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Locomotion, the way animals independently move through space by active muscle contractions, is one of the most apparent animal behaviors. However, in many situations it is more beneficial for animals to actively prevent locomotion, for instance to briefly stop before reorienting with the aim of avoiding predators, or to save energy and recuperate from stress during sleep. The molecular and cellular mechanisms underlying such locomotion inhibition still remain elusive. So, the aim of this study was to utilize the practical genetic model organism Caenorhabditis elegans to efficiently tackle relevant questions on how animals are capable of suppressing locomotion.
Nerve cells, mostly called neurons, are known to control locomotion patterns by activating some and inhibiting other muscle groups in a spatiotemporal manner via local secretion of molecules known as neurotransmitters. This study particularly focuses on whether neuropeptides modulate such neurotransmission to prevent locomotion. Neuropeptides are small protein-like molecules that are secreted by specific neurons and that act in the brain by activating G protein-coupled receptors (GPCRs) expressed in other target neurons. They can act as hormones, neuromodulators or neurotransmitters. DNA sequences coding for neuropeptides and their cognate receptors are similar across diverse species and thus indicate evolutionary conservation of their molecular signaling pathways. This could potentially also imply that regulatory functions of specific neuropeptides are also similar across species and are thus meaningful to unravel more general mechanisms for instance underlying locomotion inhibition.
Specifically, we find that the modulatory interneuron RIS constitutes a dedicated stop neuron of which the activity is sufficient to initiate rapid locomotion arrest in C. elegans while maintaining its body posture. Similar to its known function in larval sleep, RIS requires RFamide neuropeptides encoded by the flp 11 gene for this activity, in addition to GABA. Furthermore, we find that spontaneous calcium activity transients in RIS are compartmentalized and correlated with locomotion stop. These findings illustrate that a single neuron can regulate both stopping and sleeping phenotypes.
Secondly, we show that C. elegans RPamide neuropeptides encoded by nlp-22 and nlp-2 regulate sleep and wakefulness, respectively. We unexpectedly find that these peptides activate gonadotropin-releasing hormone (GnRH)-like receptors dose dependently and we highlight their sequence resemblance to other bilaterian GnRH-like neuropeptides. In addition, we show that these receptors are expressed in distinct subsets of neurons that are associated with motor behavior. Finally, we show that nlp 22 encoded peptides signal through GNNR 6 receptors to regulate larval sleep and that nlp 2 encoded peptides require both GNRR 3 and GNRR 6 receptors to promote wakefulness.
In sum, we find that locomotion inhibition in C. elegans is regulated by multiple, but evolutionary conserved RFamide and GnRH-like RPamide neuropeptidergic signaling pathways.
Prokaryotische Organismen werden in ihrer natürlichen Umgebung mit schwankenden Umwelteinflüssen konfrontiert oder müssen gegebenenfalls extremen Bedingungen standhalten. Um sich an derartige Veränderungen anpassen zu können und damit ein weiteres Überleben zu sichern, ist es wichtig neue genetische Informationen zu akquirieren. Die molekulare Basis dieser Anpassung sind Genmutationen, Genverlust, intramolekulare Rekombination und/oder horizontaler Gentransfer. Der vorliegende Selektionsdruck der Umwelt begünstigt schlussendlich die Spezialisierung und damit die Erschließung neuer Standorte aufgrund des Erwerbs neuer metabolischer Eigenschaften, Resistenzgene oder Pathogenitätsfaktoren. Vergleichende Analysen bakterieller Genome, welche auf Analysen der GC-Gehalte, der Codon- und Aminosäurenutzung und der Genlokalisation beruhen, zeigten, dass bei diesem evolutiven Prozess bzw. der Weiterentwicklung der bakteriellen Genome der horizontale Gentransfer als treibende Kraft eine entscheidende Rolle spielt. So indizieren Genomstudien, dass 0-22% der gesamten bakteriellen und 5-15% der archaeellen Gene horizontal erworben wurden, wobei der DNA-Transfer nicht ausschließlich zwischen Vertretern einer Domäne, sondern ebenfalls zwischen Organismen unterschiedlicher Domänen stattgefunden hat. So sind z.B. 24 bzw. 16% der Gene von Genomen hyperthermophiler Organismen wie Thermotoga maritima oder Aquifex aeolicus archaeellen Ursprungs. Ebenso finden sich Gene für Chaperone und DNA-Reparaturenzyme im Genom des thermophilen Bakteriums Thermus thermophilus wieder, welche wahrscheinlich ebenfalls durch horizontalen Gentransfer aus hyperthermophilen und archaeellen Genomen erworben wurden um eine Anpassung an extreme Standorte zu ermöglichen. Durch vergleichende Genomstudien wurde ebenfalls festgestellt, dass die durch horizontalen Gentransfer erworbenen Gene oftmals zu einer Neuorganisation von Transkriptionseinheiten und zu einer veränderten Genomorganisation führten. Dennoch finden sich immer wieder Beispiele von horizontal erworbenen Operonen in den verschiedenen Organismen. Gut charakterisierte Vertreter horizontal übertragener Operone sind dabei z.B. das archaeelle H+-ATPase-Operon, das Operon der Na+-translozierenden NADH:Ubichitonoxidoreduktase oder das Nitratreduktase-Operon.
Man unterscheidet bei dem horizontalen Gentransfer zwischen drei Mechanismen der DNAAufnahme: Konjugation, Transduktion und Transformation. Die DNA-Übertragung durch Konjugation ist durch einen spezifischen Zell-Zell-Kontakt definiert, der durch einen von der Donorzelle ausgehenden, sogenannten F-Pilus hergestellt wird. Die Donorzelle überträgt schließlich Plasmid-kodierte genetische Informationen und oftmals Eigenschaften für die eigenständige Konjugation auf eine Rezipientenzelle. Die Transduktion hingegen beschreibt die DNA-Übertragung von Bakteriophagen auf eine Wirtszelle, wobei hier eine hohe Wirtsspezifität Voraussetzung ist. Die Übertragung der DNA von einer Bakterienzelle in eine andere erfolgt dabei ohne Kontakt der Zellen. Die natürliche Transformation ist definiert als Transfer von freier DNA und ermöglicht damit im Gegensatz zu den beiden ersten spezifischen Mechanismen der DNA-Übertragung ein größeres Spektrum der Verbreitung genetischer Informationen. Freie DNA, welche entweder durch Zelllyse oder Typ-IVSekretion ausgeschieden wird und aufgrund von Adsorption an mineralische Oberflächen über längere Zeiträume stabil in der Umgebung vorliegen kann, kann unter der Voraussetzung der Existenz eines speziellen Aufnahmesystems von Bakterien aufgenommen werden. Mittlerweile sind über 44 Bakterien aus unterschiedlichen taxonomischen Gruppen beschrieben, die eine natürliche Kompetenz ausbilden können. Die bekanntesten Beispiele für natürlich transformierbare Gram-negative Bakterien sind Heliobacter pylori, Neisseria gonorrhoeae, Pseudomonas stutzeri, Haemophilus influenzae, T. thermophilus und Acinetobacter baylyi. Auch unter den Gram-positiven Bakterien finden sich einige Vertreter, die natürlich kompetent sind, wie Deinococcus radiodurans, Bacillus subtilis und Streptococcus pneumoniae. Ungeachtet der relevanten Rolle der Transformation im horizontalen Gentransfer, ist über die Struktur und Funktion der komplexen DNA-Aufnahmesysteme wenig bekannt.
The ubiquinol:cytochrome c oxidoreductase is a key component of several aerobic respiratory chains in different organisms. It is an integral membrane protein complex, made up of three catalytic subunits (cytochrome b, cytochrome c1 and Rieske iron sulphur protein) and up to eight additional subunits in mitochondria. The complex oxidizes one quinol molecules and reduces two cytochrome c during the Q cycle, originally described by Peter Mitchell. Electrons are split between the low and the high potential chain and protons are released on the positive side of the membrane, increasing the protonmotive force needed by the ATP-synthase for energy transduction. The cytochrome bc1 complex from P. denitrificans is a perfect model for structural and functional studies. Bacteria are easy to grow and the genetic material is readily accessible for genetic manipulation. Moreover, the P. denitrificans aerobic respiratory chain is very close to the mitochondrial one: the complexes involved in electron transfer resemble the ones found in mitochondria, but lack most of the additional subunits. As a unique feature, P. denitrificans has a strongly acidic domain at the N-terminal region of the cytochrome c1, a sequence of 150 aminoacids which does not correlate with any known protein. An analogous composition can be found in the eukaryotic cytochrome bc1 complex as a part of an accessory subunit, proposed to be involved in facilitating electron transfer between the complex and the electron acceptor cytochrome c. In order to study the function of this domain in the P. denitrificans cytochrome bc1 complex, a deletion mutant has been previously cloned and modified with an affinity tag as a C-terminal extension of cytochrome b. The complex is purified by affinity chromatography and characterized by steady-state kinetics using not only horse heart cytochrome c but also the endogenous electron acceptor, the membrane bound cytochrome c552, employed here as a soluble fragment. Steady–state kinetics indicate that the deletion of the long acidic domain had effects neither on the turnover rate nor on the apparent affinity for the substrate. To understand wether the deletion affects the reaction between the cytochrome bc1 complex and the substrate, laser flash photolysis experiments are performed, showing that the interaction observed was not changed in the complex missing the acidic domain. The results presented in this work confirm the ones previously obtained by Julia Janzon using soluble fragments of the same interaction partners. The deletion, however, affected the oligomerization state of the complex, as shown by LILBID (Laser Induced Liquid Bead Ion Desorption) analysis. The wild type complex has a tetrameric structure, better described as a “dimer of dimers”. The deletion of the acidic domain on the cytochrome c1 results in the separation of the two dimers, yielding the canonical dimer. Therefore, the complex deleted in the acidic domain is used for cloning and expression of a heterodimeric complex, containing an inactivating mutation in the quinol oxidation site in only one monomer, thus allowing a selective switch-off for half the complex. Such a complex is needed for the verification of an internal regulation mechanism, the half-of-the-sites reactivity. According to it, the dimeric structure of the cytochrome bc1 complex has functional implications, since the two monomers can communicate and work in a coordinated manner. This approach confirms that substrate oxidation does effectively take place only in one of the two monomers constituting the dimer, and that the binding of substrate at the Qo and Qi site regulates the switch between active and inactive monomer. Moreover, this mechanism works also as an effective protection against the reaction of quinone intermediates with oxygen and the formation of reactive oxygen species (ROS), responsable for cellular aging. The motion of the ISP head domain is also addressed in this work; in particular the mechanism which regulates the movements towards the cytochrome c1 and the electron bifurcation at the quinol oxidation site. Laser flash kinetics in presence of several inhibitors and the substrate allow studying the response of the ISP to the binding of different species at the quinol oxidation site. The binding of ligand at the Qo site in the complex triggers the conformational switch in the ISP head domain, supporting the mechanism proposed in the literature according to which the Qo site is able to “sense” the presence of substrate and transfer the information to the ISP, regulating its mobility. The internal electron pathway between the ISP and the cytochrome c1 has been analyzed also by stopped-flow kinetics, in presence and absence of inhibitors. The results indicate that two kinetic phases describe the reduction of cytochrome c1 by the ISP, and a model for the simulation of the data is proposed.
Infections with multidrug resistant bacterial strains like Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa or Acinetobacter baumanii that can accumulate resistance mechanisms against different groups of drugs cause increasing problems for the health care system. Multidrug efflux pumps are able to transport different classes of substances, providing a basic resistance to different antibiotics. Especially when they are overexpressed they can keep bacterial cells alive under antibiotic pressure unless other high level resistance mechanisms like expression of β-lactamases are established. One example for a clinically relevant multidrug efflux pump is the AcrAB/TolC tripartite system of E. coli, that transports a variety of different substrates, including besides antibiotics dyes, detergents, bile salts and organic compounds from the periplasm or the inner membrane out of the cell. AcrB is the inner membrane component of the protein complex that determines not only the substrate specificity of the tripartite system but energises the transport through the whole system process via proton transduction as well. TolC is the outer membrane spanning protein that forms a pore in the outer membrane enabling the system to transport drugs over the latter out of the cell. The periplasmic membrane fusion protein AcrA connects AcrB and TolC in the periplasm completing the channel from the periplasm, respective the inner membrane to the extracellular space. AcrB assembles as trimers, in asymmetric crystal structures each of the protomers adapts a different conformation designated L(oose), T(ight) and O(pen). In the protomers tunnels open up and collaps in different conformations. In the L protomer a periplasmic cleft opens up that can initially bind substrates to the periplasmic part of AcrB. In the T conformation the deep binding pocket opens that is assumed to bind substrates tightly that were bound to the access pocket before. As well in the T conformation a second pathway leading to the deep binding pocket opens that can guide substrates from a groove between transmembrane helices TM7, TM8 and TM9, the TM8 groove, that is connected with socalled tunnel 1 that ends in the deep binding pocket. In the O conformation a new tunnel opens that connects the collapsing deep binding pocket with the periplasmic space, respective the channel through the periplasmic space formed from AcrA and TolC. Substrates were cocrystallised in access and deep binding pocket verifying their role in substrate transport. In the TM8 groove in high resolution crystal structures DDM molecules were cocrystallised in L and T conformation, indicating that the AcrB substrate DDM may utilise this entrance to the deep binding pocket. The asymmetry observed in the AcrB trimers trongly suggests a peristaltic pump mechanism. The functional rotation cycle demands communication between the subunits and tight control of substrate load of protomers during the transport to optimise the ration between protons that are transduced and substrates transported. Indeed it was shown that AcrB transport mechanism is positively cooperative for some β-lactam substrates. For the communication between the subunits it was assumed that ionic interaction between ion pairs established between charged amino acids at the interfaces of protomers in different conformations are of special importance. Thus the amino acids engaged in ionic interactions, respective ion pairs D73-K131, E130-K110, D174-K110, R168, R259-E734 were substituted with non-charged amino acids pairwise and phenotypes were determined in plate dilution assays and MIC experiments. No evidence for a general, substrate independent, reduction of AcrB activity, that would be expected when the ionic residues are of special importance for AcrB function, could be found with the methods applied. Substitutions were not only combined pairwise according to the putative ion pairs but as well in combinations of R168A with D174N, E130Q and K131M. AcrB activity is reduced for the variant R168A_D174N significantly, activity decreases further for quadruple variant E130Q_K131M_ R168A_D174N. Because the reduced activity is only observed in this combination of substitutions the phenotype must result from accumulation of small effects of the single substitutions. R168A may destabilise the protomer interfaces, as its side chain is oriented in direction to the neighbouring protomer at all interfaces, enhancing substratespecific effects of substitutions E130Q, K131M, D174N that are not in all conformations oriented towards the neighbouring protomer but as well along the substrate transport pathway. Further investigations to figure out the details of the effects observed were not conducted because fluctuating expression of the variants hindered experimental procedures.
In another approach TM8 was in focus of the interest. As mentioned above it is a possible substrate entrance in the inner membrane. The linker between TM8 and the periplasmic PC2 subdomain undergoes a coil-to-helix transition when AcrB cycles through L, T and O conformations. Linking the transmembrane part of AcrB that provides the energy for the transport process via proton transduction with the periplasmic part harbouring the major part of the substrate pathway assignes TM8 and the periplasmic linker (859-876) an important role in the function of AcrB. Thus it was investigated with an alanine-scan of residues 859 to 884 and G/P respective P/G exchange followed by phenotype characterisation in growth curve and plate dilution assays of selected variants. In the phenotype determinations none of the variants, except G861P that seems to cause massive sterical restriction in an α-helical region, displayed a general, substrate independent decrease of AcrB activity. Thus it is concluded that the individual properties of amino acids in TM8 and the periplasmic linker are not of general importance for the mechanism of AcrB. The substitution of individual amino acids had impact on uptake of different substrates in plate dilution assays in a substrate dependent manner. The uptake of some substrates, like erythromycin or chloramphenicol is more affected than that of others with rhodamine 6G resistance being only reduced for the G861P variant. A relation between the PSA of substrates and reduced activity of AcrB was observed. in Substrates with higher PSA values are more affected by substitutions in TM8 or periplasmic linker, resulting in the conclusion that substrates with higher PSA are more likely to be taken up via the TM8 groove/tunnel 1 pathway than those with lower PSA values.
Resistant microbes are a growing concern. It was estimated that about 33,000 of people die because of the infections caused by multidrug resistant bacteria each year in Europe (ECDC, 2018, https://www.ecdc.europa.eu/). Bacteria can acquire resistance against toxic compounds via different mechanisms and intrinsic active efflux is one of the first mechanisms deployed by bacterial cells. The membrane-localized efflux pumps catalysing this reaction, extract toxic compounds from the interior of the cell and transport these to the outside, thereby maintaining sub-lethal toxin levels in the cytoplasm, periplasm and membranes. Gram-negative three-component efflux pumps, analysed in this study, are composed of an inner membrane protein, a member of the Resistance-Nodulation cell Division (RND) superfamily, an Outer Membrane Factor (OMF) protein and a Membrane Fusion Protein (MFP) that connects the two afore mentioned components into an active efflux pump. The pumps described in this work, AcrAB-TolC and EmrAB-TolC, are drug efflux pumps belonging to the RND and MFS superfamilies, respectively, while CusCBA is an efflux pump that belongs to the RND heavy metal efflux family. Another efflux pump that was used as a model for the design of an in vitro assay for the silver ion transport studies, CopA, belongs to the P-type ATPase superfamily. All pumps analysed in this study are part of the resistance system of Escherichia coli, which is a highly clinically relevant pathogen.
In order to examine the AcrAB-TolC, CopA and CusA efflux pumps, the individual components were separately produced in E. coli, purified to monodispersity and reconstituted in large unilamellar vesicles, LUVs. Means for the optimized production and adequate conditions for efficient reconstitution were presented in this study. The activity of AcrB in LUVs was detected using fluorescence quenching of the dye 8-hydroxy-1,3,6 pyrenetrisulfonate (pyranine), which is incorporated inside the proteoliposomes and is sensitive to the pH changes in its surrounding. The inactive AcrB variant with a substitution in the proton relay network, D407N, showed no activity in proteoliposomes, which correlates with the measurements done in empty liposomes. When AcrA was co-reconstituted with AcrB D407N proteoliposomes it did not restore protein activity. To test the assembly of the AcrAB-TolC pump out of its single components, an in vitro assay was established where the complex assembly was tested with AcrAB- and TolC-containing liposomes. These experiments showed putative AcrAB-TolC formation in the presence or absence of a pump substrate, taurocholate, as well as in the presence of the pump inhibitor, MBX3132. The assembly appeared stable over time and results were invariant in the presence or absence of a pH gradient across the AcrAB-containing membrane.
After determination of the ATPase activity of the P-type ATPase, CopA, in detergent micelles, the protein was reconstituted in LUVs. Quenching of the Ag+-sensitive dye Phen Green SK (PGSK), present on the inside of the CopA-containing proteoliposomes, was observed in presence of ATP and Ag+. Under the same conditions, but in absence of Ag+-ions, quenching was reduced by 80 % after 300 seconds. No PGSK-quenching was observed in control liposomes in the presence of ATP and Ag+. The additional presence of sodium azide led to minimal reduction of the PGSK-quenching as expected since sodium azide is not an inhibitor of P-type ATPases, but the quenching rate was similar to that of the same experimental condition with control liposomes.
The RND superfamily member CusA, as part of the tripartite CusCBA efflux pump, has been proposed to sequester Ag+ or Cu+ from either the cytoplasmic or periplasmic side of the inner membrane. The periplasmic transport of silver ions was implied from an in vitro assay where the quenching of a pH sensitive dye, 9-amino-6-chloro-2-methoxyacridine (ACMA), indicates acidification of the lumen of the proteoliposomes containing CusA when an inwardly directed pH was imposed. The same experiment with the CusA D405N variant, which was previously reported to be an inactive variant, also led to ACMA quenching, although at a slightly lower rate. Under application of an inwardly directed pH and a (negative inside), CusA-containing proteoliposomes showed a strong quenching of the incorporated PGSK dye, suggesting strong Ag+ influx.
The Major Facilitator Superfamily-(MFS-) type EmrAB-TolC pump has an analogous structural setup as the RND-type AcrAB-TolC pump. To examine the efflux of one of its substrates, carbonyl - cyanide m-chlorophenylhydrazone (CCCP), a plate-based susceptibility assay was used. The presence of the EmrAB-TolC pump confers lower susceptibility levels towards CCCP in E. coli, compared to cells not expressing the pump or cells expressing only the MFS component, indicating that EmrAB-TolC extrudes CCCP.
The work done in this study opens up a path towards investigation of drug and metal resistance in vitro. The methodologies to obtain proteoliposomal samples of multicomponent efflux pumps and subsequent measurements of drug/metal ion and H+ fluxes, as well as the determination of pump assembly are crucial for the future research on pump catalysis and transport kinetics. The in vivo drug-plate assays done in this work provide initial insights for future investigations of the drug susceptibility of E. coli expressing the MFS-type tripartite efflux pumps.
Während meiner Promotion habe ich zwei Projekte unter der Aufsicht von Dr. Misha Kudryashev durchgeführt. Im ersten Projekt habe ich die Strukturen des Ryanodinrezeptors 1 (RyR1) in Apo- und Ryanodin-Bindungszuständen in der nativen Membran durch Tomographie und Subtomogramm-Mittelung bei 12,6 bzw. 17,5 Å bestimmt. Im Vergleich zur Struktur von gereinigtem RyR1 unter Verwendung der Einzelpartikel-Kryo-Elektronenmikroskopie (Cryo-EM) können zusätzliche Dichten in der cytoplasmatischen Domäne und der sarkoplasmatischen Retikulum (SR)-Membran bzw. im SR-Lumen beobachtet werden. Die Auflösung der Struktur von RyR1 im Apo-Zustand wurde von den Kollegen in meinem Labor mithilfe der Hybridmethode auf 9,5 Å verbessert. Diese Arbeit hat unser Verständnis für die Mechanismen von RyR1 in nativen Membranen erweitert. Im zweiten Projekt habe ich die Struktur des Proteins SdeC der SidE-Familie durch Einzelpartikel-Kryo-EM bei 4,6 Å bestimmt. Die Kristallstruktur des C-Terminus von SdeA wurde von meinem Forschungspartner Dr. Mohit Misra gelöst. Durch Überlagerung einer gemeinsamen Helix dieser beiden Strukturen konnten wir ein kombiniertes Modell erstellen und ein allgemeines Verständnis der Proteine der SidE-Familie erhalten.