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Autophagy, together with the ubiquitin-proteasome system, is the main quality control pathway responsible for maintaining cell homeostasis. There are several types of autophagy distinguished by cargo selectivity and means of induction. This thesis focuses on macroautophagy, hereafter autophagy, where a double-layered membrane is formed originating from the endoplasmatic reticulum (ER) engulfing cargo selectively or unselectively. Subsequently, a vesicle forms around the cargo, an autophagosome, and eventually fuses with the lysosome leading to degradation of the vesicle content and release of the cargo “building blocks”. Basal autophagy continuously occurs, unselectively engulfing a portion of the cytoplasm. However, autophagy can also be induced by stress such as starvation, protein aggregation, damaged organelles, intracellular pathogens etc. In this case, the cargo is selectively targeted, and the fate of the autophagosome is the same as in basal autophagy. In recent years, interest in identifying mechanisms of autophagy regulation has risen due to its importance in neurodegenerative diseases and cancer. Given the complexity of the process, its execution is tightly regulated from initiation, autophagosome formation, expansion, closure, and finally fusion with the lysosome. Each of the steps involves different protein complexes, whose timely activity is orchestrated by post-translational modifications. One of them is ubiquitination. Ubiquitin is a small, 76-amino acid protein conjugated in a 3-step reaction to other proteins, in a reversible manner, meaning undone by deubiquitinases. Originally described as a degradation signal targeting proteins to the proteasome, today it is known it has various additional non-proteolytic functions, such as regulating a protein’s activity, localization, or interaction partners. The role of ubiquitin in autophagy has already been shown. However, given the reversibility and fine-tuning of the ubiquitin signal, many expected regulators remain unidentified. This work aimed to identify novel deubiquitinating enzymes that regulate autophagy. We identified ubiquitin-specific protease 11 (USP11) as a novel, negative regulator of autophagy. Loss of USP11 leads to an increase in autophagic flux, whereas overexpression of USP11 attenuates it. Moreover, this observation was reproducible in model organism Caenorhabditis elegans, emphasizing the importance of USP11 in autophagy regulation. To identify the mechanism of USP11-dependent autophagy regulation, we performed a USP11 interactome screen after 4 hour Torin1 treatment and identified a plethora of autophagy-related proteins. Following the most prominent hits, we have investigated versatile ways in which USP11 regulates autophagy. USP11 interacts with the PI3KC3 complex, the role of which is phosphorylating lipids of the ER, thereby initiating the formation of the autophagosomal membrane. Phosphorylated lipids serve as a recruitment signal for downstream effector proteins necessary for the membrane expansion. The core components of the complex are VPS34, the lipid kinase, ATG14, the protein responsible for targeting the complex to the ER, VPS15, a pseudokinase with a scaffolding role, Beclin1, a regulatory subunit, and NRBF2, the dimer-inducing subunit. We have found USP11 interacts with the complex and, based on its activity, USP11 influences post-translational status of all the aforementioned subunits, except for ATG14. Moreover, we have found that loss of USP11 leads to an increase in NRBF2 levels, whereas it does not change the levels of the other proteins. Given that the dimerization of the complex leads to an increase in complex activity, we investigated if the complex is more tightly formed in the absence of USP11, and if it is more active. We have found both to be the case. Although the exact mechanism of USP11-dependent PI3KC3 complex regulation remains to be identified, we found that loss of USP11 stimulates the complex formation and activity, likely contributing to the general effect of USP11 on autophagy flux. Additionally, we found that USP11 modulates levels of mTOR, the most upstream kinase in autophagy initiation steps and general multifaceted metabolism regulator. Loss of USP11 led to downregulation of mTOR levels, suggesting USP11 may rescue mTOR from proteasome-mediated degradation. Furthermore, we found mTOR to be differentially modified depending on the activity of USP11. However, it remains to be shown if USP11-dependent mTOR regulation contributes to the observed autophagy phenotype. Taken together, USP11 is a novel, versatile, negative regulator of autophagy, and an important addition to our knowledge on the regulation of autophagy by the ubiquitin system.
Light‐induced activation of biomolecules by uncaging of photolabile protection groups has found many applications for triggering biochemical reactions with minimal perturbations directly within cells. Such an approach might also offer unique advantages for solid‐state NMR experiments on membrane proteins for initiating reactions within or at the membrane directly within the closed MAS rotor. Herein, we demonstrate that the integral membrane protein E. coli diacylglycerol kinase (DgkA), which catalyzes the phosphorylation of diacylglycerol, can be controlled by light under MAS‐NMR conditions. Uncaging of NPE‐ATP or of lipid substrate NPE‐DOG by in situ illumination triggers its enzymatic activity, which can be monitored by real‐time 31P‐MAS NMR. This proof‐of‐concept illustrates that combining MAS‐NMR with uncaging strategies and illumination methods offers new possibilities for controlling biochemical reactions at or within lipid bilayers.
Members of the ATP‐binding cassette (ABC) transporter superfamily translocate a broad spectrum of chemically diverse substrates. While their eponymous ATP‐binding cassette in the nucleotide‐binding domains (NBDs) is highly conserved, their transmembrane domains (TMDs) forming the translocation pathway exhibit distinct folds and topologies, suggesting that during evolution the ancient motor domains were combined with different transmembrane mechanical systems to orchestrate a variety of cellular processes. In recent years, it has become increasingly evident that the distinct TMD folds are best suited to categorize the multitude of ABC transporters. We therefore propose a new ABC transporter classification that is based on structural homology in the TMDs:
Recently, photochromic derivatives of nucleobases have drawn attention for regulating oligonucleotide hybridization with light for photopharmacological applications. The nucleobase moiety provides attractive interaction for hybridization, whereas the photochromic moiety can alter the interaction upon irradiation due to conformational changes. Herein we report the synthesis of 2‐phenyldiazenyl‐substituted 2’‐deoxyadenosine (dAAzo) and 2’‐deoxyguanosine (dGAzo) and investigate their influence in a DNA context by UV/Vis absorption, fluorescence and CD spectroscopies. For comparison, the literature‐known azobenzene C‐nucleoside DNAzo was used as a reference system. It could be shown that photochromic purines improve overall hybridization affinity compared to azobenzene C‐nucleosides. In particular, 2’‐deoxyadenosine analogue dAAzo increases melting temperatures by 7.5 °C in the favored trans state with 86 % of the switching efficiency of the reference system.
Fokus meiner Doktorarbeit ist die Anwendung und Entwicklung NMR-spektroskopischer Methoden zur Charakterisierung zeitabhängiger Strukturänderungen von Biomolekülen – von lokalen dynamischen Veränderungen bis zur vollständigen Rückfaltung von Proteinen – und fasst die Ergebnisse meiner drei wichtigsten PhD-Projekte zusammen.
In meinem ersten Projekt habe ich die Leistung eines Temperatursprung-Probenkopfs – mit dem Proben mit hoher Salzkonzentration schnell erwärmt werden können – mithilfe einer Hochfrequenzspule technisch optimiert. Die optimierten Radiofrequenz-Bestrahlungsparameter, Lösungsmittel-bedingungen und der reduzierte Arbeitszyklus führten zu einem Temperatursprung von 20 °C in 400 ms. Ich habe eine Cystein-freie Mutante von Barstar hergestellt, die nach Zugabe von Harnstoff bei 0 °C kalt denaturiert werden kann, während sie ihren gefalteten Zustand bei 30 °C hält. Dadurch wurde auch ermöglicht, dass der Rückfaltungsprozess hunderte Male ohne Abbau oder Aggregation wiederholt werden kann. Die Kombination von reversibler Rückfaltung und rascher Temperaturänderung des kalt denaturierten Barstars ermöglichte die Entwicklung eines neuen kinetischen Experiments, bei dem der Rückfaltungsprozess von Barstar mit einem zweidimensionalen Echtzeit-NMR in hoher Zeitauflösung untersucht wird. Die vollständige Rückgratresonanzzuweisung wurde sowohl für den gefalteten als auch für den kalt denaturierten Zustand von Barstar durchgeführt und ergab, dass in der denaturierten Form beide Prolin-Reste einen gemischten Konformationszustand aufweisen. Dabei befindet sich die Tyr47-Pro48-Amidbindung im ungefalteten Zustand hauptsächlich in trans-, während im gefalteten Zustand in der seltenen cis-Konformation. Das neue hochauflösende kinetische Experiment zeigte, dass die Rückfaltung von Barstar durch die trans-cis-Isomerisierung der Tyr47-Pro48-Amidbindung verlangsamt wird, was sowohl die Sekundärstruktur als auch die Bildung der Tertiärstruktur beeinflusst. Basierend auf diesen Ergebnissen konnte ich einen plausiblen Faltungsmechanismus für den langsamen Faltungsweg von kalt denaturiertem Barstar skizzieren. Durch Änderung der Zeitparameter des Heizungszyklus wurde erreicht, dass die Tyr47-Pro48-Amidbindung im ungefalteten Zustand in der cis-Konformation bleibt und daher der schnelle Faltungsweg dominant wird. Das Starten des Magnetisierungstransfers vor der Temperaturänderung ermöglichte die Aufzeichnung eines Spektrums, das den entfalteten Zustand mit dem gefalteten Zustand korreliert. Dieses Spektrum ermöglichte quantitative Analysen des schnellen Faltungsweges und lieferte sogar indirekte Hinweise auf einen Zwischenzustand. Diese Methode aus Kombination von schnellem Temperatursprung und Kaltdenaturierung zeigt ein hohes Potenzial, Proteinfaltung auf atomarer Ebene experimentell zu untersuchen und ein tieferes Verständnis verschiedener Faltungswege zu erlangen.
In meinem zweiten Projekt – das Teil einer interdisziplinären Forschung war – konzentrierte ich mich auf die NMR-spektroskopische Charakterisierung von Nukleinsäuren, die mit einer photolabilen Schutzgruppe modifiziert wurden. Zuerst wurde mithilfe homonuklearer Korrelationsexperimente eine vollständige Protonresonanzzuweisung erreicht. Danach wurde die relative Konfiguration der photolabilen Schutzgruppen bestimmt basierend auf einer dreidimensionalen Modellstruktur und spezifischer NOE-Korrelationen. Des Weiteren wurde ein Strukturmodell unter Verwendung von NOE-Einschränkungen berechnet. Dieses Strukturmodell zeigte eine eingeschränkte Rotation um die CN-Bindung zwischen dem Käfig und der Nukleobase. Das Modell zeigte auch, dass der Käfig in der Hauptrille positioniert ist und nicht in das Lösungsmittel herausklappt. Im Vergleich zu einem zuvor charakterisierten NPE-Käfig führte die erhöhte Größe zu einer weiteren Senkung des Schmelzpunkts, zeigte jedoch einen geringeren Schmelzpunktunterschied zwischen der S- und der R-Konfiguration des Käfigs, wobei die S-Konfiguration zu einer größeren Reduktion des Schmelzpunktes führt. Dieser Trend wurde weiter untersucht und durch ein Screening unterstützt. Durch selektive Wasserinversions-Rückgewinnungsexperimente konnte ich auch zeigen, dass der Käfig die lokale Stabilität nur bis zu einer Entfernung von zwei benachbarten Basenpaaren von der Modifikationsstelle verringert. Die NOE-Daten dienten auch als guter Bezugspunkt, um die Qualität molekulardynamischer Simulationen zu testen, mit denen zusätzliche Käfigdesigns untersucht wurden. Die Kombination aus Synthese, NMR-Spektroskopie und MD-Simulationen ermöglichte bis jetzt die detaillierteste Untersuchung des Effekts vom Einbau eines einzelnen Käfigs zur Destabilisierung der DNA-Sekundärstruktur. Dabei wurden Einschränkungen des möglichen Designs aufgedeckt, aber auch die Entwicklung einer neuen, effizienteren Struktur ermöglicht.
Mein drittes Projekt konzentrierte sich auf die Charakterisierung eines RNA-Modellsystems. NMR-spektroskopische Daten von kleinen RNA-Modellsystemen – wie NOE, skalare Kopplungen, kreuzkorrelierte Relaxationsraten und RDC – sind eine unschätzbare Referenz für MD-Simulationen, obwohl die Menge der verfügbaren Literaturdaten – bis jetzt – sehr begrenzt ist. ...
Tyrosine kinase inhibitors (TKIs) are currently the standard chemotherapeutic agents for the treatment of chronic myeloid leukemia (CML). However, due to TKI resistance acquisition in CML patients, identification of new vulnerabilities is urgently required for a sustained response to therapy. In this study, we have investigated metabolic reprogramming induced by TKIs independent of BCR-ABL1 alterations. Proteomics and metabolomics profiling of imatinib-resistant CML cells (ImaR) was performed. KU812 ImaR cells enhanced pentose phosphate pathway, glycogen synthesis, serine-glycine-one-carbon metabolism, proline synthesis and mitochondrial respiration compared with their respective syngeneic parental counterparts. Moreover, the fact that only 36% of the main carbon sources were utilized for mitochondrial respiration pointed to glycerol-phosphate shuttle as mainly contributors to mitochondrial respiration. In conclusion, CML cells that acquire TKIs resistance present a severe metabolic reprogramming associated with an increase in metabolic plasticity needed to overcome TKI-induced cell death. Moreover, this study unveils that KU812 Parental and ImaR cells viability can be targeted with metabolic inhibitors paving the way to propose novel and promising therapeutic opportunities to overcome TKI resistance in CML.
Deubiquitinases (DUBs) are vital for the regulation of ubiquitin signals, and both catalytic activity of and target recruitment by DUBs need to be tightly controlled. Here, we identify asparagine hydroxylation as a novel posttranslational modification involved in the regulation of Cezanne (also known as OTU domain–containing protein 7B (OTUD7B)), a DUB that controls key cellular functions and signaling pathways. We demonstrate that Cezanne is a substrate for factor inhibiting HIF1 (FIH1)- and oxygen-dependent asparagine hydroxylation. We found that FIH1 modifies Asn35 within the uncharacterized N-terminal ubiquitin-associated (UBA)-like domain of Cezanne (UBACez), which lacks conserved UBA domain properties. We show that UBACez binds Lys11-, Lys48-, Lys63-, and Met1-linked ubiquitin chains in vitro, establishing UBACez as a functional ubiquitin-binding domain. Our findings also reveal that the interaction of UBACez with ubiquitin is mediated via a noncanonical surface and that hydroxylation of Asn35 inhibits ubiquitin binding. Recently, it has been suggested that Cezanne recruitment to specific target proteins depends on UBACez. Our results indicate that UBACez can indeed fulfill this role as regulatory domain by binding various ubiquitin chain types. They also uncover that this interaction with ubiquitin, and thus with modified substrates, can be modulated by oxygen-dependent asparagine hydroxylation, suggesting that Cezanne is regulated by oxygen levels.
The miRNA biogenesis is tightly regulated to avoid dysfunction and consequent disease development. Here, we describe modulation of miRNA processing as a novel noncanonical function of the 5-lipoxygenase (5-LO) enzyme in monocytic cells. In differentiated Mono Mac 6 (MM6) cells, we found an in situ interaction of 5-LO with Dicer, a key enzyme in miRNA biogenesis. RNA sequencing of small noncoding RNAs revealed a functional impact, knockout of 5-LO altered the expression profile of several miRNAs. Effects of 5-LO could be observed at two levels. qPCR analyses thus indicated that (a) 5-LO promotes the transcription of the evolutionarily conserved miR-99b/let-7e/miR-125a cluster and (b) the 5-LO-Dicer interaction downregulates the processing of pre-let-7e, resulting in an increase in miR-125a and miR-99b levels by 5-LO without concomitant changes in let-7e levels in differentiated MM6 cells. Our observations suggest that 5-LO regulates the miRNA profile by modulating the Dicer-mediated processing of distinct pre-miRNAs. 5-LO inhibits the formation of let-7e which is a well-known inducer of cell differentiation, but promotes the generation of miR-99b and miR-125a known to induce cell proliferation and the maintenance of leukemic stem cell functions.
The transcription factor ∆Np63 is a master regulator of epithelial cell identity and essential for the survival of squamous cell carcinoma (SCC) of lung, head and neck, oesophagus, cervix and skin. Here, we report that the deubiquitylase USP28 stabilizes ∆Np63 and maintains elevated ∆NP63 levels in SCC by counteracting its proteasome‐mediated degradation. Impaired USP28 activity, either genetically or pharmacologically, abrogates the transcriptional identity and suppresses growth and survival of human SCC cells. CRISPR/Cas9‐engineered in vivo mouse models establish that endogenous USP28 is strictly required for both induction and maintenance of lung SCC. Our data strongly suggest that targeting ∆Np63 abundance via inhibition of USP28 is a promising strategy for the treatment of SCC tumours.
Some anaerobic bacteria use biotin-dependent Na+-translocating decarboxylases (Bdc) of β-keto acids or their thioester analogs as key enzymes in their energy metabolism. Glutaconyl-CoA decarboxylase (Gcd), a member of this protein family, drives the endergonic translocation of Na+ across the membrane with the exergonic decarboxylation of glutaconyl-CoA (ΔG0’ ≈−30 kJ/mol) to crotonyl-CoA. Here, we report on the molecular characterization of Gcd from Clostridium symbiosum based on native PAGE, size exclusion chromatography (SEC) and laser-induced liquid bead ion desorption mass spectrometry (LILBID-MS). The obtained molecular mass of ca. 400 kDa fits to the DNA sequence-derived mass of 379 kDa with a subunit composition of 4 GcdA (65 kDa), 2 GcdB (35 kDa), GcdC1 (15 kDa), GcdC2 (14 kDa), and 2 GcdD (10 kDa). Low-resolution structural information was achieved from preliminary electron microscopic (EM) measurements, which resulted in a 3D reconstruction model based on negative-stained particles. The Gcd structure is built up of a membrane-spanning base primarily composed of the GcdB dimer and a solvent-exposed head with the GcdA tetramer as major component. Both globular parts are bridged by a linker presumably built up of segments of GcdC1, GcdC2 and the 2 GcdDs. The structure of the highly mobile Gcd complex represents a template for the global architecture of the Bdc family.
Metabolic differences between symbiont subpopulations in the deep-sea tubeworm Riftia pachyptila
(2020)
The hydrothermal vent tube worm Riftia pachyptila lives in intimate symbiosis with intracellular sulfur-oxidizing gammaproteobacteria. Although the symbiont population consists of a single 16S rRNA phylotype, bacteria in the same host animal exhibit a remarkable degree of metabolic diversity: They simultaneously utilize two carbon fixation pathways and various energy sources and electron acceptors. Whether these multiple metabolic routes are employed in the same symbiont cells, or rather in distinct symbiont subpopulations, was unclear. As Riftia symbionts vary considerably in cell size and shape, we enriched individual symbiont cell sizes by density gradient centrifugation in order to test whether symbiont cells of different sizes show different metabolic profiles. Metaproteomic analysis and statistical evaluation using clustering and random forests, supported by microscopy and flow cytometry, strongly suggest that Riftia symbiont cells of different sizes represent metabolically dissimilar stages of a physiological differentiation process: Small symbionts actively divide and may establish cellular symbiont-host interaction, as indicated by highest abundance of the cell division key protein FtsZ and highly abundant chaperones and porins in this initial phase. Large symbionts, on the other hand, apparently do not divide, but still replicate DNA, leading to DNA endoreduplication. Highest abundance of enzymes for CO2 fixation, carbon storage and biosynthesis in large symbionts indicates that in this late differentiation stage the symbiont’s metabolism is efficiently geared towards the production of organic material. We propose that this division of labor between smaller and larger symbionts benefits the productivity of the symbiosis as a whole.
CO2 has been electrochemically reduced to the intermediate formate, which was subsequently used as sole substrate for the production of the polymer polyhydroxybutyrate (PHB) by the microorganism Cupriavidus necator. Faradaic efficiencies (FE) up to 54 % have been reached with Sn‐based gas‐diffusion electrodes in physiological electrolyte. The formate containing electrolyte can be used directly as drop‐in solution in the following biological polymer production by resting cells. 56 mg PHB L−1 and a ratio of 34 % PHB per cell dry weight were achieved. The calculated overall FE for the process was as high as 4 %. The direct use of the electrolyte as drop‐in media in the bioconversion enables simplified processes with a minimum of intermediate purification effort. Thus, an optimal coupling between electrochemical and biotechnological processes can be realized.
Understanding the nano-architecture of protein machines in diverse subcellular compartments remains a challenge despite rapid progress in super-resolution microscopy. While single-molecule localization microscopy techniques allow the visualization and identification of cellular structures with near-molecular resolution, multiplex-labeling of tens of target proteins within the same sample has not yet been achieved routinely. However, single sample multiplexing is essential to detect patterns that threaten to get lost in multi-sample averaging. Here, we report maS3TORM (multiplexed automated serial staining stochastic optical reconstruction microscopy), a microscopy approach capable of fully automated 3D direct STORM (dSTORM) imaging and solution exchange employing a re-staining protocol to achieve highly multiplexed protein localization within individual biological samples. We demonstrate 3D super-resolution images of 15 targets in single cultured cells and 16 targets in individual neuronal tissue samples with <10 nm localization precision, allowing us to define distinct nano-architectural features of protein distribution within the presynaptic nerve terminal.
Understanding the conformational sampling of translation-arrested ribosome nascent chain complexes is key to understand co-translational folding. Up to now, coupling of cysteine oxidation, disulfide bond formation and structure formation in nascent chains has remained elusive. Here, we investigate the eye-lens protein γB-crystallin in the ribosomal exit tunnel. Using mass spectrometry, theoretical simulations, dynamic nuclear polarization-enhanced solid-state nuclear magnetic resonance and cryo-electron microscopy, we show that thiol groups of cysteine residues undergo S-glutathionylation and S-nitrosylation and form non-native disulfide bonds. Thus, covalent modification chemistry occurs already prior to nascent chain release as the ribosome exit tunnel provides sufficient space even for disulfide bond formation which can guide protein folding.
Characterization of a dual BET/HDAC inhibitor for treatment of pancreatic ductal adenocarcinoma
(2020)
Pancreatic ductal adenocarcinoma (PDAC) is resistant to virtually all chemo‐ and targeted therapeutic approaches. Epigenetic regulators represent a novel class of drug targets. Among them, BET and HDAC proteins are central regulators of chromatin structure and transcription, and preclinical evidence suggests effectiveness of combined BET and HDAC inhibition in PDAC. Here, we describe that TW9, a newly generated adduct of the BET inhibitor (+)‐JQ1 and class I HDAC inhibitor CI994, is a potent dual inhibitor simultaneously targeting BET and HDAC proteins. TW9 has a similar affinity to BRD4 bromodomains as (+)‐JQ1 and shares a conserved binding mode, but is significantly more active in inhibiting HDAC1 compared to the parental HDAC inhibitor CI994. TW9 was more potent in inhibiting tumor cell proliferation compared to (+)‐JQ1, CI994 alone or combined treatment of both inhibitors. Sequential administration of gemcitabine and TW9 showed additional synergistic antitumor effects. Microarray analysis revealed that dysregulation of a FOSL1‐directed transcriptional program contributed to the antitumor effects of TW9. Our results demonstrate the potential of a dual chromatin‐targeting strategy in the treatment of PDAC and provide a rationale for further development of multitarget inhibitors.
11,12-Dihydrodibenzo[c,g]-1,2-diazocines have been established as a viable alternative to azobenzene for photoswitching, in particular, as they show an inverted switching behavior: the ground state is the Z isomer. In this paper, we present an improved method to obtain dibenzodiazocine and its derivatives from the respective 2-nitrotoluenes in two reaction steps, each proceeding in minutes. This fast access to a variety of derivatives permitted the study of substitution effects on the synthesis and on the photochemical properties. With biochemical applications in mind, methanol was chosen as a protic solvent system for the photochemical investigations. In contrast to the azobenzene system, none of the tested substitution patterns resulted in more efficient switching or in significantly prolonged half-lives, showing that the system is dominated by the ring strain.
Acinetobacter baumannii is an important nosocomial pathogen that requires thoughtful consideration in the antibiotic prescription strategy due to its multidrug resistant phenotype. Tetracycline antibiotics have recently been re-administered as part of the combination antimicrobial regimens to treat infections caused by A. baumannii. We show that the TetA(G) efflux pump of A. baumannii AYE confers resistance to a variety of tetracyclines including the clinically important antibiotics doxycycline and minocycline, but not to tigecycline. Expression of tetA(G) gene is regulated by the TetR repressor of A. baumannii AYE (AbTetR). Thermal shift binding experiments revealed that AbTetR preferentially binds tetracyclines which carry a O-5H moiety in ring B, whereas tetracyclines with a 7-dimethylamino moiety in ring D are less well-recognized by AbTetR. Confoundingly, tigecycline binds to AbTetR even though it is not transported by TetA(G) efflux pump. Structural analysis of the minocycline-bound AbTetR-Gln116Ala variant suggested that the non-conserved Arg135 interacts with the ring D of minocycline by cation-π interaction, while the invariant Arg104 engages in H-bonding with the O-11H of minocycline. Interestingly, the Arg135Ala variant exhibited a binding preference for tetracyclines with an unmodified ring D. In contrast, the Arg104Ala variant preferred to bind tetracyclines which carry a O-6H moiety in ring C except for tigecycline. We propose that Arg104 and Arg135, which are embedded at the entrance of the AbTetR binding pocket, play important roles in the recognition of tetracyclines, and act as a barrier to prevent the release of tetracycline from its binding pocket upon AbTetR activation. The binding data and crystal structures obtained in this study might provide further insight for the development of new tetracycline antibiotics to evade the specific efflux resistance mechanism deployed by A. baumannii.
Membrane-suspended nanopores in microchip arrays for stochastic transport recording and sensing
(2021)
The transport of nutrients, xenobiotics, and signaling molecules across biological membranes is essential for life. As gatekeepers of cells, membrane proteins and nanopores are key targets in pharmaceutical research and industry. Multiple techniques help in elucidating, utilizing, or mimicking the function of biological membrane-embedded nanodevices. In particular, the use of DNA origami to construct simple nanopores based on the predictable folding of nucleotides provides a promising direction for innovative sensing and sequencing approaches. Knowledge of translocation characteristics is crucial to link structural design with function. Here, we summarize recent developments and compare features of membrane-embedded nanopores with solid-state analogues. We also describe how their translocation properties are characterized by microchip systems. The recently developed silicon chips, comprising solid-state nanopores of 80 nm connecting femtoliter cavities in combination with vesicle spreading and formation of nanopore-suspended membranes, will pave the way to characterize translocation properties of nanopores and membrane proteins in high-throughput and at single-transporter resolution.
The development of super-resolution microscopy (SRM) has widened our understanding of biomolecular structure and function in biological materials. Imaging multiple targets within a single area would elucidate their spatial localization relative to the cell matrix and neighboring biomolecules, revealing multi-protein macromolecular structures and their functional co-dependencies. SRM methods are, however, limited to the number of suitable fluorophores that can be imaged during a single acquisition as well as the loss of antigens during antibody washing and restaining for organic dye multiplexing. We report the visualization of multiple protein targets within the pre- and postsynapse in 350–400 nm thick neuronal tissue sections using DNA-assisted single-molecule localization microscopy (SMLM). In a single labeling step, antibodies conjugated with short DNA oligonucleotides visualized multiple targets by sequential exchange of fluorophore-labeled complementary oligonucleotides present in the imaging buffer. This approach avoids potential effects on structural integrity when using multiple rounds of immunolabeling and eliminates chromatic aberration, because all targets are imaged using a single excitation laser wavelength. This method proved robust for multi-target imaging in semi-thin tissue sections with a lateral resolution better than 25 nm, paving the way toward structural cell biology with single-molecule SRM.
Endolysosomal effectors and their relevance for antiviral activity against the Hepatitis E virus
(2021)
Mit über 20 Millionen registrierter Fälle pro Jahr, repräsentiert das Hepatitis-E-Virus (HEV) eine Hauptursache einer viralen Hepatitis weltweit und stellt ein erhebliches Risiko insbesondere für Schwangere und Immunsupprimierte dar. Jedoch sind Behandlungsoptionen stark limitiert und mit teils schweren Nebenwirkungen verbunden. Neue Erkenntnisse des Wechselspiels zwischen Wirtszelle und HEV werden deshalb benötigt, um neue antivirale Wirkstoffe zu entwickeln. Der Fokus der Arbeit wurde hierbei auf Effektoren des endosomalen Systems gesetzt, welches von HEV zur Freisetzung von Virionen genutzt wird.
Eine virale Infektion führt in der Zelle zur Produktion von Interferonen (IFNs) und weiters zu einer IFN-Antwort. Ein essenzielles Effektormolekül, welches HEV nachweislich effizient repressiert, ist die GTPase guanylate binding protein 1 (GBP1). In dieser Studie wurde beleuchtet, dass Letztere durch eine HEV-Infektion induziert wird. Zusätzlich reduziert die ektopische Expression von GBP1 sowohl die intrazelluläre Menge des HEV Kapsidproteins als auch die Menge freigesetzter Virionen. Mechanistisch liegt diesem Sachverhalt die GBP1-induzierte Inkorporation von Virionen in Lysosomen zugrunde, was schlussendlich deren Abbau nach sich zieht. Erkenntnisse über die Rolle verschiedener GBP1 Proteindomänen innerhalb des Mechanismus wurden unter Verwendung ektopischer Expression von GBP1-Mutanten erlangt. Inkorporation der Mutation R48A führt zum Verlust der GTPase-Aktivität. Andererseits führt eine Inkorporation der Mutation S73A zum Verlust der Homodimerisierung, was die nachfolgende Farnesylierung und gekoppelte Membranassoziation reduziert. Hierbei behält GBP1-R48A Fähigkeiten zur Induktion lysosomalen Abbaus von HEV bei, GBP1-S73A jedoch nicht. Dies wiederum bedeutet, dass eine GBP1 Homodimerisierung notwendig für den antiviralen Mechanismus ist, was eine Adapterfunktion des Moleküls für lysosomale Inkorporation nahelegt. Die Relevanz von GBP1 während einer IFNγ-Antwort wurde deshalb mittels siRNA-basiertem Silencing untersucht. Ähnlich der ektopischen Expression von GBP1 induziert IFNγ die lysosomale Degradation von HEV. In Abwesenheit von GBP1 jedoch, ist dieser Effekt signifikant geringer ausgeprägt, was zu einem Effizienzverlust von IFNy in Bezug auf dessen antiviralen Effekt bedeutet. Dies führte schlussendlich zur Identifizierung von GBP1 als essenziellen Restriktionsfaktor gegen HEV, was seine Rolle in Abhängigkeit seiner Homodimerisierung via Induktion lysosomalen Abbaus erfüllt.
Nebst der Induktion von GBP1, konnte eine Akkumulation von Cholesterin in Lysosomen durch IFNy nachgewiesen werden. Da dieses Lipid einen essenziellen Faktor für endosomale Reifung, Transport und Funktionalität darstellt, wurden Cholesterinspiegel und verbundene transkriptionelle Fußabdrücke im Kontext einer HEV Infektion untersucht. Letztere führt zu einer Dysregulation Cholesterin-assoziierter Genexpression, was eine Reduktion intrazellulären Cholesterins nach sich zieht. Auch in HEV infizierten Patienten liegt eine Abnahme des Serumcholesterins vor. Unter Modulation intrazellulären Cholesterins, wurde deutlich, dass die Inhibition der Cholesterinsynthese durch Simvastatin eine verstärkte Freisetzung von Virionen nach sich zieht, was ebenso in HEV infizierten Patienten nachweisbar war. Im Gegensatz hierzu zieht eine Erhöhung intrazellulären Cholesterins via Supplementierung von Lipoproteinpartikeln niedriger Dichte (LDL) oder 25-Hydroxycholesterin eine signifikante Reduktion des viralen Kapsidproteins und freigesetzter Virionen nach sich. Dem liegt eine verstärkte Inkorporation von HEV in Lysosomen mit anschließender Degradation zugrunde. Ob dieser Mechanismus pharmakologisch nutzbar ist, wurde mittels eines Screenings Lipid modulatorischer Medikamente untersucht. Der p-Glykoprotein Inhibitor PSC833 und besonders der PPARα-Agonist Fenofibrat stellten sich als äußerst effiziente Inhibitoren des HEV heraus. Beide führen zu einer Erhöhung und Akkumulation zellulären Cholesterins in vesikulären Strukturen. Dies zieht eine dramatische Erhöhung lysosomaler Lokalisation von HEV nach sich und führt letzten Endes zu einer signifikanten Reduktion freigesetzter Virionen.
Zusammenfassend konnten in dieser Studie essenzielle Funktionen von GBP1 in Bezug auf dessen restriktiven Effekt gegen HEV identifiziert werden. Weiters wurde dieses als entscheidender Wirtsfaktor für die IFNγ-Antwort gegen das Virus identifiziert. Andererseits legt diese Studie nahe, dass HEV niedrige Cholesterinspiegel innerhalb infizierter Zellen für die Freisetzung von Virionen benötigt. Andererseits sind erhöhte intrazelluläre Cholesterinspiegel schädlich für die virale Freisetzung, da der lysosomale Abbau von Virionen induziert wird. Dies führte zur erfolgreichen Entdeckung eines neuartigen antiviralen Wirkstoffes, welcher diesen cholesterinabhängigen Effekt effizient induziert: Fenofibrat.