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Institut
Development and implementation of novel optogenetic tools in the nematode Caenorhabditis elegans
(2016)
Optogenetics, though still only a decade old field, has revolutionized research in neurobiology. It comprises of methods that allow control of neural activity by light in a minimally-invasive, spatio-temporally precise and genetically targeted manner. The optogenetic actuators or the genetically encoded light sensitive elements mediate light driven manipulation of membrane potential, intracellular signalling, neuronal network activity and behaviour (Fenno et al. 2011; Dugué et al. 2012). These techniques have been particularly useful for dissecting neural circuits and behaviour in the transparent and genetically amenable nematode model system Caenorhabditis elegans (Husson et al. 2013; Fang-yen et al. 2015).
In fact, C. elegans was the first living organism in which microbial rhodopsin based optogenetic tools (Channelrhodopsin-2 or ChR2, and Halorhodopsin or NpHR) were successfully implemented and bimodal 'remote' control of behaviour was achieved (Nagel et al. 2005; Zhang et al. 2007). Since then it has been a prominent model for the development and application of novel optogenetic tools and techniques, especially in the nervous system which comprises of 302 neurons and is organised in a hierarchical organization. The environmental stimuli are sensed by the sensory neurons, leading to the processing of information by the downstream interneurons, that relay to motor neurons which in-turn synapse onto muscles that drive the movement-based responses.
The microbial rhodopsins like ChR2 and NpHR mediate light driven depolarization and hyperpolarization, respectively and thereby activate or inhibit neural activity. However, they do not allow local control of membrane potential as they are expressed all over the plasma membrane of the cell rather than being restricted to specific domains, for example synaptic sites. Moreover, they completely over-ride the intrinsic activity of the cell, completely bypassing the signal transduction processes inside the cell. Thus, in order to study intracellular signalling and to answer questions pertaining to the endogenous role of receptors and channels in an in-vivo context, the optogenetic tool-kit needs to be expanded.
This thesis aimed at developing and implementing novel optogenetic tools in C. elegans that allow for sub-cellular signalling control as well as endogenous receptor control. These are: two light activated guanylyl cyclases (bPGC and BeCyclOp) to modify cyclic guanosine monophosphate (cGMP) mediated signalling in the sensory neurons, as well as attempts towards rendering endogenous C. elegans receptors - glutamate receptor (GLR-3/-6), acetylcholine receptor (ACR-16), glutamate gated chloride channel (GLC-1) light switchable and to understand their biological function in-vivo.
Organisms respond to sensory cues by activation of a primary receptor followed by relay of information downstream to effector targets by secondary signalling molecules. cGMP is a widely used 2nd messenger in cellular signaling, acting via protein kinase G or cyclic nucleotide gated (CNG) channels. In sensory neurons, cGMP allows for signal modulation and amplification, before depolarization. Chemo-, thermo-, and oxygen-sensation in C. elegans involve sensory neurons that use cGMP as the main 2nd messenger. For example, ASJ is the pheromone sensing neuron regulating larval development, AWC is the chemosensory neuron responding to volatile odours and BAG senses oxygen and carbon dioxide in the environment. In these neurons, cGMP acts downstream of the GPCRs and functions by activating cationic TAX-2/-4 CNG channels, thereby depolarising the sensory neuron. Manipulating cGMP levels is required to access signalling between sensation and sensory neuron depolarization, thereby provide insights into signal encoding. We achieve this by implementing two photo-activatable guanylyl cyclases - 1) a mutated version of Beggiatoa sp. bacterial light-activated adenylyl cyclase, with specificity for GTP (Ryu et al. 2010), termed BlgC or bPGC (Beggiatoa photoactivated guanylyl cyclase) and 2) guanylyl cyclase rhodopsin (Avelar et al. 2014) from Blastocladiella emersonii (BeCyclOp).
bPGC is a BLUF (blue light sensing using flavin) domain containing cyclase which uses FAD as the co-factor and catalyses the synthesis of cGMP from GTP upon activation by blue light. Prior to implementation in sensory neurons, a simpler heterologous system with co-expression of the TAX-2/-4 CNG channel in C. elegans body wall muscle (BWM) was used. The cGMP generated by the light activated cyclases activates the CNG channel leading to the muscle depolarization, thereby causing changes in body length which can be easily scored.
The baker’s yeast Saccharomyces cerevisiae is a valuable and increasingly important microorganism for industrial applications (Hong and Nielsen, 2012). Its robustness concerning process conditions like low pH, osmotic and mechanical stress as well as toxic compounds is an advantage. Moreover, S. cerevisiae is ‘generally regarded as safe’ (GRAS). The model organism has been studied intensively. The collected data, including genomic, proteomic and metabolic information, can be used to genetically modify and improve its metabolism. Fatty acids and fatty acid derivatives have wide applications as biofuels, biomaterials, and other biochemicals. Several studies have been dealing with the overproduction of fatty acids and derivatives thereof in S. cerevisiae. The fatty acid biosynthesis starting with acetyl-CoA requires two enzymes, the acetyl-CoA carboxylase (Acc1p) and the fatty acid synthase complex (FAS), to produce acyl-CoA esters with predominantly 16 to 18 carbon atoms chain length (Lynen et al., 1980). For the synthesis of monounsaturated fatty acids in S. cerevisiae the ER bound acyl-CoA desaturase, Ole1p is essential (Tamura et al., 1976; Certik and Shimizu, 1999).
Using S. cerevisiae, the first section of this work dealt with the heterologous characterization of potential ω1-desaturases. Due to the fact that unsaturated fatty compounds can be modified further by hydrosilylations, hydrovinylations, oxidations to epoxides, acids, aldehydes, ketones or metathesis reactions, the interest in ω1-fatty acids is tremendous (Behr and Gomes, 2010). With the intention to find enzymes in fungi, that have a terminal desaturase activity a search in different genome databases was performed. The sequences of Pex-Desat3 and Obr-TerDes were used as reference sequences. The analysed proteins from Schizophyllum commune (EFI94599.1), Schizosaccharomyces octosporus (EPX72095.1), Wallemia mellicola (EIM20316.1), Wallemia ichthyophaga (EOR00207.1) and Agaricus bisporus var. bisporus (EKV44635.1), however, finally turned out to be Δ9 desaturases. A fungal desaturase with ω1-activity could not be found. The Δ9 desaturase SCD1 from Mus musculus was crystallized by Bai et al. (2015) and the information for specific amino acids responsible for the substrate specificity or enzyme activity were allocated. In combination with sequence and enzyme activity data form ChDes1 from Calanus hyperboreus, Desat2 from Drosophila melanogaster, Pex-Desat3 from Planotortrix excessana and Obr-TerDes from Operophtera brumata single amino acid exchanges were performed in the Δ9 desaturase Ole1p from S. cerevisiae. For all mutants, only fatty acids (C16 - C18) with a double bond between carbon C9 and C10 could be found. This indicates, that all inserted amino acid exchanges do not affect the substrate specificity or the position of the introduced double bond.
In the second section the focus was in the development of a production system for fatty acids in S. cerevisiae with regard to the previously established procedures by metabolic engineering. The combination of cytosolic malate dehydrogenase (MDH3), cytosolic malate enzyme (MAE1) and a citrate- α-ketoglutarate- carrier (YHM2) should improve the availability of acetyl-CoA in the cytosol, which is an important precursor for the fatty acid biosynthesis. If the major pathway (acetyl-CoA carboxylase and fatty acid synthase) was already optimized by high expression levels than no positive effect on increased fatty acid synthesis was detectable. Only non-optimized strains, with the additional overexpression of ATP-citrate lyase and cytosolic malate dehydrogenase, lead to a 41 % (20 mg/g dcw) improvement of fatty acid synthesis. In order to increase the fatty acid content further, the additional overexpression of DGA1 and TGL3 was performed. Hence, the highest amount of fatty acids could be observed with the strain S. cerevisiae WRY1ΔFAA1ΔFAA4 (2.5 g/L ± 0.8 g/L). The additional elimination of acyl-CoA synthetase Fat1p did not improve the yield.
It was recently reported, that chain length control of the fatty acid synthesis of bacterial FAS can be changed by rational engineering (Gajewski et al., 2017a). The knowledge about bacterial FAS was transferred in this work to S. cerevisiae FAS. Mutating up to five amino acids in the FAS complex enabled S. cerevisiae to produce medium chain fatty acids (C6 - C12). Further improvement was done by metabolic pathway engineering (promoter of alcohol dehydrogenase II from S. cerevisiae (pADH2), deletion of acyl-CoA synthetase FAA2) and optimization of fermentation conditions (YEPD-bacto medium buffered with potassium phosphate). The production of medium chain fatty acids resulted in the highest yield of 464 mg/L (C6 to C12 fatty acids). Furthermore, strains were created specifically overproducing hexanoic acid (158 mg/L) and octanoic acid (301 mg/L). The characterization of transferases, which could be responsible for the de-esterification of CoA-bound fatty acids, was analysed in an additional approach. It could be shown, that the genes EHT1, EEB1 and MGL2 have an influence on the MCFA yield in the supernatant. Generally speaking, the data from the single and double deletion strains suggest that Eeb1p has a selective hydrolytic activity for hexanoic acid-CoA ester, while Eht1p shows selective hydrolytic activity for octanoic acid-CoA ester, which is in line with Saerens et al. (2006).
The composition of cellular membranes is extremely complex and the mechanisms underlying their homeostasis are poorly understood. Organelles within a eukaryotic cell require a non-random distribution of membrane lipids and a tight regulation of the membrane lipid composition is a prerequisite for the maintenance of specific organellar functions. Physical membrane properties such as bilayer thickness, lipid packing density and surface charge are governed by the lipid composition and change gradually from the early to the late secretory pathway. As the endoplasmic reticulum (ER) is situated at the beginning of the cells secretory pathway, it has to accept and accommodate a great variety and quantity of secretory and transmembrane proteins, which enter the ER on their way to their final cellular destination. Secretory proteins can be translocated into the lumen of the ER co- or posttanslationally and membrane proteins are being inserted and released into the ER membrane. In the oxidative milieu of the ER-lumen, supported by a variety of chaperones, proteins can fold into their native form.
If the folding capacity of the ER-lumen is exceeded, an accumulation of mis- or unfolded proteins in the lumen of the ER occurs, consequently triggering the unfolded protein response (UPR). This highly conserved program activates a wide-spread transcriptional response to restore protein folding homeostasis. In fact, 7 – 8% of all genes in the yeast Saccharomyces cerevisiae (S. cerevisiae) are regulated by the UPR. The mechanism underlying the activation of the UPR by protein folding stress has been investigated thoroughly in the last decades and many of its mechanistic details have been elucidated. Recently, it became evident that aberrant lipid compositions of the ER membrane, collectively referred to as lipid bilayer stress, are equally potent in activating the UPR. The underlying molecular mechanism of this membrane-activated UPR, however, remained unclear.
This study focuses on the UPR in S. cerevisiae and characterizes the inositol requiring enzyme 1 (Ire1) as the sole UPR sensor in S. cerevisiae. Active Ire1 forms oligomers and, collaboratively with the tRNA ligase Rlg1, splices immature mRNA of the transcription factor HAC1, which results in the synthesis of mature HAC1 mRNA and the production of the active Hac1 protein, which binds to UPR-elements in the nucleus and activates the expression of UPR target genes. Here, the combination of in vivo and in vitro experiments is being used, which is supplemented by molecular dynamics (MD) simulations performed by Roberto Covino and Gerhard Hummer (MPI for Biophysics, Frankfurt), aiming to identify the molecular mechanism of Ire1 activation by lipid bilayer stress. This study focuses on the analysis of the juxta- and transmembrane region of Ire1. Bioinformatic analyses revealed a putative ER-lumenal amphipathic helix (AH) N-terminally of and partially overlapping with the transmembrane helix (TMH). This predicted AH contains a large hydrophobic face, which inserts into the ER membrane, forcing the TMH into a tilted orientation within the membrane. The resulting unusual architecture of Ire1’s AH and TMH constitutes a unique structural element required for the activation of Ire1 by lipid bilayer stress.
To investigate the function of the AH in the physiological context, different variants of Ire1 were produced under the control of their endogenous promoter and from their endogenous locus. The functional role of the AH was tested, by disrupting its amphipathic character by the introduction of charged residues into the hydrophobic face of the AH. The role of a conserved negative residue between the TMH and the AH (E540 in S. cerevisiae) was tested by substituting it by a unipolar, polar, or positively charged residue. These variants were intensively characterized using a series of assays:
This thesis provides evidence that the AH is crucial for the function of Ire1: Mutant variants with a disrupted (F531R, V535R) or otherwise modified AH (E540A) exhibited a lower degree of oligomerization and failed to catalyze the splicing of the HAC1 mRNA as the Wildtype control. Likewise, the induction of PDI1, a target gene of the UPR, was greatly reduced in mutants with a disrupted or defective AH. These data revealed an important functional role of the AH for normal Ire1 function.
An in vitro system was established to analyze the membrane-mediated oligomerization of Ire1. This system enabled the isolated functional analysis of the AH and TMH during Ire1 activation by lipid bilayer stress. A fusion construct, coding for the maltose binding protein (MBP) from Escherichia coli (E. coli), N-terminally to the AH and TMH of Ire1 was produced. The heterologous production in E. coli, the purification and reconstitution of this minimal sensor of Ire1 in liposomes was established as part of this study. To analyze the oligomeric status of the minimal sensor in different lipid environments, continuous wave electron paramagnetic resonance (cwEPR) spectroscopic experiments were performed. These experiments revealed that the molecular packing density of the lipids had a significant influence of the oligomerization of the spin-labeled membrane sensor: increasing packing densities resulted in sensor oligomerization. The AH-disruptive F531R mutant, in which the amphipathic character of the AH was destroyed, showed no membrane-sensitive changes in its oligomerization status.
Thus, the activation of Ire1 by lipid bilayer stress is achieved by a membrane-based mechanism. According to the current model, the AH induces a local membrane compression by inserting its large hydrophobic face into the membrane. As membrane thickness and acyl chain order are interconnected, this compression simultaneously results in an increased local disordering of lipid acyl chains. Supporting MD simulations performed by Roberto Covino and Gerhard Hummer revealed that the bilayer compression is significantly more pronounced in a densely packed lipid environment, than in a lipid environment of lower lipid packing density. Hence, the energetic cost of the local compression increases with the packing density of the membrane, but is compensated for by the oligomerization of Ire1. This minimization of energetic cost induced by the membrane deformation of Ire1 forms the basis for the activation of Ire1 by lipid bilayer stress.
Fettsäuresynthasen vom Typ I (FAS I), hier bezeichnet als Fettsäuremegasynthasen,sind Multienzymkomplexe, in denen sämtliche funktionellen Domänen für die de-novo-Synthese von Fettsäuren einen strukturellen Verbund eingehen. Auch das für den Transport von Edukten und Intermediaten nötige Acyl Carrier Protein (ACP) ist kovalent gebundener Teil dieses Komplexes, der so zu einer hocheffizienten molekularen Maschine zur Massenproduktion dieser grundlegend essentiellen Zellbausteine wird. Die FAS I aus Pilzen (fFAS), als Gegenstand dieser Arbeit, mit einer Masse von bis zu 2,7 MDa ist heute in ihrer Struktur durch Röntgenkristallographische sowie elektronenmikroskopische Methoden gut charakterisiert. 48 funktionelle Domänen sind zu einem geschlossenen Reaktionskörper angeordnet, indem sie in einer strukturgebenden Matrix aus Expansionen und Insertionen bzgl. der enzymatischen Kerndomänen eingebettet sind, die 50% des gesamten Proteins ausmacht. Neben den zahlreichen strukturellen Informationen über fFAS ist jedoch noch wenig über ihre Assemblierung verstanden. Dabei ist sie nicht nur als ein Beispiel für das generelle Verständnis von Assemblierungsmechanismen von Multienzymkomplexen interessant, sondern wird hier auch als Ziel eines inhibitorischen Eingriffs betrachtet, um eine neue antimykotische Wirkstrategie abseits des Ausschaltens aktiver Zentren zu evaluieren. Nur wenn die Mechanismen und Wechselwirkungen im Assemblierungsprozess offen gelegt sind, lassen sie sich später gezielt attackieren. Essentielle Sekundärstrukturmotive müssen identifiziert und bewertet werden, um sie einer weiteren Evaluation als Drug-Target-Kandidaten zugänglich zu machen. In dieser Arbeit werden Resultate aus in-vivo-Experimenten an rational mutierten fFAS-Konstrukten unter Zuhilfenahme einer evolutionären Betrachtung der fFAS gemeinsam mit Erkenntnissen aus andernorts geleisteten in-vitro-Experimenten an fFAS-Fragmenten zu einem geordneten Assemblierungsweg der fFAS zusammengeführt. Dabei werden Evidenzen aus den Kausaltäten zentraler Anforderungen an einen Assemblierungsmechanismus der fFAS zu drei konsequenten Schlüsselschritten verdichtet, die (i) eine frühe Interaktion zweier komplementärer Polypeptidketten zu einer Pseudo-Einzelkette, (ii) eine posttranslationale Modifikation von ACP und (iii) die geordnete Reifung zum fertigen Komplex durch Selbstassemblierung der beteiligten Domänen umfassen. Durch rationale Mutationen an den Schnittstellenmotiven für die Pseudo-Einzelkettenbildung, werden diese als Schwachstelle der Assemblierung unterschiedlicher fFAS-Typen charakterisiert, wobei für S. cerevisiae nicht weniger als zwei gezielte Punktmutationen ausreichen, um die Assemblierung des gesamten Komplexes zu verhindern. Darüber hinaus zeigen Experimente mit fFAS-Konstrukten, deren Schnittstellenmotive einer intramolekular kompetitiven Wechselwirkung ausgesetzt sind, prinzipiell die Möglichkeit zur Inhibierung der fFAS-Assemblierung durch Störung der Pseudo-Einzelkettenbildung.
If the biotechnological production of chemicals can further replace or support regular synthetic chemistry, industry will be able to move away from fossil oils towards renewable sources. However, in many cases the much needed adaptation of biotechnological production systems is not yet developed to the necessary level.
For processes where short fatty acids (FA) are needed, as for example in the microbial production of biofuels in the gasoline range, protein engineering had not yet delivered feasible solutions. In this thesis, several approaches to introduce chain length control on type I fatty acid synthases (FAS) were established and made available in a publication and two patents. Therein, engineering was focused on rational design based on available structural information.
First, the type I FAS from C. ammoniagenes was used as a model enzyme to probe modifications on FAS in a low complex in vitro environment in order to gain information about structure-function relationships. At this stage, engineering was conducted in several rounds, first addressing possible ways to alter product distributions by changing substrate affinities through concise mutations in binding channels. Several FAS constructs were generated ranging from first successes, where short FA were produced as side products, to FAS where native chain length programming was overwritten and only short FA were produced.
Furthermore, another engineering target was addressed with the modification of domain-domain interactions on FAS. For its exploitation to direct synthesis, contact surfaces on catalytic domains were changed to interfere with acyl carrier protein binding. This channeling of the kinetic process on the enzyme led to similar successes and short FA became the primary product.
The two approaches have proven to be potent tools to introduce systems of chain length control in FAS. This rational engineering has the big advantage that it is mostly minimally invasive and due to the high conservation of de novo FA synthesis, individual mutations could easily be used in other FAS (and their organisms) as well. Even heterologous expression of modified FAS genes is feasible.
Engineering was not only tested in a defined in vitro environment and but also in S. cerevisiae as an exemplary in vivo system. The results eventually confirmed the in vitro findings and proved that the chosen engineering could be transferred to more complex systems. Even before any optimization for highest output, the titers of short FA from S. cerevisiae fermentation matched previous reports with 118 mg/L.
In sum, this work covers several layers from basic research to preliminary applications. The presented modifications to create short FA producing FAS can be a key step in synthesis pathways and will likely enable a whole range of new succeeding research. It can be seen as a valuable contribution towards establishing novel ways for the production of chemicals from renewable sources.
Multidomain enzymes, such as fatty acid synthases (FASs) or polyketide synthases (PKSs), play a crucial role in the biosynthesis of important natural products. They have a high significance in the development of new pharmaceuticals and various research approaches focus on the engineering of these proteins. For example, human type I FAS is an interesting therapeutic target. Owing to its importance in lipogenesis, upregulation of human type I FAS expression has been observed in numerous cancers. Type I FAS is also regarded as important target in antiobesity treatment. Both multidomain enzyme classes - FASs and PKSs - show high structural and functional similarities. Particularly animal type I FAS is most relevant as evolutionary precursor of the PKS family. Therefore, the well characterized FASs are suitable model proteins for the poorly characterized PKSs, to gain deeper understanding in these megasynthases.
Furthermore, fatty acids are considered to be strategically important platform chemicals accessible through sustainable microbial approaches. The recently acquired structural information on FASs provides an excellent understanding of the molecular basis of fatty acid synthesis. The specific understanding of chain-length control, the characterization of a multitude of substrate-specific thioesterases, and the emerging tools and means for metabolic engineering have fostered targeted approaches for modulating chain length. There is large interest in short-chain fatty acids, since these compounds are biotechnologically valuable platform chemicals and biofuel precursors, and attempts on the synthesis of short-chain fatty acids have been reported during the last years.
Primary focus of this thesis lies on the animal type I FASs, which exhibit large conformational variety, as seen in electron microscopy and high-speed atomic force microscopy. Conformational dynamics facilitate productive protein-protein interactions between catalytic domains within the enzyme and aid acyl carrier protein (ACP)-mediated substrate shuttling during the catalytic cycle of fatty acid biosynthesis. To gain deeper insight into the fundamental processes of ACP-mediated substrate shuttling and the underlying conformational dynamics, spectroscopic methods like Förster resonance energy transfer and electron paramagnetic resonance spectroscopy shall be employed. These spectroscopic methods demand site-specific labeling of proteins with fluorophore or spin labels, which can be accomplished with the amber codon suppression technology. Through amber codon suppression, a non-canonical amino acid (ncAA) with an orthogonal functional group is incorporated site-specifically into the protein sequence, which can be used in chemoselective reactions for protein labeling.
This thesis is at the forefront of employing the technology of amber codon suppression for addressing complex biological questions on megasynthases. The successful production of ncAA-modified FASs is challenging. With the aim of incorporating ncAAs into the multidomain 540 kDa large murine FAS, we by far exceed boundaries of documented application of amber codon suppression. Most of the proteins that are reported by Liu & Schultz in applications of amber codon suppression are in the range of 30kDa - for example the TE domain of human FAS. In the same review, the largest protein amber codon suppression was applied to is a potassium channel with roughly 80 kDa. Thus, to the best of my knowledge no protein exceeding 100 kDa has been used in amber codon suppression so far.
In this thesis a low-complex, well-plate based reporter assay is presented, based on an ACP-GFP fusion protein for fast and efficient screening of ncAA incorporation. Reliability and applicability of the reporter assay is demonstrated by successful upscaling to larger protein constructs and increased expression scale.
As outlined in this thesis, we have carefully set up methods for the modification of murine FAS and made several achievements:
(i) We have created our own toolbox with a multitude of suppressor plasmids and various orthogonal pairs. pACU and pACE plasmids are compatible for fast exchange of cassettes, and cloning procedures are optimized for modification of synthetases by site-directed mutagenesis. (ii) We have organic synthesis of several ncAAs stably running in the lab and synthesis of other ncAAs can be established when required. Therefore, extensive screening at moderate costs is possible. (iii) We have established a reporter assay for screening our own library of vectors for amber codon suppression and for optimizing incorporation of ncAAs. (iv) We successfully incorporated ncAAs into subconstructs and full-length murine FAS, and collected initial promising results for the application of these proteins in spectroscopic methods. Thus, laying the foundation for future studies to address fundamental questions of the ACP-mediated substrate shuttling and other conformational dynamics of these enzymes.
This work comprises the investigation of four different biosynthesis gene clusters from Xenorhabdus. Xenorhabdus is an entomopathogenic bacterium that lives in mutualistic symbiosis with its Steinernema nematode host and together they infect and kill insect larvae. Xenorhabdus is well known for the production of so-called specialised metabolites and many of these compounds are synthesised by non-ribosomal peptide synthetases (NRPSs) or NRPS-polyketide synthase (PKS)-hybrids. These enzymes are organised in a modular manner and produce structurally very diverse molecules, often with the help of modifying domains and tailoring enzymes. In general, the genes involved in the biosynthesis are organised in so-called biosynthetic gene clusters (BGCs) in the genome of the producing strain. Exchanging the native promoter with an inducible promoter, e.g. PBAD, allows the targeted activation of the BGC and in turn the analysis of the biosynthesis product via LC-MS analysis.
The first BGC investigated in this work is responsible for the biosynthesis of xenofuranones. Based on gene deletions, this work shows that the NRPS-like enzyme XfsA produces a carboxylated furanone intermediate which is subsequently decarboxylated by XfsB to yield xenofuranone B. The next step in xenofuranone biosynthesis is the O-methylation of xenofuranone B to yield xenofuranone A. A comparative proteomics approach allowed the identification of four methyltransferase candidates and subsequent gene deletions confirmed one of the candidates to be responsible for methylation of xenofuranone B. The proteome analysis was based on the comparison of X. szentirmaii WT and X. szentirmaii Δhfq because distinct levels of the methylated xenofuranone A were observed when the xfs BGC was activated in either WT or Δhfq strain. Hfq is a global transcriptional regulator whose deletion is associated with the down regulation of natural product biosynthesis in Xenorhabdus. The strong PBAD activation of the xfs BGC also allowed the detection of two novel xenofuranone derivatives which arise from incorporation of one 4-hydroxyphenylpyruvic acid as first or second building block, respectively.
PBAD based activation of the second BGC addressed in this work lead to the detection of a novel metabolite and compound purification allowed NMR-based structure elucidation. The molecule exhibits two pyrrolizidine moieties and was named pyrrolizwilline (pyrrolizidine + twin (German: “Zwilling”)). The BGC comprises seven genes and single gene deletions as well as heterologous expression in E. coli and NRPS engineering were conducted to investigate the biosynthesis. The first two genes xhpA and xhpB encode a bimodular NRPS and a monooxygenase which synthesise a pyrrolizixenamide-like structure, similar to PxaA and PxaB in pyrrolizixenamide biosynthesis. It is suggested that the acyl side chain incorporated by XhpA is removed by the α,β-hydrolase XhpG. The keto function is then reduced by two subsequent two electron reductions catalysed by XhpC and XhpD. One of these two reduced pyrrolizidine units most likely is extended with glyoxalate prior to non-enzymatic dimerisation with the second pyrrolizidine moiety. To finally yield pyrrolizwilline, L-valine is incorporated, probably by the free-standing condensation domain XhpF.
The third BGC investigated is responsible for the production of a tripeptide composed of β-D-homoserine, α-hydroxyglycine and L-valine and is referred to as glyoxpeptide. This work demonstrates that the previously observed glyoxpeptide derivative is derived from glycerol present in the culture medium. Furthermore, this work shows that the monooxygenase domain, which is found in an unusual position between motifs A8 and A9 within the adenylation domain, is responsible for the α-hydroxylation of glycine. It is suggested that the α-hydroxylation of glycine renders the tripeptide prone to hydrolysis via hemiacetal formation. Hence, the XgsC_MonoOx domain might be an interesting candidate for further NRPS engineering.
The fourth BGC addressed is responsible for the production of xildivalines and this work describes two additional derivatives which are detected only when the promoter is exchanged and activated in the X. hominickii WT strain but not in X. hominickii Δhfq. Deletion of the methyltransferase encoding gene xisE results in the production of non-methylated xildivalines. It remains to be determined when the N-methylation of L-valine takes place. It is discussed that the methyltransferase could act on the NRPS released product but also during the assembly. The peptide deformylase is not involved in the proposed biosynthesis as xildivaline production is detected in a ΔxisD strain. The PKS XisB features two adjacent, so-called tandem T domains. The inactivation of the first or the second T domain by point mutation causes decreased production titres of detected xildivalines in the respective mutant strain when compared to the wild type.
This thesis reports on the results obtained by expression photoactivatable adenylyl cyclase from Beggiatoa spp. (bPAC) in cholinergic neurons from Caenorhabditis elegans (C. elegans) and the characterization of the role of a single neuron, RIS, during locomotion in the adult animal.
Pharmacological activation of adenylyl cyclases through Forskolin is known to induce increased neuronal output in diverse model organisms through a protein kinase A (PKA) dependent mechanism. Nevertheless, pharmacological assays are not spatially restricted, do not allow for precise and acute activation nor to cessation of the signal. Thus, an optogenetic approach for was selected trough the expression of photoactivatable adenylyl cyclase from Beggiatoa spp. (bPAC) in cholinergic neurons of Caenorhabditis elegans (C. elegans). This model organism was chosen due to its transparency, ease of maintenance, fast generation cycles as well as for being an eutelic animal. Further, its genome has been fully sequenced and the connectome of the neuronal network is known, thus allowing for precise analysis of neuronal function. Furthermore, the molecular mechanisms governing neuronal functions are well conserved up to primates. Mainly two optogenetical tools were applied, bPAC and the light gated cation channel channelrhodopsin 2 (ChR2).
Behavioral assays of bPAC photostimulation in cholinergic neurons recapitulated previous work performed with the photoactivatable adenylyl cyclase from Euglena gracilis (EuPACa), in which swimming frequency and speed on solid substrate were increased. Electrophysiological recordings of body wall muscle (BWM) cells by Dr. Jana F. Liewald showed that bPAC photoactivation led to an increase in miniature postsynaptic current (mPSC) rate and, in contrast to ChR2 invoked depolarization, also amplitude. Analysis of mutants deficient in neuropeptidergic signaling (UNC- 31) via electrophysiology performed by Dr. Jana F. Liewald showed that the increase in mPSC amplitude due to bPAC photoactivation requires neuropeptide release. This was confirmed by co-expression of bPAC with the neuropeptide marker NLP-21::Venus and subsequent fluorescence analysis of release, exploiting the fact that released neuropeptides are ultimately degraded by scavenger cells (coelomocytes). These were enriched with NLP-21::Venus after bPAC photostimulation, but no fluorescence could be observed in the UNC-31 mutants.
Additional analysis of the electrophysiological data performed by myself showed no modulation of mPSC kinetics dues to neuropeptidergic release induced by bPAC. Hence, neuropeptide release and action sites were in the cholinergic neurons, the latter including cholinergic motoneurons.
Dr. Szi-chieh Yu provided electron microscopy images of high pressure frozen, bPAC or ChR2 expressing animals. These were tagged by myself for automatic analysis of ultrastructural properties of the cholinergic presynapse, also during photoactivation of both optogenetic tools. Photoactivation of both induced a reduction of synaptic vesicles, with ChR2 showing a more severe effect. In contrast to ChR2, though, bPAC also reduced the amount of dense core vesicles (DCV), the neuropeptide transporters. Additionally, long bPAC photoactivation as well as ChR2 photoactivation led to the appearance of large vesicles (LV), presumably in response to the increased SV fusion rate. bPAC photostimulation also induced an increase in SV size, not observed after ChR2 photostimulation. In UNC-31 mutants, bPAC photostimulation could not lead to the SV size increase, a further argument for the presynaptic effect of the released neuropeptide. Additional analysis of electrophysiology paired with pharmacology, performed by Dr. Jana F. Liewald, showed that mPSC amplitude increase requires the function of the vesicular acetylcholine transporter.
A further effect observed in the ultrastructure of bPAC photostimulated cholinergic presynapses was a shift in the distribution of SV regarding the dense projection. An analysis of cAMP pathway mutants showed that synapsin is required for bPAC induced behavior effects. Synapsin is known to mediate SV tethering to the cytoskeleton. Here, I show evidence for a new role of synapsin in controlling the availability of DCVs for fusion and thus, in neuropeptidergic signaling.
In the second part of my thesis I characterized the function of the GABAergic interneuron RIS in the neuronal network of C. elegans. RIS was shown to induce lethargus, a sleep-like state, during all larval molts, but its function in the adult animal was not yet described. Specific RIS expression of ChR2 achieved by a recombinase based system allowed to acutely depolarize the neuron during locomotion, which led to an acute behavioral stop. Diverse signal transduction pathway mutants were analyzed showing that the phenotype was induced by neuropeptidergic signaling. Through mutagenesis followed by whole genome sequencing data analysis as well as analysis of RIS specific RNA sequencing data further narrowed the signal transduction pathway to mediate the locomotion stop behavior. Since the neuropeptide and, to some extent, the neuron are conserved across nematodes, an argument is outlined in favor of the conservation of this sleep-like state.
In addition, since ChR2 could induce neuropeptidergic signaling from RIS, secretion of vesicles is regulated by variable pathways depending on the neuronal identity. Nevertheless, expression of bPAC in RIS allowed to optogenetically increase the probability of short stops, as observed by expression of a calcium sensor (GCaMP) in RIS and analysis of its intrinsic activity in the adult animal.
Non-ribosomal peptide synthetases (NRPSs) are modular biosynthetic megaenzymes producing many important natural products and refer to a specific set of peptides in bacteria’s and fungi’s secondary metabolism. With the actual purpose of providing advantages within their respective ecological niche, the bioactivity of the structurally highly diverse products ranges from, e.g., antibiotic (e.g., vancomycin) to immunosuppressive (e.g., cyclosporin A) to cytostatic (e.g., echinomycin or thiocoralin) activity.
An NRPS module consists of at least three core domains that are essential for the incorporation of specific substrates with the 'multiple carrier thiotemplate mechanism' into a growing peptide chain: an adenylation (A) domain selects and activates a cognate amino acid; a thiolation (T) domain shuffles the activated amino acid and the growing peptide chain, which are attached at its post-translationally 4ʹ-phosphopantetheine (4'-PPant) group, between the active sites; a condensation (C) domain links the upstream and downstream substrates. NRPS synthesis is finished with the transfer of the assembled peptide to the C-terminal chain-terminating domain. Accordingly, the intermediate is either released by hydrolysis as a linear peptide chain or by an intramolecular nucleophilic attack as a cyclic peptide.
The NRPS’s modular character seems to imply straightforward engineering to take advantage of their features but appears to be more challenging. Since the pioneering NRPS engineering approaches focused on the reprogramming and replacement of A domains, several working groups developed advanced methods to perform a complete replacement of subdomains or single or multiple catalytic domains.
The first part of this work focusses parts of the publication with the title 'De novo design and engineering of non-ribosomal peptide synthetases', which follows up assembly line engineering with the development of a new guideline. Thereby, the pseudodimeric V-shaped structure of the C domain is exploited to separate the N-terminal (CDSub) and C-terminal (CASub) subdomains alongside a four-AA-long linker. This results in the creation of self-contained, catalytically active CASub-A-T-CDSub (XUC) building blocks. As an advantage over the previous XU concept, the characteristics (substrate- and stereoselectivity) assigned to the C domain subunits are likewise exchanged, and thus, no longer represent a barrier. Furthermore, with the XUC concept, no important interdomain interfaces are disrupted during the catalytic cycle of NRPS, allow to expect much higher production titers. Moreover, the XUC concept shows a more flexible application within its genus origin of building blocks to create peptide libraries. Additionally, with this concept only 80 different XUC building blocks are needed to cover the entire proteinogenic amino acid spectrum.
The second part of this work addresses the influence of the C domain on activity and specificity of A domains. In a comprehensive analysis, a clear influence of different C domains on the in vitro activation rate and the in vivo substrate spectrum could be observed. Further in situ and in silico characterizations indicate that these influences are neither the result of the respective A domains promiscuity nor the C domain’s proofreading, but due to an 'extended gatekeeping' function of the C domain. This novel term of an 'extended gatekeeping' function describes the very nature of interfaces that C domains can form with an A domain of interest. Therefore, the C-A interface is assumed to have a more significant contribution to a selectivity filter function.
The third part of this work combines the NRPS engineering with phylogenetic/evolutionary perspectives. At first, the C-A interface could be precisely defined and further identified to encode equivalent information corresponding to the complete C-A didomain. Moreover, the comparison of NRPSs topology reveals hints for a co-evolutionary relatedness of the C-A didomain and could be shown to reassemble even after separation. In this regard, based on a designed CAopt.py algorithm, the reassembling-compatibility of hybrid interfaces could be determined by scoring of the co-expressed NRPS hybrids. This algorithm also enables the randomization of the interface sequences, thus, leading to the identification of more functional interface variant, which cause significantly higher peptide production and could even be applied to other native and hybrid interfaces.
Physical Biology is a field of life sciences dealing with the extraction of quantitative data from biophysical or molecular biological experiments with different levels of complexity. Such data are further used as parameters for mathematical models of the biological system. These models allow to predict reactions on external stimuli by describing the relevant molecular interactions and are therefore used for example to generate a deeper comprehension of complex human diseases. An essential technique in biophysical research on human diseases is fluorescence microscopy. This is a constantly developed toolbox comprising a large number of specific labeling strategies, as well as a broad spectrum of fluorescent probes. It is further minimal invasive and therefore suitable for measurements in living cells or organisms. The sensitivity of modern photo-detectors even allows for the detection of a single fluorescent probe with an accuracy of approximately 10 nm.
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The model-prediction was further verified by two color SMLM experiments. In this work the development and application of imaging-systems are described which provide quantitative data with single-molecule resolution for systems biological model approaches with a low degree of abstractness. In the near future, the impact of mathematical models in the research field of complex human diseases will increase. The predictions of these models will be more exact, the more detailed and accurate the input parameters will become. This work gives an impression of how quantitative data obtained by SMLM may serve as input parameters for mathematical models at the single-cell level.
Polyketides are highly valuable natural products, which are widely used as pharmaceuticals due to their beneficial characteristics, comprising antibacterial, antifungal, immunosuppressive, and antitumor properties, among others. Their biosynthesis is performed by large and complex multiproteins, the polyketide synthases (PKSs). This study solely focuses on the class of type I PKSs, which arrange all their enzymatic domains on one or more polypeptides. Despite their high medical value, little is known about mechanistic details in PKSs.
One central domain is the acyl transferase (AT), which is present in all PKSs and channels small acyl substrates into the enzyme. More precisely, the AT loads the substrates onto the essential acyl carrier protein (ACP), which subsequently shuttles the substrates and all intermediates for condensation and modification to additional domains to build the final polyketide.
Some PKSs use their domains several times during biosynthesis and work iteratively – these are called iterative PKSs. Others feature several sets of domains, each being used only once during biosynthesis – these PKSs are called modular PKSs. All PKSs or PKS modules consist of minimum three essential domains to connect the acyl substrates. Three modifying domains are optional and can enlarge the minimal set. According to the domain composition, the acyl substrate is fully reduced, partly reduced, or not reduced at all. This variation of modifying domains accounts for the huge structural and therefore functional variety of polyketides.
Even though the structure of fatty acids is not exactly reminiscent of polyketides, their biosynthetic pathways are closely related. Fatty acid biosynthesis is carried out by fatty acid synthases (FASs), which share many similarities with PKSs. Both megasynthases feature the same domains, performing the same reactions to connect and modify small acyl substrates. In contrast to PKSs, FASs always contain one full set of modifying domains which is used iteratively, leading to fully reduced fatty acids.
The present thesis extensively analyzes the AT of different PKSs in its substrate selectivity, AT-ACP domain-domain interaction, and enzymatic kinetic properties. The following key findings are revealed through comparison: 1.) ATs of PKSs appear slower than the ones of FASs, which may reflect the different scopes of biosynthetic pathways. Fatty acids as essential compounds in all organisms are needed in high amounts for physiological functions, whereas polyketides as secondary metabolites only require basal concentrations to take effect. 2.) The slower ATs from modular PKSs do not load non-native substrates even in absence of the native substrates. This is different to the faster ATs from iterative PKSs and FASs, which indicates high substrate specificity solely for the ATs from modular PKSs and emphasizes their role as gatekeepers in polyketide synthesis. 3.) The substrate selectivity can emerge in either the first or the second step of the AT-mediated ACP loading and is not assured by a hydrolytic proofreading function.
Moreover, a mutational study on the AT-ACP interaction in the modular PKS 6-deoxyerythronolide B synthase (DEBS) shows that single surface point mutations can influence AT-mediated reactions in a complex manner. Data reveals high enzyme kinetic plasticity of the AT-ACP interaction, which was also recently demonstrated for the interaction in a type II FAS.
Based on these findings, the mammalian FAS is engineered towards a modular PKS-like as- sembly line with the long-term goal to rationally synthesize new products. Basically, three important aspects need to be considered: 1.) AT’s loading needs to be splitted in specific loading of a priming substrate by a priming AT and in specific loading of an elongation substrate by an elongation AT. 2.) FAS-based elongation modules need to be designed with varying domain compositions for introducing functional groups in the product. 3.) Covalent and non-covalent linkers need to be designed for connection of priming and elongation modules.
This study focuses on the first aspect, splitting loading of priming and elongation substrates. An elongation substrate-specific AT is installed in the mammalian FAS via domain swapping. Since ATs from modular PKSs were proven to be substrate specific, these are used to exchange the mammalian FAS AT. This work demonstrates that it is extremely challenging to create stable and functional chimeras, but first essential steps are taken. Proper domain boundaries for AT swapping are established and a stable chimera with 70 % wild type AT activity is created. However, this chimera is only of limited value for application in an elongation module due to the intrinsic slow turnover rate of the wild type AT. Using another PKS AT, a stable elongation module is designed and analyzed in its activity in combination with a priming module. These experiments demonstrate that the loading of priming substrates are successfully suppressed in the elongation module, but nonetheless only minor turnover rates are detected in the assembly line.
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RNA research is very important since RNA molecules are involved in various gene regulatory mechanisms as well as pathways of cell physiology and disease development.1 RNAs have evolved from being considered as carriers of genetic information from DNA to proteins, with the three major types of RNA involved in protein synthesis, including messenger RNA (mRNA), transfer RNA (tRNA), and ribosomal RNA (rRNA).2 In addition to the RNAs involved in protein synthesis numerous regulatory non-coding RNAs (ncRNAs) have been discovered in the transcriptome. The regulatory ncRNAs are classified into small ncRNAs (sncRNAs) with transcripts less than 200 nucleotides (nt) and long non-coding RNAs (lncRNAs) with more than 200 nt.3
LncRNAs represent the most diverse and versatile class of ncRNAs that can regulate cellular functions of chromatin modification, transcription, and post-transcription through multiple mechanisms.4 They are involved in the formation of RNA:protein, RNA:RNA and RNA:DNA complexes as part of their gene regulatory mechanism.4,5 The RNA:DNA interactions can be divided into RNA:DNA heteroduplex formation, also called R-loops, and RNA:DNA:DNA triplex formation. In triplex formation, RNA binds to the major groove of double-stranded DNA through Hoogsteen or reverse Hoogsteen hydrogen bonding, resulting in parallel or anti-parallel triplexes, respectively. In vitro studies have confirmed the formation of RNA:DNA:DNA triplexes.6 However, the extent to which these interactions occur in cells and their effects on cellular function are still not understood, which is why these structures are so exciting to study (Chapter I RNA:DNA:DNA Triplexes).
This cumulative thesis investigates several functional and regulatory important RNAs. The first project involves the improved biochemical and biophysical characterization of RNA:DNA:DNA triplex formation between lncRNAs of interest and their target genes. Triplex formation was confirmed by a series of experiments including electromobility shift assays (EMSA), thermal melting assays, circular dichroism (CD), and liquid state nuclear magnetic resonance (NMR) spectroscopy. The following is a summary of the main findings of these publications.
In research article 5.1, the oxygen-sensitive HIF1α-AS1 was identified as a functionally important triplex-forming lncRNA in human endothelial cells using a combination of bioinformatics techniques, RNA/DNA pulldown, and biophysical experiments. Through RNA:DNA:DNA triplex formation, endogenous HIF1α-AS1 decreases the expression of several genes, including EPH receptor A2 (EPHA2) and adrenomedullin (ADM), by acting as an adaptor for the repressive human silencing hub (HUSH) complex, which has been studied by our collaborators in the groups of Leisegang and Brandes.
2) Triplex formation between HIF1α-AS1 and the target genes EPHA2 and ADM was investigated in biochemical and biophysical studies. The EMSA results indicated that HIF1α-AS1 forms a low mobility RNA:DNA:DNA triplex complex with the EPHA2 DNA target sequence. The CD spectrum of the triplex showed distinct features compared to the EPHA2 DNA duplex and the RNA:DNA heteroduplex. Melting curve analysis revealed a biphasic melting transition for triplexes, with a first melting point corresponding to the dissociation of the RNA strand with melting of the Hoogsteen hydrogen bonds. The second, higher melting temperature corresponds to the melting of stronger Watson-Crick base pairing. Stabilized triplexes were formed using an intramolecular EPHA2 DNA duplex hairpin construct in which both DNA strands were attached to a 5 nucleotide (nt) thymidine linker. This approach allowed improved triplex formation with lower RNA equivalents and higher melting temperatures. By NMR spectroscopy, the triplex characteristic signals were observed in the 1H NMR spectrum, the imino signals in a spectral region between 9 and 12 ppm resulting from the Hoogsteen base pairing. To elucidate the structural and sequence specific Hoogsteen base pairs 2D 1H,1H-NOESY measurements of the EPHA2 DNA duplex and the HIF1α-AS1:EPHA2 triplex were performed. The 1H,1H-NOESY spectrum of the HIF1α-AS1:EPHA2 triplex with a 10-fold excess of RNA was semi-quantitatively analyzed for changes in the DNA duplex spectrum. We discovered, strong and moderate attenuation of cross peak intensities in the imino region of the NOESY spectrum. This attenuation was proposed to result from weakening of Watson-Crick base pairing by Hoogsteen hydrogen bonding induced by RNA binding. The Hoogsteen interactions can be mapped based on the analysis of the cross peak attenuation in the NOESY spectra, which we used to generate a structural model of the RNA:DNA:DNA triplex. These biophysical results support the physiological function of HIF1α as a triplex-forming lncRNA that recruits the HUSH-epigenetic silencing complex to specific target genes such as EPHA2 and ADM, thereby silencing their gene expression through RNA:DNA:DNA triplex formation.
Identification of new natural products from nematode-associated bacteria using mass spectrometry
(2023)
This work aims to find unknown natural products produced by bacteria, that live in close association with nematodes and to elucidate their structure by using mass spectrometry.
The first chapter of this work is dedicated to the detection of hitherto unknown natural products by using a metabolomics approach and subsequent structure elucidation of said compounds. This chapter includes metabolomics analysis of Xenorhabdus szentirmaii wild type and knockout mutants, overproduction of the target compound, identification of derivatives from other strains and MS based structure elucidation.
The second and third chapters are about natural products that protect C. elegans from B. thuringiensis infections.
The second chapter deals with natural products that protect the nematode host without killing the pathogen. I deployed molecular biology methods to generate deletion and overproduction strains of a target compound, identified it via LC-MS/MS analysis and used LC-MS/MS and lipidomics to analyse the chemical properties of the active compound.
The third chapter aims at finding natural products, which are produced by Pseudomonas strains MYb11 and MYb12, respectively. These natural products display the ability to protect C. elegans by killing B. thuringiensis. I identified said compounds via fractionation and subsequent bioactivity testing. After identification, I generated production strains of the target compounds and elucidated the structure of the bioactive derivative.
The last chapter deals with the structure elucidation of peptides produced by an unusual GameXPeptide synthetase in Xenorhabdus miraniensis. I analysed producer strains of GameXPeptides using LC-MS and elucidated the structural differences between the known GameXPeptides, produced by P. luminescens TT01, and the unusual ones produced by X. miraniensis.
Um molekulare Mechanismen in biologischen Prozessen zu verstehen, ist es unerlässlich biologisch aktive Verbindungen zu kontrollieren. Dabei spielt besonders die Aktivierung bzw. Desaktivierung von Genabschnitten eine zentrale Rolle in der gegenwärtigen chemischen, biologischen und medizinischen Forschung. Nukleinsäuren sind dabei offenkundige Zielmoleküle, da sie die Genexpression auf unterster Ebene regulieren und auf vielfältige Art und Weise an biologischen Prozessen beteiligt sind. Um solch eine genaue Steuerung zu erreichen, werden Nukleinsäuren häufig photolabil modifiziert und unter die Kontrolle von Licht gebracht. Da hochentwickelte Technologien es erlauben Photonen bestimmter Energie unter präziser räumlicher und zeitlicher Auflösung zu dosieren, ist Licht als nicht invasives Triggersignal ein besonders geeignetes Werkzeug um molekulare Prozesse zu kontrollieren.
Die Verwendung photolabiler Schutzgruppen („cage“) ermöglicht es, diese lichtaktivierbaren Nukleinsäuren („caged compound“) herzustellen. Üblicherweise werden Oligonukleotide damit an funktionsbestimmenden Stellen versehen, woraufhin die Funktion der Oligonukleotide unterdrückt wird. Die biologische Aktivität kann durch Bestrahlung mit Licht wieder hergestellt werden, da die photolabile Schutzgruppe durch den Lichtimpuls abgespalten wird. Neben der zeitweiligen Maskierung der Nukleinsäureaktivität existiert auch eine Methode, die als „photoaktivierbarer Strangbruch“ (‘‘caged strand break‘‘) bezeichnet wird. Dabei werden mit Hilfe von photolabilen Linkern (‘‘Verknüpfer‘‘) lichtinduzierte Strangbrüche in Oligonukleotiden ausgelöst, um so beispielsweise die Struktur eines Nukleinsäurestrangs zu zerstören. Die Idee der photoaktivierbaren Strangbrüche ist nicht neu, dennoch werden photolabile Schutzgruppen überwiegend nach der erstgenannten Strategie verwendet. Im Rahmen dieses Promotionsvorhabens wurden neue photosensitive Linkerbausteine für Oligonukleotide entwickelt und hergestellt, welche sich vor allem im Hinblick auf die Anwendbarkeit in lebenden biologischen Systemen von den bisherigen photolabilen Linkern unterscheiden.
Im ersten Projekt wurde ein nicht-nukleosidischer, photolabiler Linker, basierend auf dem Cumaringrundgerüst, entwickelt. Das Ziel war hier, vor allem, einen zweiphotonenaktiven Linker für biologische Anwendungen und Zweiphotonen-Fragestellungen nutzbar zu machen. Bisherige Zweiphotonen-Linker konnten hauptsächlich nur für Proteinverknüpfungen bzw. Neurotransmitter verwendet werden oder mussten chemisch umständlich (z.B. Click-Chemie) und postsynthetisch in Oligonukleotide eingeführt werden. Der neu entwickelte Zweiphotonen-Linker wurde als Phosphoramiditbaustein für die Oligonukelotid-Festphasensynthese synthetisiert, was einen problemlosen und automatisierten Einbau garantiert. Mit einem modifizierten Oligonukleotid konnten die photochemischen Eigenschaften des Linkers bestimmt und mit Hilfe eines fluoreszenzbasierten Verdrängungsassays und Lasertechniken der Zweiphotonen-Effekt visualisiert werden. Dazu wurde ein Hairpin-DNA-Strang hergestellt, welcher eine Linkermodifikation im Bereich der Loopregion enthält. Durch eine Thiolmodifikation am 5‘-Ende des Oligonukleotidstranges war es möglich, diesen in einem Maleimid-funktionalisierten Hydrogel zu fixieren. Ein DNA-Duplex mit einem Fluorophor/Quencherpaar und einer korrespondierenden Sequenz zum modifizierten Hairpin-Strang wurde ebenfalls dem System zugegeben, allerdings wurde dieser nicht fixiert, um Diffusion zu ermöglichen. Durch die räumliche Nähe des Fluorophors zum Quencher konnte im unbelichteten Zustand zunächst keine Fluoreszenz gemessen werden. Mit einem (Femtosekunden-)gepulsten Laser und dem damit verbundenen Bindungsbruch im Hairpin-Strang durch Zweiphotonen-Effekte wurde es dem fluoreszierenden Strang des DNA-Duplex ermöglicht, sich vom Quencher-Strang zu lösen und an den fixierten Strang zu hybridisieren. Das Photolyse-Ereignis konnte so in ein lokales Fluoreszenzsignal übersetzt und detektiert werden.
Der eindeutige Beweis, dass es sich tatsächlich um ein Zweiphotonen-induziertes Ereignis handelt, konnte durch die dreidimensional aufgelöste Photolyse und über die quadratische Anhängigkeit des Fluoreszenzsignals von der eingestrahlten Laserleistung erbracht werden.
Die generelle Kompatibilität des Cumarin-Linkers mit biologischen Systemen konnte in Zellkulturexperimenten gezeigt werden. Dazu wurde eine Transkriptionsfaktor-DNA Decoy-Strategie entwickelt, in der Linker-modifizierte DNA Decoys an regulatorische Transkriptionsfaktoren binden und diese aber auch photochemisch wieder freisetzen können („catch and release-Strategie“). Zellkulturexperimente, um mit dieser Methode das Transkriptionsfaktor-gesteuerte und endogene Gen für Cyclooxygenase-2 (COX2) zu regulieren, lieferten keine aussagekräftigen Ergebnisse. Daher wurden die verwendeten Zellen dahingehend manipuliert, sodass sie das Protein GFP (grün fluoreszierendes Protein) in Abhängigkeit von der Anwesenheit eines Transkriptionsfaktors exprimieren. Das so durch die Zellen verursachte Fluoreszenzsignal steht in direkter Abhängigkeit zur Decoy-Aktivität. Mit Hilfe modifizierter GFP-Decoys konnte hierbei eine Regulation auf Transkriptionsebene in biologischen Organismen erreicht werden. Mit dem Electrophoretic Mobility Shift Assay (EMSA), einer molekularbiologischen in vitro-Analysetechnik, wurden die Interaktionen zwischen modifizierten Decoys und dem Transkriptionsfaktor untersucht.
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Mitochondria perform essential energetic, metabolic and signalling functions within the cell. To fulfil these, the integrity of the mitochondrial proteome has to be preserved. Therefore, each mitochondrial subcompartment harbours its own system for protein quality control. However, if the capacity of mitochondrial chaperones and proteases is overloaded, mitochondrial misfolding stress (MMS) occurs. Upon this stress condition, mitochondria communicate with the nucleus to increase the transcription of nuclear encoded mitochondrial chaperones and proteases. This proteotoxic stress pathway was termed the mitochondrial unfolded protein response (UPRmt) aiming at restoring protein homeostasis. Despite being discovered over 25 years ago, the signalling molecules released by stressed mitochondria as well as the corresponding receptor and transcription factor remain poorly understood. With this study, we aimed at characterising the underlying signalling events and mechanisms of how mitochondria react to misfolded proteins. First, we aimed to establish different methods to induce MMS that triggers the transcriptional induction of mitochondrial chaperones and proteases detected by quantitative polymerase chain reaction. We were able to induce UPRmt signalling by overexpression of an aggregation-prone protein and by knock-down or inhibition of mitochondrial protein quality control components. To study the signalling in a time-resolved manner, we focused on the usage of the mitochondrial HSP90 inhibitor GTPP and the mitochondrial LONP1 protease inhibitor CDDO.
Early time point RNA sequencing analysis of cells stressed with GTPP or CDDO revealed upregulated genes in response to oxidative stress. Indeed, measurements of mitochondrial superoxide with the fluorescent dye MitoSOX showed increased levels of reactive oxygen species (ROS) upon MMS induction. In contrast, there was no induction of mitochondrial chaperones and proteases when combining MMS with antioxidants. Compartment-specific targeting of the hydrogen peroxide sensor HyPer7 revealed increased ROS levels in the intermembrane space and matrix of mitochondria, followed by elevated ROS levels in the cytosol at later time points. The importance of cytosolic ROS for the signalling was supported by preventing UPRmt induction with an inhibitor blocking the outer mitochondrial membrane pore. Thus, ROS were identified as an essential UPRmt signal.
To understand which cytosolic factor is modified by ROS, redox proteomics was performed. Here, reversible changes on cysteine residues of the HSP40 co-chaperone DNAJA1 were observed upon MMS. Consequently, transcriptional induction of UPRmt genes was abolished by DNAJA1 knock-down. To understand the function of DNAJA1 during UPRmt signalling, quantitative interaction proteomics upon MMS revealed an increased binding to mitochondrial proteins and its interaction partner HSP70. Immunoprecipitation confirmed a ROS-dependent interaction between HSP40 and HSP70. Increased binding to mitochondrial proteins represented a cytosolic interaction of DNAJA1 with mitochondrial precursor proteins, whose accumulation was confirmed by western blot. Moreover, a fluorescent protein targeted to mitochondria accumulated in the cytosol during GTPP treatment, confirming a reduced import efficiency upon MMS. Preventing the accumulation of precursors by a translation inhibitor or depletion of a general mitochondrial transcription factor resulted in reduced UPRmt activation. Thus, DNAJA1 is essential for UPRmt signalling, since its oxidation by mitochondrial ROS and its enhanced recruitment to mitochondrial precursors allows the integration of both MMS-induced signals.
To link these findings to an increased transcription of mitochondrial chaperones and proteases, we screened for transcription factors accumulating in the nucleus upon MMS by cellular fractionation mass spectrometry. We demonstrated that specifically HSF1 accumulates in nuclei of cells stressed with GTPP or CDDO. Depletion of HSF1 by knock-down or knock-out resulted in the abrogation of the UPRmt-specific transcriptional response. HSF1 activation was visualised by nuclear accumulation on western blot, a process inhibited by ROS and precursor suppression. Moreover, DNAJA1 depletion prevented HSF1 activation. Ultimately, we proved by immunoprecipitation that the inhibitory interaction between HSF1 and HSP70 is reduced upon MMS.
Thus, we conclude that MMS increases mitochondrial ROS that are released into the cytosol. In addition, the import efficiency is reduced upon MMS, resulting in the accumulation of non-imported mitochondrial precursor proteins in the cytosol. Both signals are recognised via DNAJA1 oxidation and substrate binding. The concurrent recruitment of HSP70 to DNAJA1 results in the loss of the inhibitory HSP70-HSF1 interaction. Thus, active HSF1 can migrate to the nucleus to initiate transcription of mitochondrial chaperones and proteases. These findings are in accordance with observations in yeast, where mistargeted mitochondrial proteins activate cellular stress responses. Our results highlight a surprising interconnection and dependence of the mitochondrial and the cytosolic proteostasis network, in which the UPRmt is activated by a combination of two mitochondria-specific proteotoxic stress signals.
This work characterizes the post-PKS modifications of AQ-256. Additionally, the second part describes the establishment of an AQ production platform for electrolyte generation that can be utilized in redox-flow-batteries. Lastly, a silent BGC that encodes the genes for terpenoid biosynthesis was described and characterized with regards to product formation and putative ecological function.
This work addresses the investigation of the biosynthesis mechanisms of type II polyketide synthase (PKS) and fatty acid synthase (FAS) derived specialized metabolites (SMs) from Photorhabdus laumondii.
The elucidation of the biosynthetic pathway of the bacterial 3,5-dihydroxy-4-isopropyl-trans-stilbene (IPS) was one of the major topics of this thesis. IPS exhibits several bioactive characteristics as it inhibits the phenoloxidase of insects, acts antibacterial, but also influences the soluble epoxide hydrolase which is involved in inflammatory reactions. It was recently approved as a treatment against psoriasis by the FDA and is the first Photorhabdus derived drug.
The stilbene generation in Photorhabdus requires the formation of the two acyl-carrier-protein (ACP) bound 5-phenyl-2,4-pentadienoyl- and isovaleryl-β-ketoacyl-moieties. The ketosynthase (KS)/cyclase StlD catalyzes a ring formation via a Michael-addition between the two intermediates which is then further processed by an aromatase. The formation of 5-phenyl-2,4-pentadienoyl-ACP was shown via in vitro assays with purified proteins by proving the influence of the KS FabH, ketoreductase FabG and dehydratase FabA or FabZ of the fatty acid metabolism. While E. coli was able to complement most of these enzymes in attempts to produce IPS in the heterologous host, the Photorhabdus derived FabH was not replaceable despite 73 % sequence identity with the E. coli based isoenzyme, acting as a gatekeeper enzyme for cinnamic acid (CA) moieties. Furthermore, the ability to incorporate meta-substituted halogenated CA-derivatives was shown in order to produce 3-chloro- and 3-bromo-IPS. While studying the stilbene biosynthesis, the ability of Photorhabdus and Xenorhabdus to produce hydrazines was also discovered.
The second investigated biosynthesis was the formation of benzylideneacetone (BZA). BZA is produced by Photorhabdus and Xenorhabdus strains acting as a suppressor for the immune cascade of insects and has also antibiotic activities towards Gram-negative bacteria. Due to its structural similarity towards CA and the intermediates during the stilbene formation, a shared mechanism for Photorhabdus and Xenorhabdus budapestensis was proposed due to their ability to produce CA. The production of BZA was also dependent on the stilbene related CoA-ligase, the ACP and FabH. It was verified in vitro and in vivo in E. coli yielding a 150-fold increase of the BZA production compared to the Photorhabdus and Xenorhabdus wildtype (WT) strains.
The second part of this work deals with the optimization of P. laumondii strains regarding the production titers of IPS. Therefore, several deletions of other SM related genes as well as promoter exchanges in front of stilbene related genes were carried out. These approaches were combined with the upregulation of the phenylalanine by heterologous plasmid expression, since it is the precursor of CA. Another approach applied in parallel was the optimization of the cultivation conditions with different media and supplementation with XAD-resins. It was proved that media rich on fatty acids or peptides led to higher optical densities of the cultures and thus to higher titers of stilbenes. Since IPS is inhibiting the phenoloxidase, an enzyme important for the insect immunity, it was hypothesized that cultivation in media containing insects might enhance the output of this SM. Starting from 23 mg/l of IPS in the P. laumondii WT strain, it was possible to increase the production levels to more than 860 mg/l by utilizing the mentioned approaches.
The last topic of this thesis focuses on the production of epoxidated IPS (EPS) and its derivatives. Under laboratory conditions, only a low titer of EPS was observed for the wildtype strain. However, the optimized IPS strains and IPS-production conditions could also be applied for EPS which led to higher productions and also to the detection of many new derivatives. Most of the EPS derivatives were amino acid or peptide derived acting as nucleophiles to open the epoxide ring and yielding β-amino-alcohols. However, purification and chemical synthesis attempts to obtain EPS failed due to its poor stability. Epoxides were utilized in in vitro assays with amino acids, peptides and proteins to get insights whether epoxidations might act as posttranslational modification in Photorhabdus. The reactions were performed with styrene oxide and stilbene oxide replacing EPS based on their structural similarity. The modifications were executed successfully although proteomics approaches with in vivo data are required to confirm these findings. During the purification attempts of EPS, further derivatives were detected. The structures of dimerized stilbenes, a cis-isomer of IPS and another derivative that might incorporate an amino-group in the resveratrol ring were proposed on the basis of the HPLC-MS data.