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Institute
Natural products (NPs) have been a rich source for pharmaceutically used anti-infectives and other drugs. However, the application of anti-infectives inevitably causes the development of resistant and multiresistant pathogens, which have to be treated with novel anti-infectives. The industrial research for novel anti-infectives has been concentrating on members of the bacterial Actinomycetales for a long time. Due to several reasons, e.g. the rediscovery of already known NPs, pharmaceutical companies abandoned their NP-research and focused on drug development based on combinatorial chemistry. However, the limited structural diversity of merely synthetic compound libraries has not been a fruitful source for bioactive compounds. Hence the discovery of novel bioactive NPs as a source for anti-infectives is still of economical and humanitarian interest and will remain to be an important branch of research in the future. One strategy to circumvent the rediscovery of bioactive NPs is the analysis of yet unexplored bacterial taxa. Based on this assumption, this work aimed at the discovery of novel NPs from the entomopathogenic bacterial genera Xenorhabdus and Photorhabdus and other promising taxa, as well as the investigation of their biosynthesis. ...
Myxobacteria are on order of Gram-negative, soil dwelling bacteria that feature an impressive number of properties: they can glide on solid surfaces by using two different motility motors, subsist by preying on other microorganisms, are often producers of multiple natural products, and upon adverse environmental conditions, they are able to form multicellular structures called “fruiting bodies”. The process, in which these macroscopically visible structures arise from independent single cells, has been the predominant subject of myxobacterial research for many decades. More precisely, researchers have strived for the discovery of genes, proteins and small molecules that act as signals, receivers or modulators of this complex process. In this regard, the species Myxococcus xanthus has evolved into the model organism due to its relatively simple and reliable handling in a laboratory environment. The research underlying this thesis focused on the identification and biosynthesis of lipids that may act as intercellular signaling molecules during the course of fruiting body formation of the myxobacterium Myxococcus xanthus as part of the “E-signal” system. In general, lipids containing branched-chain fatty acids with an uneven number of carbon atoms were found to be important players in this particular process. Nevertheless, their exact roles remain largely unknown as of this day. The first publication that is part of this thesis deals with an aspect that even strengthened the importance of role of iso-branched compounds in myxobacteria: myxobacterial metabolism is able to transform precursors of iso-lipids to isoprenoids. It addresses the question whether isoprenoids in general are important for fruiting body formation. Phenotypic analysis of mutants impaired in the biosynthesis of the central isoprenoid precursor 3-hydroxymethylglutaryl-Coenzyme A (3-HMG-CoA) from acetate and/or branched chain keto acids and their genetic and metabolic complementation clearly showed that isoprenoids are essential for fruiting body formation and confirmed that leucine derived isovalerate is an important source for isoprenoid precursors in myxobacteria. The second, and by far and away most tedious and sophisticated study, addressed the question as to how myxobacteria form fatty acid derived iso-branched ether lipids and to what extent they are important for fruiting body formation and sporulation. In a previous study, those unusual lipids were identified as specific biomarkers for myxobacterial development. No biochemical pathways to ether lipids specific for prokaryotes were known by then. In this study, a putative candidate gene that may be in involved in ether lipid biosynthesis was investigated. A combination of gene disruption and complementation experiments, phenotypic analysis and monitoring of ether lipid formation by means of GC-MS demonstrated its involvement in myxobacterial ether lipid biosynthesis and the importance of these lipids for the developmental process. Heterologous expression and biochemical testing of this gene together with in-silico sequence analysis and docking experiments confirmed the functions of its predicted domains. The discussion section provides an additional suggestion on how the ether bond formation is performed. Furthermore and most importantly, iso-branched ether lipids were found to be essential for sporulation but not for fruiting body formation. In summary, one or several molecules derived from an iso-branched alkylglycerol seem to play a role during sporulation in M. xanthus and a multidomain enzyme unique for myxobacteria is involved in their biosynthesis. The last manuscript addresses the complexity of lipid metabolism in myxobacteria. Prior to this work, there was limited knowledge about the exact composition of the myxobacterial lipidome and no method was available to monitor putative changes in the myxobacterial lipidome down to the single molecular species for studying lipid biosynthesis or regulation. An ultra-performance liquid chromatography coupled with mass spectrometry based method with electrospray ionization (UPLC-ESI-MS) utilizing standard equipment and a water/acetonitrile/isopropanol based eluent system proved to be geared for the construction of lipid profiles for wild type and mutant cells of M. xanthus and to show their differences. Fragmentation spectra based structure elucidation of lipid molecular species resulted in the identification of 99 molecular species comprising glycerophosphoethanolamines, glycerophosphoglycerols, glycerolipids, ceramides and ceramide phosphoinositols. The latter have never been described for any prokaryotes before. Three dimensional plots were created from the relative intensity differences of the single molecular ion species between the different samples to provide an efficient and versatile visualization of the data and enable the researcher to quickly detect differences.
In the last couple of years the research on natural products concerning ecological questions has gained more and more interest. Especially natural products play an important role for the maintenance of symbiotic relationships.
Here we present the application of the “overlap extension PCR-yeast homologous recombination“(ExRec) to simplify the availability of natural products. We successfully cloned a 45 kb gene cluster and characterized two new peptides ambactin and xenolindicin from Xenorhabdus – the latter derived from a silent gene cluster. ExRec is a very efficient cloning technique and resembles a powerful method regarding the assembly of large gene clusters as well as the cloning from metagenomic libraries or RNA pools.
In addition, we discovered bacterial pyrrolizidine alkaloids from Xenorhabdus, referred to as pyrrolizixenamides. The gene cluster consisted of a NRPS and a hydroxylase encoding gene. Surprisingly, this gene cluster and its variations (type A to D) can be found throughout the bacterial kingdom which might indicate an essential function. While these substances are mainly known to play a role in the defense mechanism of plants, the function of the identified pyrrolizixenamides from Xenorhabdus yet remains unsolved.
Moreover, we firstly identified a phosphopantetheinyl transferase (PPTase) from the lichenized fungus of Evernia prunastri. The gene eppA encoding a Sfp-type PPTase was heterologously expressed in Escherichia coli and Saccharomyces cerevisiae and functional characterized by indigoidine production and complementation of lys5, respectively. All represented results contribute to the elucidation of natural products and thereby to their role in nature with special regard to symbiotic associations.
Die hier vorliegende Dissertation befasst sich mit der Synthese von Naturstoffen aus Xenorhabdus und Photorhabdus spp. Da 6,0 - 7,5% ihres Genoms Sekundärmetabolit Clustern zuzuordnen sind, gelten diese entomopathogenen Bakterien als vielversprechende Naturstoffproduzenten. Die Palette der von ihnen produzierten Naturstoffe reicht von Antibiotika über Insektizide bis hin zu potentiellen Zytostatika. Die im Rahmen dieser Arbeit synthetisierten und charakterisierten Substanzen lassen sich in vier Kategorien einteilen: kleine Sekundärmetabolite (Phurealipide), zyklische Makrolaktame (Xenotetrapeptide, GameXPeptide und Ambactin), zyklische Makrolaktone (Szentiamide, Xentrivalpeptide und Xenephematide) und methylierte lineare Peptide (Rhabdopeptide und Rhabdopeptid-ähnliche Moleküle).
The metabolome of any live cell consists of several hundred, if not thousands of different molecules at any given moment, be it a relatively small bacterial cell or a whole multicellular organism. Although there are continuous attempts to differentiate between primary and secondary metabolites, the borders often blur in the eye of almost perfect interconvertability of all such matter. With chemistry and physics dominating this domain of biology it is an interdisciplinary endeavor to tackle the questions surrounding the workings of the metabolic pathways involved, searching for answers that ultimately help us to better understand life and find solutions to problems that affect us humans. One area of biochemistry that serves as a formidable example of the intertwined primary and secondary metabolic pathways are fatty acids, essential components of bacterial membranes, sources of energy and carbon but also important building blocks of several natural products. The second area to be mentioned is the metabolism of amino acids, the basic components of proteins and enzymes, which also serve as precursors to a diverse set of metabolites with many biological purposes.
This work focuses on these two areas of biochemistry, as several intermediates of their metabolism serve as building blocks for complex secondary metabolites whence many interesting and bioactive natural products are derived. The powerful and relatively novel tool of click-chemistry is employed to track azide-labeled precursors of primary and secondary metabolism in various bacterial strains to observe biochemistry at work and adds to the knowledge gained through other methods. The methods presented in this work serve the observation of fatty acid biosynthesis, degradation, modification and transport through direct ligation of azido fatty acids with cyclooctynes on one hand, leading to a revision of fatty acid transport in general. On the other hand a cleavable azide-reactive resin is devised to generally track the fate of azidated compounds through the myriads of metabolic pathways offered by entomopathogenic bacteria possessing a rich secondary metabolism. The resulting findings led to the identification of several antimicrobial peptides, amides and other compounds of which many had remained so far undetected in the strains that underwent investigation, underlining the worth of this method for future metabolomic research and beyond.
The metabolome of any live cell consists of several hundred, if not thousands of different molecules at any given moment, be it a relatively small bacterial cell or a whole multicellular organism. Although there are continuous attempts to differentiate between primary and secondary metabolites, the borders often blur in the eye of almost perfect interconvertability of all such matter. With chemistry and physics dominating this domain of biology it is an interdisciplinary endeavor to tackle the questions surrounding the workings of the metabolic pathways involved, searching for answers that ultimately help us to better understand life and find solutions to problems that affect us humans. One area of biochemistry that serves as a formidable example of the intertwined primary and secondary metabolic pathways are fatty acids, essential components of bacterial membranes, sources of energy and carbon but also important building blocks of several natural products. The second area to be mentioned is the metabolism of amino acids, the basic components of proteins and enzymes, which also serve as precursors to a diverse set of metabolites with many biological purposes.
This work focuses on these two areas of biochemistry, as several intermediates of their metabolism serve as building blocks for complex secondary metabolites whence many interesting and bioactive natural products are derived. The powerful and relatively novel tool of click-chemistry is employed to track azide-labeled precursors of primary and secondary metabolism in various bacterial strains to observe biochemistry at work and adds to the knowledge gained through other methods. The methods presented in this work serve the observation of fatty acid biosynthesis, degradation, modification and transport through direct ligation of azido fatty acids with cyclooctynes on one hand, leading to a revision of fatty acid transport in general. On the other hand a cleavable azide-reactive resin is devised to generally track the fate of azidated compounds through the myriads of metabolic pathways offered by entomopathogenic bacteria possessing a rich secondary metabolism. The resulting findings led to the identification of several antimicrobial peptides, amides and other compounds of which many had remained so far undetected in the strains that underwent investigation, underlining the worth of this method for future metabolomic research and beyond.
Xenorhabdus and Photorhabdus bacteria are gaining more and more attention as a subject of research because of their unique yet similar life cycle with nematodes and insects. This work focused on the secondary metabolites that are produced by Xenorhabdus and Photorhabdus. With the help of modern HPLC-MS methodologies and increasingly available bacterial genome sequences, the structures of unknown secondary metabolites could be elucidated and thus their biosynthesis pathways could be proposed, too.
The first paper reported 17 depsipeptides termed xentrivalpeptides produced by the bacterium Xenorhabdus sp. 85816. Xentrivalpeptide A could be isolated from the bacterial culture as the main component. The structure of xentrivalpeptide A was elucidated by NMR and the Marfey´s method. The remaining xentrivalpeptides were exclusively identified by feeding experiments and MS fragmentation patterns.
The second paper described the discovery and isolation of xenoamicin A from Xenorhabdus mauleonii DSM17908. Additionally, other xenoamicin derivatives from Xenorhabdus doucetiae DSM17909 were analyzed by means of feeding experiments and MS fragmentation patterns. The xenoamicin biosynthesis gene cluster was identified in Xenorhabdus doucetiae DSM17909.
The manuscript for publication focused on the biosynthesis of anthraquinones in Photorhabdus luminescens. The Type II polyketide synthase for the biosynthesis of anthraquinone derivatives was discovered in P. luminescens in a previous publication by the Bode group,1 in which a partial reaction mechanism for the biosynthesis has been proposed. The manuscript reported in this thesis however elucidated the biosynthetic mechanisms in a greater detail as compared to the previous publication. Particularly, the biosynthetic mechanism was deciphered through heterologous expression of anthraquinone biosynthesis (ant) genes in E. coli. Additionally, deactivation of the genes antG encoding a putative CoA ligase and antI encoding a putative hydrolase, was performed in P. luminescens. Selected ant genes were over-expressed in E. coli as well as the corresponding proteins purified for in vitro assays. Model compounds were chemically synthesized as possible substrates of AntI and were used for in vitro assays. Here, it was revealed that the CoA ligase AntG played an essential role in the activation of the ACP AntF. Furthermore, a chain shortening mechanism by the hydrolase AntI was identified and was further confirmed by in vitro assays using model compounds. Additionally, this chain shortening mechanism was supported by homology based structural modeling of AntI.
Natural products are valuable sources for biologically active compounds, which can be utilized as pharmaceuticals. Thereby, the synthesis is based purely on biosynthetic grounds often conducted by so-called megaenzymes. One major biosynthetic pathway is the acetate pathway including polyketide and fatty acid synthesis, which encompass one of the largest classes of chemically diverse natural products. These have medicinal relevance due to their antibacterial, antifungal, anthelmintic, immunosuppressive and antitumor properties.
Due to the high structural and functional similarity between polyketide synthases and type I animal fatty acid synthases (FASs), FAS can serve as a paradigm for the whole class of multifunctional enzymes. To fully exploit the biosynthetic potential of FASs, a good access to the enzyme is of essential importance. In this regard, Escherichia coli remains an unchallenged heterologous host due to low culturing costs, particularly fast mutagenesis cycles and relatively easy handling. Surprisingly, no sufficient expression strategy for an animal FAS in E. coli has yet been reported, as it turned out that the only approach was not reproducible.
We commenced our analysis with searching for an appropriate FAS homolog that fulfills our requirements of high protein quality, sufficient yield and ensured functionality. After extensive screening of different variants, culturing conditions and co-expression strategies, we identified the murine FAS (mFAS) as our protein of choice. The established purification strategy using tags at both termini led to a reproducible and sufficient access to the protein in excellent quality. The enzyme was further biochemically characterized including an enzyme kinetic investigation of fatty acid synthesis and an examination whether different acyl-CoA substrates can serve as priming units. This adds mFAS to our repertoire of manageable megaenzymes paving the way to exploit the catalytic efficiency in regards of microbial custom-compound synthesis.
With a strong focus on deepening our understanding of the working mode of such megaenzymes, rather than analyzing respective biosynthetic products, we have addressed the question whether mFAS itself can be engineered towards PKSs or whether properties of mFAS can be exploited to engineer PKSs. This approach was conducted on three levels of complexity from function of individual domains via organization of domains to form modules to the interplay of two modules in bimodular constructs.
Fatty acid synthesis begins with the loading of acyl moieties onto the FAS, which is conducted by a domain called malonyl-/acetyltransferase (MAT). This domain was in-depth characterized due to its important role of choosing the substrates that are built in the final compound. Our analysis comprised structural and functional aspects providing crystal structures of two different acyl-bound states and kinetic parameters for the hydrolysis and transacylation reaction using twelve exemplary CoA-esters. For this purpose, we have successfully established a continuous fluorometric assay using the α-ketoglutarate dehydrogenase as a coupled enzyme, which converts the liberated coenzyme A into Nicotinamide adenine dinucleotide. These data revealed an extensive substrate ambiguity of the MAT domain, which had not been reported to that extent before. Further, we could demonstrate that the fold fulfills both criteria for the evolvability of an enzyme by expressing MAT in different structural arrangements (robustness) and by altering the substrate ambiguity within a mutagenesis study (plasticity). Taken these aspects together, we are persuaded that the MAT domain can serve as a versatile tool for PKSs engineering in potential FAS/PKS hybrid systems.
On the higher level of complexity, we investigated the architectural variability of the mFAS fold, which constitutes a fundamental basis for a broader biosynthetic application. We could rebuild all four module types occurring in typical modular PKSs confirming a high degree of modularity within the fold. Not only structural, but also functional integrity of these modules was validated by using triacetic acid lactone formation and ketoreductase activity. Especially the latter analysis, made it possible to quantify effects of the engineering within the processing part by respective enzyme kinetic parameters. Expanding our focus beyond a singular module, we have utilized the mFAS fold for designing up to 380 kDa large bimodular constructs. In this approach, a loading didomain was attached N-terminally containing an additional MAT and acyl carrier protein (ACP) domain. Two constructs could be expressed and purified in excellent quality to investigate the influence of an altered overall architecture on fatty acid synthesis. By comparison with appropriate controls, a functional effect of the additional loading module could indeed be proven in the bimodular systems. Those constructs allow a comprehensive analysis of the underlying molecular mechanism in the future and serve as a potential model system to study the transition from iterative to vectorial polyketide synthesis in vitro.
In the 'Golden Age of Antibiotics', between 1940 and 1970, the global pharmaceutical companies discovered many antibiotics, such as cephalosporins, tetracyclines, aminoglycosides, glycopeptides, etc., as well as antifungal and antiparisitic agents. Due to several reasons, e.g. the steady re-discovery of already known NPs and the associated high costs, many pharmaceutical companies have significantly scaled back or totally abandoned their NP discovery programs since the late 20th century. Instead those companies started to focus on drug discovery based on combinatorial synthesis and thereby on the creation of enormous synthetic libraries containing small molecules. Unfortunately, this synthetic approach dealing with the optimization of existing NP or antibiotic has its limitations. As a result, leading pharmaceutical companies are re-conducting NPs research to discover new antimicrobials for the upcoming antimicrobial resistance threat. The Natural Product Center of Excellence, a collaboration between Sanofi-Aventis and Fraunhofer IME, is advancing in this context the discovery and development of novel antimicrobial agents for the treatment of infectious diseases through the testing of Sanofi's microbial extract library and strain collection. The aim of the present PhD thesis was the discovery and isolation of novel antimicrobial compounds with improved activities and/or novel MOAs as potential lead compound for a further drug discovery.
This work deals with the characterization of three different type II polyketide synthase systems (PKS II) from the Gram-negative bacteria Xenorhabdus and Photorhabdus.
Particular attention was paid to a biochemically underexplored class of aryl polyene (APE) pigments. Bioinformatic analysis of enzymes involved in the biosynthesis and the in vitro reconstruction proved that the synthesis of APEs involves an unusual fatty acid-like elongation mechanism. Furthermore, the discovery of unexpected protein-protein interactions provided new insights into the multienzyme complex formation of this unusual PKS II system. Through collaboration with the groups from Prof. Michael Groll and junior Prof. Nina Morgner, two protein complexes were structurally solved and several native protein multimerization events were identified and allowed us to suggest a possible protein-interaction network. The results are summarized in publication ‘An Uncommon Type II PKS Catalyzes Biosynthesis of Aryl Polyene Pigments’ (first author; J. Am. Chem. Soc.).
In addition to in vitro-analysis, in vivo-studies were used to investigate the APE compound produced by X. doucetiae in more detail. The activation of the silent biosynthetic gene cluster (BGC) led to the detection of the APE compound in the homologous host. Further combination of homologous expression and targeted deletions of the APE BGC revealed an APE-lipid-like structure. MS-based analyses and purification of intermediates allowed us to deduce structural building blocks of the APE-lipid, which is composed of an APE structural core, a glucosamine residue and an unusual long-chain fatty acid with unusual conjugated double bonds and a phosphoethanolamine head group. In combination with the above stated in vitro-data, we assumed a plausible biosynthetic mechanism of the APE-lipid. The results are summarized in the section ‘Additional Results: Tracing the Full-length APE’.
The biosynthesis of isopropylstilbene (IPS) has already been well-studied by the Bode laboratory and the group of Prof. Ikuro Abe. Studies with Photorhabdus laumondii TT01 by the Bode group revealed the distributed locations and functions of the genes involved in biosynthesis, which originate from two pathways. Particularly, the Bode group first demonstrated that an unusual ketosynthase/cyclase (StlD) catalyzes the condensation of 5-phenyl-2,4-pentadienoyl-ACP and isovaleryl-beta-ketoacyl-ACP via a Michael addition. Such a pathway for stilbene formation is distinct from those widespread in plants. The Abe group solved the structure and biochemical mechanism of StlD and further investigated the aromatization reaction of the aromatase StlC. However, the generation of the required cinnamoyl-precursor 5-phenyl-2,4-pentadienoyl-ACP as a Michael acceptor for this cyclization reaction remained elusive. In this work, we were able to reconstitute the synthesis of the Michael acceptor in vitro, by the action of enzymes from the fatty acid biosynthesis. With the knowledge about the crucial cross-talk from primary and specialized metabolism, we further determined the minimal endowment for stilbene production in a heterologous host. Here, the discovered AasS enzyme StlB is responsible for the generation of cinnamoyl-ACP and among others, plFabH plays a key role as gatekeeper enzyme for further processing. With this information in hand, we were able to obtain IPS production in E. coli. These results are presented in the manuscript ‘Biosynthesis of the Multifunctional Isopropylstilbene in Photorhabdus laumondii Involves Cross-talk Between Specialized and Primary Metabolism’ (co-first author, manuscript).
The biosynthesis of the orange-to-red-pigmented anthraquinones (AQs) is the best-studied type II PKS system according to preliminary results. While several investigations by Brachmann et al. discovered the BGC and the overall product spectrum of the main AQ-256 and its methylated derivatives, data of Quiqin Zhou (Bode group) performed biochemical in vitro analysis paired with in vivo heterologous expression of the ant-genes antA-I. This led to the identification of shunt products that indicated an AQ-scaffold derived from an octaketide intermediate that gets shortened to a heptaketide by the hydrolase AntI, resulting in the main anthraquinone AQ-256. This PKS-shortening mechanism was further confirmed by the protein crystal structure of AntI by the Groll group (publication, minor contributions, co-author, Chem Sci. ‘Molecular Mechanism of Polyketide Shortening in Anthraquinone Biosynthesis of Photorhabdus luminescens’). Further substrate analysis of the P. luminescens AQ-producer and mutants revealed an inhibitory effect of cinnamic acid against the hydrolase AntI. Cinnamic acid might therefore be involved in regulation of AQ biosynthesis (‘Anthraquinone Production is Influenced by Cinnamic Acid’, first author, manuscript).
Biochemical analysis from Quiqin Zhou with the minimal PKS of the AQ-synthase further revealed the exclusive activation of the AQ-ACP by the PPTase AntB. The PPTase is insoluble alone but gets stabilized by the CoA-ligase, most likely inactive, working as a chaperone. Thus, the minimal PKS endowment to produce the octaketide scaffold compromises, besides the ACP, the KS:CLF heterodimer and the MCAT, the co-occurrence of the PPTase AntB and the CoA-ligase AntG. For the first time, X-ray crystallography depicted a minimal PKS in action, by obtaining the structural data of native complexes from an ACP:KS:CLF, the KS:CLF alone and an ACP:MCAT in their non-active and active forms. It was possible to confirm a KS-bound hexaketide, which was built upon heterologous expression of the KS:CLF. Mutagenesis with amino-acids proposed to be involved in protein-protein interactions in the ACP:KS:CLF complex revealed some interesting protein-interaction sites. Additionally, an induced-fit mechanism of the MCAT with the ACP during the malonylation reaction confirmed a monodirectional transfer reaction (‘Structural Snapshots of the Minimal PKS System Responsible for Octaketide Biosynthesis’ co-author, manuscript under review).