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We compiled an NMR data set consisting of exact nuclear Overhauser enhancement (eNOE) distance limits, residual dipolar couplings (RDCs) and scalar (J) couplings for GB3, which forms one of the largest and most diverse data set for structural characterization of a protein to date. All data have small experimental errors, which are carefully estimated. We use the data in the research article Vogeli et al., 2015, Complementarity and congruence between exact NOEs and traditional NMR probes for spatial decoding of protein dynamics, J. Struct. Biol., 191, 3, 306–317, doi:10.1016/j.jsb.2015.07.008 [1] for cross-validation in multiple-state structural ensemble calculation. We advocate this set to be an ideal test case for molecular dynamics simulations and structure calculations.
The solution structure of the lantibiotic immunity protein NisI and its interactions with nisin
(2015)
Many Gram-positive bacteria produce lantibiotics, genetically encoded and posttranslationally modified peptide antibiotics, which inhibit the growth of other Gram-positive bacteria. To protect themselves against their own lantibiotics these bacteria express a variety of immunity proteins including the LanI lipoproteins. The structural and mechanistic basis for LanI-mediated lantibiotic immunity is not yet understood. Lactococcus lactis produces the lantibiotic nisin, which is widely used as a food preservative. Its LanI protein NisI provides immunity against nisin but not against structurally very similar lantibiotics from other species such as subtilin from Bacillus subtilis. To understand the structural basis for LanI-mediated immunity and their specificity we investigated the structure of NisI. We found that NisI is a two-domain protein. Surprisingly, each of the two NisI domains has the same structure as the LanI protein from B. subtilis, SpaI, despite the lack of significant sequence homology. The two NisI domains and SpaI differ strongly in their surface properties and function. Additionally, SpaI-mediated lantibiotic immunity depends on the presence of a basic unstructured N-terminal region that tethers SpaI to the membrane. Such a region is absent from NisI. Instead, the N-terminal domain of NisI interacts with membranes but not with nisin. In contrast, the C-terminal domain specifically binds nisin and modulates the membrane affinity of the N-terminal domain. Thus, our results reveal an unexpected structural relationship between NisI and SpaI and shed light on the structural basis for LanI mediated lantibiotic immunity.
Chemistry and time
(2015)
Intrinsically disordered protein (IDP) duplexes composed of two IDP chains cross-linked by bivalent partner proteins form scaffolds for assembly of multiprotein complexes. The N-terminal domain of dynein intermediate chain (N-IC) is one such IDP that forms a bivalent scaffold with multiple dynein light chains including LC8, a hub protein that promotes duplex formation of diverse IDP partners. N-IC also binds a subunit of the dynein regulator, dynactin. Here we characterize interactions of a yeast ortholog of N-IC (N-Pac11) with yeast LC8 (Dyn2) or with the intermediate chain-binding subunit of yeast dynactin (Nip100). Residue level changes in Pac11 structure are monitored by NMR spectroscopy, and binding energetics are monitored by isothermal titration calorimetry (ITC). N-Pac11 is monomeric and primarily disordered except for a single α-helix (SAH) at the N terminus and a short nascent helix, LH, flanked by the two Dyn2 recognition motifs. Upon binding Dyn2, the only Pac11 residues making direct protein-protein interactions are in and immediately flanking the recognition motifs. Dyn2 binding also orders LH residues of Pac11. Upon binding Nip100, only Pac11 SAH residues make direct protein-protein interactions, but LH residues at a distant sequence position and L1 residues in an adjacent linker are also ordered. The long distance, ligand-dependent ordering of residues reveals new elements of dynamic structure within IDP linker regions.
[Nachruf] Franz Josef Comes
(2015)
The title compound, C21H26Cl2N2O2, was prepared in a solvent-free microwave-assisted synthesis, and crystallizes in the orthorhombic space group Pna21. The imidazolidine ring adopts an envelope conformation and its mean plane is almost perpendicular to the two pendant aromatic rings [dihedral angles = 84.61 (9) and 86.54 (9)°]. The molecular structure shows the presence of two intramolecular O—H⋯N hydrogen bonds between the phenolic hydroxy groups and imidazolidine N atoms. The two 3-chloro-6-hydroxy-2,4-dimethylbenzyl groups are located in a cis orientation with respect to the imidazolidine fragment. As a result, the lone pairs of electrons on the N atoms are presumed to be disposed in a syn conformation. This is therefore the first example of an exception to the `rabbit-ears' effect in such 2,2′-[imidazolidine-1,3-diylbis(methylene)]diphenol derivatives.
A current challenge in life sciences is to image cell membrane receptors while characterizing their specific interactions with various ligands. Addressing this issue has been hampered by the lack of suitable nanoscopic methods. Here we address this challenge and introduce multifunctional high-resolution atomic force microscopy (AFM) to image human protease-activated receptors (PAR1) in the functionally important lipid membrane and to simultaneously localize and quantify their binding to two different ligands. Therefore, we introduce the surface chemistry to bifunctionalize AFM tips with the native receptor-activating peptide and a tris-N-nitrilotriacetic acid (tris-NTA) group binding to a His10-tag engineered to PAR1. We further introduce ways to discern between the binding of both ligands to different receptor sites while imaging native PAR1s. Surface chemistry and nanoscopic method are applicable to a range of biological systems in vitro and in vivo and to concurrently detect and localize multiple ligand-binding sites at single receptor resolution.
Der viersemestrige Master-Studiengang Biochemie leitet sich aus der langjährigen Tradition in biomolekularer Forschung und Lehre in der Frankfurter Forschungslandschaft her und ist stark forschungsorientiert.
Ziel des Studienganges ist es, fachliche Kenntnisse, Fähigkeiten und Methodenkompetenzen zu vermitteln, mit denen die Absolventen in die Lage versetzt werden, in einem forschungsbezogenem Kontext selbstständig zu arbeiten. ...
As a surrogate of live cells, proteo-lipobeads are presented, encapsulating functional membrane proteins in a strict orientation into a lipid bilayer. Assays can be performed just as on live cells, for example using fluorescence measurements. As a proof of concept, we have demonstrated proton transport through cytochrome c oxidase.
CD44v6, a member of the CD44 family of transmembrane glycoproteins is a co-receptor for two receptor tyrosine kinases (RTKs), Met and VEGFR-2 (vascular endothelial growth factor receptor 2). CD44v6 is not only required for the activation of these RTKs but also for signalling. In order to understand the role of CD44v6 in Met and VEGFR-2 activation and signalling we tested whether CD44v6 binds to their ligands, HGF (hepatocyte growth factor) and VEGF (vascular endothelial growth factor), respectively. FACS analysis and cellular ELISA showed binding of HGF and VEGF only to cells expressing CD44v6. Direct binding of CD44v6 to HGF and VEGF was demonstrated in pull-down assays and the binding affinities were determined using MicroScale Thermophoresis, fluorescence correlation spectroscopy and fluorescence anisotropy. The binding affinity of CD44v6 to HGF is in the micromolar range in contrast with the high-affinity binding measured in the case of VEGF and CD44v6, which is in the nanomolar range. These data reveal a heparan sulfate-independent direct binding of CD44v6 to the ligands of Met and VEGFR-2 and suggest different roles of CD44v6 for these RTKs.
Cyclic GMP (cGMP) signalling regulates multiple biological functions through activation of protein kinase G and cyclic nucleotide-gated (CNG) channels. In sensory neurons, cGMP permits signal modulation, amplification and encoding, before depolarization. Here we implement a guanylyl cyclase rhodopsin from Blastocladiella emersonii as a new optogenetic tool (BeCyclOp), enabling rapid light-triggered cGMP increase in heterologous cells (Xenopus oocytes, HEK293T cells) and in Caenorhabditis elegans. Among five different fungal CyclOps, exhibiting unusual eight transmembrane topologies and cytosolic N-termini, BeCyclOp is the superior optogenetic tool (light/dark activity ratio: 5,000; no cAMP production; turnover (20 °C) ∼17 cGMP s−1). Via co-expressed CNG channels (OLF in oocytes, TAX-2/4 in C. elegans muscle), BeCyclOp photoactivation induces a rapid conductance increase and depolarization at very low light intensities. In O2/CO2 sensory neurons of C. elegans, BeCyclOp activation evokes behavioural responses consistent with their normal sensory function. BeCyclOp therefore enables precise and rapid optogenetic manipulation of cGMP levels in cells and animals.
Proton-pumping complex I of the mitochondrial respiratory chain is among the largest and most complex membrane protein complexes. The enzyme contributes substantially to oxidative energy-conversion in eukaryotic cells. Its malfunctions are implicated in many hereditary and degenerative disorders. Here, we report the X-ray structure of mitochondrial complex I at 3.6- 3.9 Å resolution describing in detail the central subunits that execute the bioenergetic function. A continuous axis of basic and acidic residues running centrally through the membrane arm connects the ubiquinone reduction site in the hydrophilic arm to four putative proton-pumping units. The binding position for a substrate analogous inhibitor and blockage of the predicted ubiquinone binding site provide a model for the ‘deactive’ form of the enzyme. The proposed transition into the active form is based on a concerted structural rearrangement at the ubiquinone reduction site rendering support for a two-state stabilization-change mechanism of protonpumping.
Membrane proteins are biological macromolecules that are located in a cell’s membrane and are responsible for essential functions within an organism, which makes them to prominent drug targets. The extraction of membrane proteins from the hydrophobic membrane bilayer to determine high-resolution crystal structures is a difficult task and only 2% of all solved proteins structures are membrane proteins. Computational methods may help to gain deeper insights into membrane protein structures and their functions. This study will give an overview of such computational methods on a representative set of membrane proteins and will provide ideas for future computational and experimental research on membrane proteins.
In a first step (chapter 2), I updated an earlier, manually-curated data set of homologous membrane proteins (HOMEP) to more recent versions in 2010 (HOMEP2) and 2013 (HOMEP3) using an automated clustering approach. High-resolution structures of membrane proteins listed in the PDB_TM database were structurally aligned and subsequently clustered using structural similarity scores. Both data sets were used as a standard gold reference set for subsequent work.
Subsequently, I have updated and applied the sequence alignment program AlignMe to determine protein descriptors that are suitable for detecting evolutionary relationship between homologous a-helical membrane proteins. Single input descriptors were tested alone and in combination with each other in different modes of AlignMe by optimizing gap penalties on the HOMEP2 data set. Most accurate alignments and homology models on the HOMEP2 data set were observed when using position-specific substitution information (P), secondary structure propensities (S) and transmembrane propensities (T) in the AlignMe PST mode. An evaluation on an independent reference set of membrane protein sequence alignments from the BAliBASE collection showed that different modes of AlignMe are suitable for different sequence similarity levels. The AlignMe PST mode improved the alignment accuracy significantly for distantly related proteins, whereas for closely-related proteins from the BAliBASE set the AlignMe PS mode was more suitable. This work was published in March 2013 in PLOS ONE. In order to allow also an easier usage of the AlignMe program, I have implemented a web server of AlignMe (chapter 4) that provides the optimized settings and gap penalties for the AlignMe P, PS and PST modes. A comparison to other recent alignment web server shows that the alignments of AlignMe are similar or even more accurate than those of other methods, especially for very distantly related proteins for which the inclusion of membrane protein information has been shown to be suitable. This work was published in the NAR web server issue in July 2014.
Although membrane-specific information has been shown to be suitable for aligning distantly related membrane proteins on a sequence level, such information was not incorporated into structural alignment programs making it unclear which method is the most suitable for aligning membrane proteins. Thus, I compared 13 widely-used pairwise structural alignment methods on an updated reference set of homologous membrane protein structures (HOMEP3) and evaluated their accuracy by building models based on the underlying sequence alignments and used scoring functions (e.g., AL4 or CAD-score) to rate the model accuracy (chapter 5). The analysis showed that fragment-based approaches such as FR-TM-align are the most useful for aligning structures of membrane proteins that have undergone large conformational changes whereas rigid approaches were more suitable for proteins that were solved in the same or a similar state. However, no method showed a significant higher accuracy than any other. Additionally, all methods lack a measure to rate the reliability of the accuracy for a specific position within a structure alignment. In order to solve these problems, I propose a consensus-type approach that combines alignments from four different methods, namely FR-TM-align, DaliLite, MATT and FATCAT and assigns a confidence value to each position of the alignment that describes the agreement between the methods. This work has been published 2015 in the journal “PROTEINS: structure, function and bioinformatics”.
Consensus alignments were then generated for each pair of proteins of the HOMEP3 data set and subsequently analyzed for single evolutionary events within membrane spanning segments and for irregular structures (e.g., 310- and p-helices) (chapter 6). Interestingly, single insertions and deletions could be observed with the help of consensus alignments in the conserved membrane-spanning segments of membrane proteins in four protein families. The detection of such single InDels might help to identify crucial residues for a proteins function.
A wide variety of enzymatic pathways that produce specialized metabolites in bacteria, fungi and plants are known to be encoded in biosynthetic gene clusters. Information about these clusters, pathways and metabolites is currently dispersed throughout the literature, making it difficult to exploit. To facilitate consistent and systematic deposition and retrieval of data on biosynthetic gene clusters, we propose the Minimum Information about a Biosynthetic Gene cluster (MIBiG) data standard.
Ribosomes are the central cellular assembly lines for protein synthesis. To cope with the translational needs, a proliferating mammalian cell can produce up to 7500-ribosomes per minute. However, under growth limiting conditions, such as nutrient depletion, ribosome synthesis is rapidly shut down exemplifying the importance of a tight coordination between ribosome supply and cellular energy status. In addition to the quantitative regulation, a strict quality control of ribosome synthesis is equally important, because alterations in the composition or function of ribosomes can lead to a variety of pathologies. To cope with these challenges a highly regulated, multi-step pathway of ribosome biogenesis has evolved. In mammals this pathway generates the mature 80S ribosomes that comprise the large 60S and the small 40S subunits. Together they contain around 80 ribosomal proteins and the 28S, 18S, 5.8S and 5S rRNAs. The 28S, 5.8S and 5S rRNAs are assembled into the large subunit, while the 18S rRNA is part of the small subunit. The pathway of ribosome biogenesis is a multi-step cellular process, where specific stages occur in distinct subcellular compartments. Transcription of the 47S rRNA, which is the precursor for the 28S, 18S and 5.8S species, occurs in the nucleolus. Modification of distinct bases and early processing of this precursor also take place in the nucleolus. Subsequently, the 40S and 60S pre-ribosomes take separate maturation routes through the nucleoplasm before their export and final assembly in the cytoplasm. The various stages of preribosomal maturation require the constant and sequential action of a large number of non-ribosomal proteins, known as trans-acting factors. These factors coordinate the delicate remodeling of the pre-ribosomal intermediates and thereby ensure proper progression of the maturation process. The remodeling events largely depend on the dynamics of post-translational modifications, such as phosphorylation or SUMOylation. This requires that the enzymes controlling these modifications are properly targeted to their sites of activity as they fulfill their functions within specific compartments. Here we studied the regulatory principles that govern the subcellular partitioning of the SUMO-specific isopeptidase SENP3 and its associated factor PELP1. Previous work from our laboratory has delineated the importance of the SUMO system for proper ribosome biogenesis in mammalian cells. In particular, we have shown that SENP3 is critically involved in 28S rRNA formation, which is a key step for pre-60S subunit maturation. A critical involvement of SENP3 at this stage of the maturation process is in agreement with the observed enrichment of SENP3 in the nucleolus, since 28S rRNA processing is considered to occur in the nucleolus. Our subsequent work identified the nucleolar scaffold protein NPM1 and the ribosomal trans-acting factor PELP1 as bona fide substrates of SENP3. For both proteins we could demonstrate modification by SUMO2/3 and define SENP3 as the demodifying enzyme. Depletion of SENP3 enhanced the conjugation of SUMO to both proteins and concomitantly reduced conversion of the 32S pre-rRNA to the mature 28S rRNA. PELP1 is part of a larger protein complex consisting of the core components PELP1, TEX10 and WDR18. We could show that the balanced SUMOylation/deSUMOylation of PELP1 controls the nucleolar/nucleoplasmic distribution of this complex. Enhanced SUMOylation, which is observed in the absence of SENP3, triggers the nucleolar release of the complex suggesting that SENP3-mediated deSUMOylation controls the dynamics of nucleolar trans-acting factors. Based on these findings we first wanted to understand, in which cellular compartment(s) SENP3 exerts its function on 28S maturation. Next, we wanted to tackle the question how the subcellular distribution of SENP3 is controlled. Finally
we addressed the question how the SUMOylation of PELP1 determines the subnuclear distribution of the PELP1 complex. This work initially revealed that the nucleolar localization of SENP3 is crucial for proper 28S rRNA formation and 60S ribosome maturation. Importantly, we could demonstrate that the nucleolar compartmentalization of SENP3 depends on its direct physical interaction with NPM1. Further, we could show that the amino-terminal region of SENP3 is necessary for its binding to NPM1 and nucleolar recruitment. Strikingly, this interaction requires the phosphorylation of SENP3, which is brought about by the mTOR kinase. By in-vitro kinase assays and mass-spectrometric approaches we identified five serine/threonine residues within the amino-terminal region of SENP3 that are targeted by mTOR (S/T 25, 26, 141, 142, 143). We could further demonstrate by mutagenesis that these sites in SENP3 are in fact critical for the phospho-dependent binding of SENP3 to NPM1 and its nucleolar recruitment.
Consistent with these data, we found that chemical inhibitors of the mTOR kinase trigger the nucleolar release of SENP3 and impair its interaction with NPM1. Strikingly, this goes along with severe 28S rRNA maturation defects demonstrating the physiological importance of mTOR signaling in the regulation SENP3 function and rRNA processing. By specifically depleting components of the either mTORC1 or mTORC2, we could attribute the observed effects to signaling by mTORC1 rather than mTORC2. In an attempt to find the negative regulators of SENP3 phosphorylation, we identified PP1-γ as the candidate phosphatase in this pathway. We found a strong physical interaction of SENP3 with PP1-γ and observed a loss of SENP3 nucleolar localization upon ectopic expression of PP1-γ. Thus we could define mTOR/PP1-γ mediated phosphorylation/dephosphorylation of SENP3 as an important
mechanism in the control of ribosome maturation. Given that mTOR activity is controlled by nutrient availability, SENP3 functions as a sensor that couples ribosome synthesis with nutrient availability. The second part of this work delineated the role of SUMOylated PELP1 in nucleoplasmic partitioning of the SENP3-PELP1 complex. It was revealed that the AAA-ATPase MDN1 binds preferentially to SUMO modified PELP1 and likely segregates SUMOylated PELP1 from nucleolar pre-60S particles. We initially found that the PELP1 complex associates with MDN1, a factor known to be involved in the 28S rRNA maturation. Notably, depletion of MDN1 led to an enhanced accumulation of the PELP1 complex in the nucleolus and a strong association of PELP1 with pre-60S particles, suggesting that MDN1 is required for the release of this complex from the pre-ribosomes. Intriguingly, the interaction of PELP1 with MDN1 requires SUMO2/3 and SUMOylated PELP1 shows enhanced binding to MDN1 when compared to unmodified PELP1. Taken together this work provides new insights in the control of the SENP3-PELP1 complex dynamics. We could define several layers for the coordinated spatial regulation of SENP3 and the PELP1 complex. This work therefore underscores the crucial importance of dynamic post-translational modifications for the control of ribosome maturation.
Crystallization and X-ray diffraction studies of a complete bacterial fatty-acid synthase type I
(2015)
While a deep understanding of the fungal and mammalian multi-enzyme type I fatty-acid synthases (FAS I) has been achieved in recent years, the bacterial FAS I family, which is narrowly distributed within the Actinomycetales genera Mycobacterium, Corynebacterium and Nocardia, is still poorly understood. This is of particular relevance for two reasons: (i) although homologous to fungal FAS I, cryo-electron microscopic studies have shown that bacterial FAS I has unique structural and functional properties, and (ii) M. tuberculosis FAS I is a drug target for the therapeutic treatment of tuberculosis (TB) and therefore is of extraordinary importance as a drug target. Crystals of FAS I from C. efficiens, a homologue of M. tuberculosis FAS I, were produced and diffracted X-rays to about 4.5 Å resolution.
Das Enzym 5-Lipoxygenase (5-LO) spielt eine entscheidende Rolle in der Generierung von Leukotrienen. Diese fungieren als wichtige proinflammatorische Mediatoren. Darüber hinaus ist die 5-LO anhand ihrer N-terminalen Domäne in der Lage mit verschiedenen Proteinen zu interagieren. Unter den Interaktionspartnern befindet sich Dicer, ein Enzym welches für den finalen Schritt der microRNA (miRNA)-Biosynthese verantwortlich ist. MiRNA sind kurze, nicht kodierende RNA Stränge mit einer typischen Länge von etwa 23 Nukleotiden, die an der posttranskriptionalen Regulierung der Proteinbiosynthese beteiligt sind.
Ziel dieser Arbeit war es den Einfluss der 5-LO auf die miRNA-Prozessierung im zellulären Kontext zu untersuchen. Als Modellsystem wurde die MonoMac6 (MM6) Zelllinie ausgewählt. MM6-Zellen exprimieren im undifferenzierten Grundzustand nur geringe Mengen an 5-LO. Erst nach Differenzierung mittels transformierenden Wachstumsfaktors ß (TGFß) und Calcitriol kommt es zur Induktion der 5-LO Proteinbiosynthese. Darüber hinaus war es Basavarajappa et al. möglich die 5-LO-Expression in diesen Zellen mittels RNA-Interferenz stark herunter zu regulieren (Δ5-LO).
Um die Frage der Auswirkungen des 5-LO knockdowns auf die miRNA-Expression analysieren zu können, wurde ein Microarray in differenzierten Kontroll-und Δ5-LO-Zellen durchgeführt.Es wurden 37 miRNAs identifiziert deren Expression 5-LO abhängig ist. Dabei war das Niveau von 30 Vertretern in Abwesenheit der 5-LO erhöht, wohingegen die Expression von sieben miRNAs reduziert war. Unter diesen sieben herunter regulierten miRNAs befanden sich miR-99b-5p und miR-125a-5p, die einem gemeinsamen Cluster entstammen. Als Cluster wird eine Gruppe von miRNAs bezeichnet, die aus einem gemeinsamen primären Transkript (pri-miRNA) hervorgeht. Diese Eigenschaft führte zur Vermutung, dass bereits die Expression dieser pri-miRNA durch die 5-LO reguliert wird. Allerdings zeigte sichim Verlauf dieser Arbeit, dass die Expression der pri-miRNA 5-LO unabhängig verläuft. Im Gegensatz dazu wies die Zwischenstufe zwischen pri-miRNA und reifer miRNA eine reduzierte Expression in Δ5-LO Zellen auf. Für die Prozessierung dieser sogenannten precursor miRNAs (pre-miRNA) ist die Ribonuklease III Drosha verantwortlich, welche die pre-miRNA aus der jeweiligen pri-miRNAs chneidet. Das verringerte pre-miR-99b-und pre-miR-125a-Niveau ist daher ein Hinweis darauf, dass überDicerhinausmöglicherweise ebenfalls die Drosha Aktivität mittels 5-LO reguliert wird.
Des Weiteren wurde untersucht iniefern Leukotriene beziehungsweise 5-LO-Inhibitoren die Expression von miR-99b-5p und miR-125a-5p beeinflussen. Dabei stellte sich heraus, dass das miRNA-Niveau unabhängig von der vorhandenen Leukotrien-Menge ist. Das 5-LO aktivierende Protein (FLAP) besitzt dahingegen einen mit der 5-LO vergleichbaren Einfluss auf die reife miRNA. FLAP ist ein weiterer Interaktionspartner der 5-LO und essentiell für die Leukotrien-Biosynthese in vivo. Anhand von Protein-Lokalisationsstudien mittels Immunofluoreszenz konnte gezeigt werden, dass FLAP außerdem in der Lage zu sein scheint die Relokalisation der 5-LO aus dem Zytoplasma in den Nukleus einzuschränken. Im Zytoplasma ist die 5-LO in der Lage mit Dicer zu interagieren. Daten bezüglich einer Interaktion zwischen Drosha und 5-LO im Zellkern liegen bisher nicht vor. Eine etwaige Interaktion könnte allerdings helfen die reduzierten pre-miRNA Spiegel in Abwesenheit der 5-LO zu erklären.
Im Laufe dieser Arbeit wurden weiterhin die Auswirkungen von proinflammatorischen Lipopolysacchariden (LPS) auf die Prozessierung von miR-99b-5p und miR-125a-5p analysiert. Ausschließlich in Anwesenheit von 5-LO zeigte sich eine differenzierungsunabhängig gesteigerte Biosynthese der pri-und der reifen miRNA. Allerdings konnte kein Einfluss von LPS auf die 5-LO-Lokalisation beziehungsweise Expression festgestellt werden. Aufgrund dessen sind weiterführende Studien, die den Zusammenhang zwischen LPS induzierter miR-99b-5p- beziehungsweise miR-125a-5p-Biosynthese und 5-LO herstellen, nötig.
Abschließend hat sich diese Arbeit mit den Zielgenen der durch 5-LO regulierten miRNAs auseinandergesetzt. Es konnte gezeigt werden, dass in Abwesenheit von miR-99b-5p und miR-125a-5p die Freisetzung der beiden durch LPS stimulierten Zytokine Interleukin 6 (IL-6) und Tumornekrosefaktor α (TNFα) gesteigert ist. Interessanterweise besitzt TNFα einen stimulierenden Effekt auf die Leukotrien-Biosynthese. Allerdings konnte kein direkter Zusammenhang zwischen miR-99b-5p/miR-125a-5p Expression, TNFα und der 5-LO Aktivität hergestellt werden. Der Einsatz von miR-99b-5p-und miR-125a-5p-Inhibitoren zeigte keine Auswirkungen auf die Leukotrien-Biosynthese nach LPS Stimulation. Im Gegensatz dazu konnte in unstimulierten Zellen eine signifikante Aktivitätssteigerung in Abwesenheit von miR-125a-5p festgestellt werden. Diese Beobachtungen legen nahe, dass miR-125a-5p einen TNFα unabhängigen Einfluss auf die 5-LO Aktivität besitzt. In LPS stimulierten Zellen kommt es möglicherweise zu Überlagerungen dieses Effektes.
Zusammenfassend konnte in dieser Arbeit gezeigt werden, dass 5-LO eine regulierende Funktion auf die Reifung der beiden miRNAs miR-99b-5p und miR-125a-5p aufweist. Dieser Effekt könnte einer direkten Interaktion zwischen 5-LO und Dicer zuzuschreiben sein. Des Weiteren konnte gezeigt werden, dass die Regulierung der Expression bestimmter miRNAs mittels 5-LO nicht auf deren kanonischer enzymatischer Aktivität beruht. Diese Ergebnisse schlagen eine neue Richtung der 5-LO-Forschung ein und können in Zukunft dazu beitragen 5-LO vermittelte Effekte besser charakterisieren zu können.
Die Arachidonsäurekaskade spielt bei Entzündungsprozessen und der Schmerzentstehung eine wichtige Rolle. Deren primäre Produkte, die Leukotriene und die Prostaglandine, sind entzündungsfördernde Mediatoren und nehmen Einfluss auf den Entzündungs-auflösendenprozess und sind bei einer Dysregulation für diverse Erkrankungen wie z.B. Asthma bronchiale und allergische Rhinitis mitverantwortlich. Die Kaskade gliedert sich mit ihren beiden Hauptenzymen, Cyclooxygenase und 5-Lipoxygenase (5-LO), in zwei Wege auf. Beide Enzyme sind außerdem in der Lage entzündungsauflösenden Mediatoren zu bilden. Die Mediatoren wie z.B. Lipoxin können im Zellstoffwechsel einerseits über die Lipoxygenase-Route, oder andererseits wie „aspirin-triggered“-Lipoxin von der durch geeignete Wirkstoffe acetylierten Cyclooxygenase-2 (COX-2) katalysiert werden. Diese Mediatoren werden benötigt, um (chronische) Entzündungen und beschädigtes Gewebe zurück zur Homöostase zu führen.
Die Pharmakotherapie chronisch entzündlicher Erkrankungen mit guter Wirksamkeit und verträglichem Profil bei Langzeiteinnahme stellt jedoch eine Herausforderung dar. Die Therapie verzögern oft, z. B bei Einnahme von nicht-steroidalen Antirheumatika (NSAR), die Entzündungsauflösung, da die Bildung von entzündungshemmenden und entzündungs-auflösenden Lipidmediatoren gehemmt werden. Die gezielte Modulation und Einflussnahme auf die Arachidonsäurekaskade an einem der beiden Enzyme, stellt daher einen guten Ansatz für eine verbesserte Therapiemöglichkeit von (chronischen) entzündlichen Krankheiten dar. Diese Arbeit beschäftigt sich mit der Synthese von Modulatoren und Inhibitoren der Arachidonsäurekaskade. Zum einen befasst sie sich mit der Entwicklung von irreversiblen COX-2-acetylierenden Substanzen als neues anti-entzündliches und entzündungsauflösendes Prinzip. Zum anderen mit der Untersuchung der Struktur-Wirkungsbeziehung (SAR) von 2-Aminothiazolen als direkte 5-LO-Inhibitoren ausgehend von SKI-II, welches zuvor als Leitstruktur zur Entwicklung von 5-LO-Inhibitoren entdeckt wurde.
Als Leitstrukturen für die irreversiblen COX-2-acetylierenden Substanzen wurden bekannte COX-2 selektive Substanzen ausgewählt sowie vereinzelte nicht-selektive NSAR. Es wurden an der COX-2 Kristallstruktur Docking-Studien durchgeführt, um die geeignetsten Positionen für die Einführung einer (labilen) Acetylgruppe zu identifizieren. Aufgrund dieser Studien wurden drei Positionen ausgewählt zur Derivatisierung. Es wurden daraufhin zahlreiche Derivate synthetisiert von Celecoxib, Valdecoxib, Rofecoxib, Etericoxib, als Vertreter der (COX-2) selektive Inhibitoren, sowie von Acetylsalicylsäure, Diclofenac und Nimesulid-Analoga als Vertreter der nicht-selektiven NSARs. Zusätzlich wurden Derivate synthetisiert mit Michael-Akzeptoren als kovalente bindende Komponente. Alle synthetisierten Substanzen wurden sukzessiv auf ihre COX inhibitorischen Eigenschaften hin untersucht und auf COX-2 Selektivitäten überprüft. Weiterhin wurden von allen Derivaten Auswaschungs-Studien durchgeführt als Vorversuche welche Derivate eine irreversible COX-2-Inhibition hervorrufen. In den Vorversuchen zeigte die Verbindung ST-1650 am deutlichsten eine COX-2-Selektivität sowie eine starke irreversible Inhibition der COX-2. Die Verbindung ST-1650 wurde weiterhin auf indirekte Hinweise zur Entstehung von heilungsfördernden Mediatoren untersucht anhand von: M1-Macrophagen Polarisation und einem Schmerzmodell, dem Zymosan-Überempfindlichkeit Pfotenmodell. Im Makrophagen-Modell konnte ST-1650 keine Phänotypverschiebung hinzu entzündungsauflösenden M2-Makrophagen bewirken, sowie in den Schmerzmodellen leider keine schnellere Schmerzauflösung als die Kontrollgruppe. Ob diese Effekte durch mangelnde oder zu geringer Entstehung von entzündungshemmenden Mediatoren zurückzuführen ist, ist noch unklar.
Für die SAR der 2-Aminothiazole als direkte 5-LO-Inhibitoren wurden über 60 Verbindungen synthetisiert und untersucht. Zu Beginn erfolgte eine Optimierung der Grundstruktur als 5-LO-Inhibitor. Es wurden die Einflüsse der Substituenten des Thiazolsrings und des Aminolinkers auf die 5-LO-Aktivität ermittelt, um die SAR initialer Arbeiten zu vertiefen. Nach der SAR-Untersuchung im intakten Zellsystem konnten durch Kombination bevorzugter Strukturelemente die zwei Verbindungen ST-1853 und ST-1906, als neue potente 5-LO-Inhibitoren entwickelt werden, die sich als nicht-toxisch herausstellten. Diese beiden 5-LO-Inhibitoren wirken um einen Faktor 10 potenter und sind weniger toxisch verglichen mit der Leitstruktur SKI-II. ST-1853 wurde innerhalb der Arachidonsäurekaskade auch auf Off-targets getestet, deren Aktivitäten sie erst bei 100-fach höherer Konzentration beeinflusst, sowie in humanem Vollblut, wo sie sich ihre 10-fach bessere Wirksamkeit im Vergleich zu SKI-II bestätigte. Darüber hinaus erwies sich ST-1853 bei den ersten Überprüfungen seiner Stabilität unter physiologischen Bedingungen wie bei der in vitro Metabolisierung durch Rattenlebermikrosomen als ausreichend stabil und daher zur weiteren Charakterisierung gut geeignet.
Reactivation of autophagy by spermidine ameliorates the myopathic defects of collagen VI-null mice
(2015)
Autophagy is a self-degradative process responsible for the clearance of damaged or unnecessary cellular components. We have previously found that persistence of dysfunctional organelles due to autophagy failure is a key event in the pathogenesis of COL6/collagen VI-related myopathies, and have demonstrated that reactivation of a proper autophagic flux rescues the muscle defects of Col6a1-null (col6a1(-/-)) mice. Here we show that treatment with spermidine, a naturally occurring nontoxic autophagy inducer, is beneficial for col6a1(-/-) mice. Systemic administration of spermidine in col6a1(-/-) mice reactivated autophagy in a dose-dependent manner, leading to a concurrent amelioration of the histological and ultrastructural muscle defects. The beneficial effects of spermidine, together with its being easy to administer and the lack of overt side effects, open the field for the design of novel nutraceutical strategies for the treatment of muscle diseases characterized by autophagy impairment.