second copies for its transcription factors SigmaL and AcoR could be observed. Anaerobic zones and areas with excess glucose caused by insufficient mixing are common conditions in large scale bioprocesses and lead to oscillating conditions for the cells. In turn, this oscillation provokes an excretion of so called overflow metabolites, which can negatively affect the bacterial productivity. Detailed scientific characterizations of industrial scale processes under such oscillating conditions are scarce due to the high costs and logistics involved. A B. Subtilis sporulation mutant was thus examined in respect to its extra- and intracellular metabolites in a scale-down, two-compartment reactor giving hints about conditions the host is exposed to and how it reacts. To improve tolerance thresholds and utilization capacity for such metabolites in B. subtilis, the glyoxylate cycle was transferred from its close relative Bacillus licheniformis into the genome of B. subtilis. This feature enabled our B. subtilis ACE mutant to grow on acetate. The improved strain showed higher tolerance towards excess glucose in a fed-batch as well as higher productivity during the expression of a reporter enzyme in comparison to the wild type. The ACE strain and B. licheniformis showed an increased formation of glycolate during growth with the glyoxylate cycle. This with regard to bacteria undescribed metabolite seems to play a role as a by-product of the glyoxylate cycle. Summarizing, this thesis deals with the characterization and optimization of B. subtilis for growth on overflow metabolites, enhancements of the acoA-expression system and the influence of sporulation and lysis mutants on its activity. Complementary, the host was begun to be characterized in respect to its behaviour in industrial scale processes.
In Deutschland sterben jedes Jahr rund 10.000 Menschen (Gastmeier 2010) aufgrund nosokomialer Infektionen, wobei die größte Rolle unter den Infektionserregern Keime aus der körpereigenen mikrobiellen Flora des Patienten spielen. Zur Prävention dieser Infektionen ist es wichtig, diese Erreger schnell und sicher nachzuweisen, um beispielsweise - soweit sinnvoll - eine effektive Bekämpfung, z. B. durch Dekontamination, einleiten zu können. In dieser Arbeit wurde die luminometrische Adenosintriphosphat (ATP) – Messung auf ihre Eignung als Schnelltest zur Bestimmung einer veränderten Keimlast, u. a. auf der Haut, untersucht. Dabei wird über die in einer Probe bestimmten ATP-Menge indirekt auf die Keimzahl geschlossen. Als Praxistest für die ATP-Methode ist die Wirkung eines neuartigen Wirkstoffes aus Algen (Maresome) beurteilt worden. Dessen in Tierversuchen vorbeschriebenen adhäsionshemmenden Eigenschaften auf S.aureus als häufiger Vertreter der Normalflora der Haut und Nasenschleimhaut konnten in dieser Arbeit auch auf gesunder humaner Haut gezeigt werden. Eine Erregerreduktion durch den Wirkstoff sollte über die ATP-Messung als Schnelltest nachgewiesen und soweit möglich quantitativ analysiert werden. Initial ist geprüft worden, ob die ATP-Menge in einer Probe eine signifikante Korrelation zur Erregermenge in Keimsuspensionen, in Abklatsch- bzw. Abstrichuntersuchungen von unbelebten Flächen und auf der Haut zeigt. Dies konnte zunächst für reine Keimsuspensionen, aber nur bedingt bei den Abstrichen von unbelebten und belebten Oberflächen bestätigt werden, wobei prinzipiell die sehr sensitive ATP-Nachweistechnik bestätigt werden konnte. Die luminometrische Methode zeigte sich für die praktische Anwendung als Schnelltest bei Hautabstrichproben im Gegensatz zur sensitiveren, aber viel länger dauernden kulturellen Keimzahlbestimmung als nicht geeignet, da die Ergebnisse nicht zuverlässig reproduzierbar waren. Daher kann diese derzeit nicht für den klinischen Einsatz, z. B. zur Effizientüberwachung der Hautantiseptik oder zum Monitoren einer Adhäsionshemmung durch Maresome empfohlen werden. Bevor ein ATP-Test als Produkt für den Einsatz auf belebten Oberflächen (Haut, Schleimhaut, Wunden) denkbar ist, bedarf es weiterer Forschungen.