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The formation of amyloid-β oligomers plays a key role in the onset of Alzheimer’s disease. We investigated the aggregation of amyloid-β oligomers by mass spectrometry and ion mobility spectrometry, revealing those structural properties, which lead to the formation of mature fibrils. We can show that the arrangement of the first oligomers is crucial for the topology of the resulting species, leading to the formation of non-toxic aggregates or fibrils.
Herein, we present a multi-cycle chemoenzymatic synthesis of modified RNA with simplified solid-phase handling to overcome size limitations of RNA synthesis. It combines the advantages of classical chemical solid-phase synthesis and enzymatic synthesis using magnetic streptavidin beads and biotinylated RNA. Successful introduction of light-controllable RNA nucleotides into the tRNAMet sequence was confirmed by gel electrophoresis and mass spectrometry. The methods tolerate modifications in the RNA phosphodiester backbone and allow introductions of photocaged and photoswitchable nucleotides as well as photocleavable strand breaks and fluorophores.
The heterotetrameric human transfer RNA (tRNA) splicing endonuclease (TSEN) catalyzes the excision of intronic sequences from precursor tRNAs (pre-tRNAs)1. Mutations in TSEN and its associated RNA kinase CLP1 are linked to the neurodegenerative disease pontocerebellar hypoplasia (PCH)2–8. The three-dimensional (3D) assembly of TSEN/CLP1, the mechanism of substrate recognition, and the molecular details of PCH-associated mutations are not fully understood. Here, we present cryo-electron microscopy structures of human TSEN with intron-containing pre-tRNATyrgta and pre-tRNAArgtct. TSEN exhibits broad structural homology to archaeal endonucleases9 but has evolved additional regulatory elements that are involved in handling and positioning substrate RNA. Essential catalytic residues of subunit TSEN34 are organized for the 3’ splice site which emerges from a bulge-helix configuration. The triple-nucleotide bulge at the intron/3’-exon boundary is stabilized by an arginine tweezer motif of TSEN2 and an interaction with the proximal minor groove of the helix. TSEN34 and TSEN54 define the 3’ splice site by holding the tRNA body in place. TSEN54 adapts a bipartite fold with a flexible central region required for CLP1 binding. PCH-associated mutations are located far from pre-tRNA binding interfaces explaining their negative impact on structural integrity of TSEN without abrogating its catalytic activity in vitro10. Our work defines the molecular framework of pre-tRNA recognition and cleavage by TSEN and provides a structural basis to better understand PCH in the future.
Structure-function relationships in substrate binding protein dependent secondary transporters
(2023)
This work provides new insights into the relevance of SBP dependent secondary transport systems, especially in the thus far under-researched subgroup of TAXI transporters. Importantly, we identified and characterized the TAXI transport system TAXIPm-PQM from Proteus mirabilis. We demonstrated that, in contrast to previously characterized SBP dependent secondary transport systems, TAXIPm-PQM is a proton coupled system and transports the C5-dicarboxylate α- ketoglutarate. Since initially the transport of α-ketoglutarate could only be demonstrated in vivo but not in vitro using established protocols (Mulligan et al. 2009), we investigated in detail the differences between the in vivo and in vitro assay. This resulted in a bioinformatic analysis of TRAP and TAXI signal peptides, which strongly implied that TAXIPm-P requires a transmembrane anchor to allow for transport. We then provided TAXIPm-P surface tethered to the membrane in in vitro transport assays and confirmed the prediction of our bioinformatic analysis that TAXIPm-PQM deploys a membrane-anchored instead of a soluble SBP. Furthermore, the TAXI transport system TAXIMh-PQM from Marinobacter hydrocarbonoclasticus transports fumarate only if both membrane domains Q and M are present. For further characterization, Michaelis-Menten kinetics and affinities were determined for both TAXI transport systems TAXIPm-PQM from Proteus mirabilis and TAXIMh-PQM from Marinobacter hydrocarbonoclasticus. In addition, nanobodies were selected for the membrane domain TAXIPm-QM from Proteus mirabilis to stabilize different conformations which can serve in subsequent structural elucidation studies. Furthermore, the TRAP SBP TRAPHi-SiaP from Haemophilus influenzae was shown to interact not only with its corresponding membrane domain TRAPHi-SiaQM but with at least one additional transporter. It was thereby excluded that TRAPHi- SiaP transfers N-acetylneuraminic acid to the only native E. coli TRAP transporter TRAPEc-YiaMNO and suggested to rather interact with a SBP dependent ABC transport system as this protein family represents the largest SBP dependent protein group in E. coli (Moussatova et al. 2008).
Salt-inducible kinases (SIKs) are key metabolic regulators. Imbalance of SIK function is associated with the development of diverse cancers, including breast, gastric and ovarian cancer. Chemical tools to clarify the roles of SIK in different diseases are, however, sparse and are generally characterized by poor kinome-wide selectivity. Here, we have adapted the pyrido[2,3-d]pyrimidin-7-one-based PAK inhibitor G-5555 for the targeting of SIK, by exploiting differences in the back-pocket region of these kinases. Optimization was supported by high-resolution crystal structures of G-5555 bound to the known off-targets MST3 and MST4, leading to a chemical probe, MRIA9, with dual SIK/PAK activity and excellent selectivity over other kinases. Furthermore, we show that MRIA9 sensitizes ovarian cancer cells to treatment with the mitotic agent paclitaxel, confirming earlier data from genetic knockdown studies and suggesting a combination therapy with SIK inhibitors and paclitaxel for the treatment of paclitaxel-resistant ovarian cancer.
Unc-51-like kinase 4 (ULK4) is a pseudokinase that has been linked to the development of several diseases. Even though sequence motifs required for ATP binding in kinases are lacking, ULK4 still tightly binds ATP and the presence of the cofactor is required for structural stability of ULK4. Here we present a high-resolution structure of a ULK4-ATPγS complex revealing a highly unusual ATP binding mode in which the lack of the canonical VAIK motif lysine is compensated by K39, located N-terminal to αC. Evolutionary analysis suggests that degradation of active site motifs in metazoan ULK4 has co-occurred with an ULK4 specific activation loop, which stabilizes the C-helix. In addition, cellular interaction studies using BioID and biochemical validation data revealed high confidence interactors of the pseudokinase and armadillo repeat domains. Many of the identified ULK4 interaction partners were centrosomal and tubulin associated proteins and several active kinases suggesting new roles for ULK4.
Highlights: Structure of the ULK4 ATP complex reveals a unique ATP binding mode.
Disease associated mutations modulate ATP binding and ULK4 stability
Degradation of active site motifs co-occurred in evolution with an ULK4 specific activation loop
BioID suggests a role of ULK4 regulating centrosomal and cytoskeletal functions,
MKK7 (MEK7) is a key regulator of the JNK stress signaling pathway and targeting MKK7 has been proposed as a chemotherapeutic strategy. Detailed understanding of the MKK7 structure and factors that impact its activity is therefore of critical importance. Here, we present a comprehensive set of MKK7 crystal structures revealing insights into catalytic domain plasticity and the role of the N-terminal regulatory helix, conserved in all MAP2Ks, mediating kinase activation. Crystal structures harboring this regulatory helix revealed typical structural features of active kinase, providing exclusively a first model of the MAP2K active state. A small molecule screening campaign yielded multiple scaffolds, including type-II irreversible inhibitors a binding mode that has not been reported previously. We also observed an unprecedented allosteric pocket located in the N-terminal lobe for the approved drug ibrutinib. Collectively, our structural and functional data expand and provide alternative targeting strategies for this important MAP2K kinase.
Selectivity remains a challenge for ATP-mimetic kinase inhibitors, an issue that may be overcome by targeting unique residues or binding pockets. However, to date only few strategies have been developed. Here we identify that bulky residues located N-terminal to the DFG motif (DFG-1) represent an opportunity for designing highly selective inhibitors with unexpected binding modes. We demonstrate that several diverse inhibitors exerted selective, noncanonical binding modes that exclusively target large hydrophobic DFG-1 residues present in many kinases including PIM, CK1, DAPK, and CLK. By use of the CLK family as a model, structural and biochemical data revealed that the DFG-1 valine controlled a noncanonical binding mode in CLK1, providing a rationale for selectivity over the closely related CLK3 which harbors a smaller DFG-1 alanine. Our data suggest that targeting the restricted back pocket in the small fraction of kinases that harbor bulky DFG-1 residues offers a versatile selectivity filter for inhibitor design.
Selectivity remains a challenge for ATP-mimetic kinase inhibitors, an issue that may be overcome by targeting unique residues or binding pockets. However, to date only few strategies have been developed. Here we identify that bulky residues located N-terminal to the DFG motif (DFG-1) represent an opportunity for designing highly selective inhibitors with unexpected binding modes. We demonstrate that several diverse inhibitors exerted selective, non-canonical binding modes that exclusively target large hydrophobic DFG-1 residues present in many kinases including PIM, CK1, DAPK and CLK. Using the CLK family as a model, structural and biochemical data revealed that the DFG-1 valine controlled a non-canonical binding mode in CLK1, providing a rational for selectivity over the closely-related CLK3 which harbors a smaller DFG-1 alanine. Our data suggests that targeting the restricted back pocket in the small fraction of kinases that harbor bulky DFG-1 residues offers a versatile selectivity filter for inhibitor design.
The nsP3 macrodomain is a conserved protein interaction module that plays essential regulatory roles in host immune response by recognizing and removing posttranslational ADP-ribosylation sites during SARS-CoV-2 infection. Thus, targeting this protein domain may offer a therapeutic strategy to combat the current and future virus pandemics. To assist inhibitor development efforts, we report here a comprehensive set of macrodomain crystal structures complexed with diverse naturally-occurring nucleotides, small molecules as well as nucleotide analogues including GS-441524 and its phosphorylated analogue, active metabolites of remdesivir. The presented data strengthen our understanding of the SARS-CoV-2 macrodomain structural plasticity and it provides chemical starting points for future inhibitor development.
DNA points accumulation for imaging in nanoscale topography (DNA-PAINT) is a super-resolution technique with relatively easy-to-implement multi-target imaging. However, image acquisition is slow as sufficient statistical data has to be generated from spatio-temporally isolated single emitters. Here, we train the neural network (NN) DeepSTORM to predict fluorophore positions from high emitter density DNA-PAINT data. This achieves image acquisition in one minute. We demonstrate multi-colour super-resolution imaging of structure-conserved semi-thin neuronal tissue and imaging of large samples. This improvement can be integrated into any single-molecule imaging modality to enable fast single-molecule super-resolution microscopy.
N6-methyladenosine (m6A) is the most abundant and well understood modification in eukaryotic mRNA and was first identified in polyadenylated parts of the mRNA.The distinct distribution of m6A in the transcriptome with special enrichment in long internal exons, 39UTRs and around stop codons was uncovered by early biochemical work and later on antibody based sequencing techniques. The so called m6A writer, reader and eraser machinery is responsible for the dynamic and with that regulatory nature of the m6A modification. As m6A writer, the human N6-methyltransferase complex (MTC) cotranscriptionally methylates the central adenine within a RRACH (preferably GGACU) sequence context to form m6A in the nascent RNA chain.9–15 The catalytic core of the complex is formed by the two proteins METTL3 and METTL14, with the active site located in the methyltransferase domain (MTD) of METTL3.16–18 The DPPW motif near the methyl donor S-adenosylmethionine (SAM) binding site in this MTD was postulated to bind the target adenine during catalysis. Moreover, a positively charged groove in the METTL3-METTL14 interface, the C-terminal RGG domain in METTL14 and the zinc finger motifs in METTL3 were identified as important domains for RNA binding. However, to date there are no full-length or substrate-RNA-bound structures of the catalytic METTL3-METTL14 complex.
In addition, a set of accessory proteins assembles to the METTL3-METTL14 heterodimer to form the full MTC, mediated by WTAP that firmly binds to the N-terminal leader helix in METTL3.20 WTAP was shown to locate the whole complex to the nuclear speckles and can modulate m6A deposition to specific sites in the RNA. Moreover, WTAP acts as binding platform for other accessory proteins including VIRMA, RBM15, ZC3H13 and HAKAI that are mostly identified to mediate position specific methylation. For example, RBM15 was shown to mediates region-selective methylation in a WTAP dependent manner, directing specificity towards U-rich sequences.
The observed specificity of the methyltransferase complex to methylate only site specific DRACH sequenced is still poorly understood. Some possible modulators like the role of the accessory proteins are under investigation, however, the structural context of the RNA methylation sites or a structural preference of the complex have been mainly neglected so far. Moreover, the structural dynamics of this methylation process still remain elusive. This thesis contributes to the afore-mentioned aspects by analysis of the methylation process regarding RNA structure sensitivity with enzymatic activity assays and its dynamic nature by implementing a smFRET approach.
We hypothesized the target RNA secondary structure to be an additional important modulator of methylation efficiency, based on the RNA binding elements of the complex (positively charged binding groove, zinc finger domain, RGG domain) and the supposed target adenine binding in the active site. Here, we postulated the possibility for a flipped-out adenine to be of special relevance, which is closely related to the local stability of the target adenine containing structure. Moreover, efficient binding of the protein complex to the RNA should require the ability to anchor the RNA on both sides of the target sequence.
Large international airports were identified as sources of ultrafine particles (UFPs) (Hu et al., 2009; Yu et al., 2012; Hsu et al., 2013; Keuken et al., 2015; Hudda and Fruin, 2016). Since September 2017 UFP emissions originating from the Frankfurt International Airport, Germany are monitored by the Hessian Agency for Nature Conservation, Environment and Geology (HLNUG) showing elevated UFP concentrations during airport operating hours (05:00–23:00 CET) (Ditas et al., 2022). Referring to that, the organic chemical composition of aviation-related UFPs emerging from the Frankfurt Airport was analysed by performing a comprehensive non-target screening of UFP filter samples.
Aluminium-filter samples were collected at an air quality monitoring station 4 km north of the Frankfurt Airport, using a 13-stage impactor system (Nano-MOUDI). The chemical
characterization of UFPs in the size range of 10-18 nm, 18-32 nm and 32-56 nm was accomplished by ultra-high-performance liquid chromatography, heated electrospray ionisation and mass analysis using an Orbitrap high-resolution mass spectrometer. Non-target screening revealed that the majority of detected compounds belong to homologous series of two different types of organic esters, which are base stocks of aircraft lubrication oils.
In reference to five different jet engine lubrication oils of various manufacturers, the corresponding lubricant base stocks and their additives, two amines and one organophosphate, were identified in the UFPs by the use of matching retention time, exact mass and MS/MS fragmentation pattern of single organic molecules. The quantitative analysis of the jet engine oil constituents in the aviation-related UFPs with diameters < 56 nm was accomplished by standard addition. By characterizing the Nano-MOUDI, loss factors for each size stage were determined and used for correction accordingly. Particle-number size distribution measurements, conducted parallel to the filter sampling, enabled the determination of the jet engine oil contribution to the UFP mass.
Furthermore, the nucleation and particle formation potential of a commonly used synthetic jet engine lubrication oil was investigated in the laboratory. Thermodenuder experiments at 20 °C and 300 °C were carried out to monitor the gas-to-particle partitioning behaviour of jet engine oils. At 300 °C a significantly higher number of particles with a mean diameter of ~10 nm are formed, leading to a more than fivefold increase in total particle numbers compared to 20 °C. Particle diameters of the newly formed oil particles in the laboratory experiment appeared in the same size region as UFPs emerging from Frankfurt Airport. Particles originating from the Frankfurt city centre direction showed larger diameters.
Results indicate that aircraft emissions strongly influence the total mass of 10-18 nm particles. The jet oil fraction decreases for bigger particles (e.g., 18-56 nm), implying that these oils form new particles in the cooling exhaust gases of aircraft engines. In addition, non-target screening and in vitro bioassays on aviation-related PM2.5 filter samples were combined to provide indications for potential toxicologically relevant compounds in dependence of different wind directions and airport operations. Most recently, the applied non-target screening method was also used to identify seasonal variations in the organic aerosol composition in Beijing.
F-type ATP synthases are multiprotein complexes composed of two separate coupled motors (F1 and FO) generating adenosine triphosphate (ATP) as the universal major energy source in a variety of relevant biological processes in mitochondria, bacteria and chloroplasts. While the structure of many ATPases is solved today, the precise assembly pathway of F1FO-ATP synthases is still largely unclear. Here, we probe the assembly of the F1 complex from Acetobacterium woodii. Using laser induced liquid bead ion desorption (LILBID) mass spectrometry, we study the self-assembly of purified F1 subunits in different environments under non-denaturing conditions. We report assembly requirements and identify important assembly intermediates in vitro and in cellula. Our data provide evidence that nucleotide binding is crucial for in vitro F1 assembly, whereas ATP hydrolysis appears to be less critical. We correlate our results with activity measurements and propose a model for the assembly pathway of a functional F1 complex.
Die vorliegende Dissertation mit dem Titel “Structural dynamics of eukaryotic H/ACA RNPs from Saccharomyces cerevisiae & Structural dynamics of the Guanidine-II riboswitch from Escherichia coli” besteht aus zwei Projekten. Das erste Projekt befasst sich mit den eukaryotischen H/ACA Ribonukleoproteinen (RNP) aus der Hefe. Diese können sequenzspezifisch in der RNA ein Uridin Nukleotid in das Rotationsisomer Pseudouridin (Ψ) umwandeln. Die H/ACA RNPs bestehen aus einer Leit-RNA und vier Proteinen, der katalytisch aktiven Pseudouridylase Cbf5, Nhp2, Gar1 und Nop10. Die Leit-RNA besteht in Eukaryoten konserviert aus zwei Haarnadelstrukturen, die von einem H-Box oder ACA-Box Sequenzmotiv gefolgt sind. In jeder dieser Haarnadeln befindet sich ein ungepaarter Bereich, die sogenannte Pseudouridylierungstasche, wo durch komplementäre Basenpaarung die Ziel-RNA gebunden wird. Fehlerhafte H/ACA RNPs können beim Menschen zu schweren Krankheiten wie verschiedenen Krebsarten oder dem Knochenmarksversagen Dyskeratosis congenita führen, aber sie bieten auch Möglichkeiten zum Einsatz als Therapiemethode. In dieser Arbeit wurde hauptsächlich der zweiteilige Aufbau der H/ACA RNPs untersucht.
Dafür wurden zunächst die einzelnen Komponenten hergestellt werden. Cbf5, Nop10 und Gar1 wurden zusammen heterolog in E. coli exprimiert und gereinigt. Außerdem wurden mehrere Deletionsvarianten von Gar1 hergestellt. Zusätzlich wurde die Leit-RNA unmarkiert über T7 Transkription synthetisiert, sowie sechs verschiedene FRET-Konstrukte mit verschiedenen Markierungschemas der Fluorophore Cy3 und Cy5 über DNA-geschiente Ligation. Anschließend wurde über Größenausschlusschromatographie und radioaktiven Aktivitätsassays geprüft, dass sich die aktiven H/ACA RNPs in vitro aus den einzelnen Komponenten rekonstituieren lassen.
In smFRET Experimenten wurden einzelne Haarnadelstrukturen mit dem zweiteiligen Komplexen verglichen. Dabei konnte gezeigt werden, dass die H3 Haarnadel durch die Anwesenheit von H5 dynamischer und heterogener wurde, während H5 überwiegend unbeeinflusst war. Außerdem konnte die dreidimensionale Orientierung der Haarnadelstrukturen in verschiedenen Assemblierungsschritten mittels smFRET untersucht werden. Hier deutete sich an, dass in Abwesenheit von Proteinen beide Haarnadeln eher entgegengesetzt stehen als in einer parallelen Konformation. Cbf5 scheint den Linker zwischen den Beiden auszustrecken bzw. zu orientieren und die Haarnadelstrukturen etwas gegeneinander zu neigen. Ein Zusammenspiel von Nhp2 und Gar1 war nötig um die oberen Bereiche der Haarnadeln zusammenzuziehen. Es konnte auch ein Modell für den vollen H/ACA RNP vorgeschlagen werden. Im kompletten Komplex könnte das Zusammenziehen der Haarnadelstrukturen durch Nhp2 und Gar1 mit dem Effekt von Cbf5 konkurrieren und könnte hauptsächlich den oberen Bereich von H3 betreffen. Zum Schluss wurde das Zusammenspiel von Gar1 und Nhp2 auf eine Abhängigkeit von den RGG Domänen von Gar1 hin untersucht. Hier besteht möglicherweise eine Hierarchie, die eine Kooperativität von den N- und C-terminalen Domänen benötigt.
Das zweite Projekt befasst sich mit dem Guanidin-II Riboschalter aus E. coli. Der Riboschalter kann das toxische Molekül Guanidinium (Gdm+) spezifisch in seiner Aptamerdomäne binden und dadurch die Genexpression von Proteinen zur Detoxifizierung von Gdm+ aktivieren. Der Riboschalter besteht aus zwei Haarnadelstrukturen, mit einer Schleife, die aus der Sequenz ACGR besteht, wobei R ein Purin ist. In einem vorgeschlagenen Modell soll die Ribosomenbindestelle (Shine-Dalgarno Sequenz) in Abwesenheit von Ligand mit dem Linker komplementär Basenpaaren und so die Translation verhindern. Mit Ligand würde sich dann eine Schleifen-Schleifen Interaktion mit den beiden CG Basen ausbilden, wodurch die Anti-Shine-Dalgarno Sequenz nicht mehr zugänglich wäre. Bisherige Studien arbeiteten zumeist nur mit der Aptamerdomäne, den einzelnen Haarnadeln oder noch kleineren Elementen. In dieser Arbeit wurden die Strukturdynamiken von verschiedenen Längen, auch mit der Expressionsplatform, untersucht. Außerdem wurden verschiedene Mutationen analysiert und die Effekte auf den Riboschalter in seiner natürlichen Umgebung in E. coli.
Zunächst mussten insgesamt 24 FRET-Konstrukte hergestellt werden, die sich in Länge, Markierungsschema und Mutationen unterschieden. Hierfür wurde DNA-geschiente Ligation verwendet. Dank der verschiedenen Fluorophorpositionen konnte ein konformationelles Modell für die Aptamerdomäne vorgeschlagen werden. In diesem Modell könnte in Abwesenheit von Ionen das Aptamer offen vorliegen. Durch Mg2+ würde sich bereits eine lockere Schleifen-Schleifen Interaktion ausbilden. Zusätzlich deuten die Ergebnisse auf eine neue Konformation hin, der stabilisierten Schleifen-Schleifen Interaktion, bei der der Linker zusätzlich mit den Haarnadelstrukturen interagiert, beispielswese mit den Purinen an der vierten Schleifenposition...
Bleaching-independent, whole-cell, 3D and multi-color STED imaging with exchangeable fluorophores
(2018)
We demonstrate bleaching-independent STED microscopy using fluorogenic labels that reversibly bind to their target structure. A constant exchange of labels guarantees the removal of photobleached fluorophores and their replacement by intact fluorophores, thereby circumventing bleaching-related limitations of STED super-resolution imaging in fixed and living cells. Foremost, we achieve a constant labeling density and demonstrate a fluorescence signal for long and theoretically unlimited acquisition times. Using this concept, we demonstrate whole-cell, 3D, multi-color and live cell STED microscopy with up to 100 min acquisition time.
Alzheimer’s Disease (AD) is a progressive and irreversible neurodegenerative disorder, characterized by the accumulation of abeta-amyloid aggregates, which triggers tau hyperphosphorylation and neuronal loss. While the precise mechanisms underlying neurodegeneration in AD are not entirely understood, it is known that loss of proteostasis is implicated in this process. Maintaining neuronal proteostasis requires proper transfer RNA (tRNA) modifications, which are crucial for optimal translation. However, research into tRNA epitranscriptome in AD is limited, and it is not yet clear how alterations in tRNA modifying enzymes and tRNA modifications might contribute to disease progression. Here, we report that expression of the tRNA modifying enzyme ELP3 is reduced in the brain of AD patients and amyloid AD mouse models, suggesting ELP3 is implicated in proteostasis dysregulation observed in AD. To investigate the role of ELP3 specifically in neuronal proteostasis impairments in the context of amyloid pathology, we analyzed SH-SY5Y neuronal cells carrying the amyloidogenic Swedish familial AD mutation in the APP gene (SH-SWE) or the wild-type gene (SH-WT). Similarly to the amyloid mouse models, SH-SWE exhibited reduced levels of ELP3 which was associated with tRNA hypomodifications and reduced abundance, as well as proteostasis impairments. Furthermore, the knock-down of ELP3 in SH-WT recapitulated the proteostasis impairments observed in SH-SWE cells. Importantly, the correction of tRNA deficits due to ELP3 reduction rescued and reverted proteostasis impairments of SH-SWE and SH-WT knock-down for ELP3, respectively. Additionally, SH-WT exposed to the secretome of SH-SWE or synthetic amyloid aggregates recapitulate the SH-SWE phenotype, characterized by reduced ELP3 expression, tRNA hypomodification and increased protein aggregation. Taken together, our data suggest that amyloid pathology dysregulates neuronal proteostasis through the reduction of ELP3 and tRNA modifications. This study highlights the modulation of tRNA modifications as a potential therapeutic avenue to restore neuronal proteostasis in AD and preserve neuronal function.
Different modification pathways for m1A58 incorporation in yeast elongator and initiator tRNAs
(2022)
As essential components of the cellular protein synthesis machineries, tRNAs undergo a tightly controlled biogenesis process, which include the incorporation of a large number of posttranscriptional chemical modifications. Maturation defaults resulting in lack of modifications in the tRNA core may lead to the degradation of hypomodified tRNAs by the rapid tRNA decay (RTD) and nuclear surveillance pathways. Although modifications are typically introduced in tRNAs independently of each other, several modification circuits have been identified in which one or more modifications stimulate or repress the incorporation of others. We previously identified m1A58 as a late modification introduced after more initial modifications, such as Ѱ55 and T54 in yeast elongator tRNAPhe. However, previous reports suggested that m1A58 is introduced early along the tRNA modification process, with m1A58 being introduced on initial transcripts of initiator tRNAiMet, and hence preventing its degradation by the nuclear surveillance and RTD pathways. Here, aiming to reconcile this apparent inconsistency on the temporality of m1A58 incorporation, we examined the m1A58 modification pathways in yeast elongator and initiator tRNAs. For that, we first implemented a generic approach enabling the preparation of tRNAs containing specific modifications. We then used these specifically modified tRNAs to demonstrate that the incorporation of T54 in tRNAPhe is directly stimulated by Ѱ55, and that the incorporation of m1A58 is directly and individually stimulated by Ѱ55 and T54, thereby reporting on the molecular aspects controlling the Ѱ55 → T54 → m1A58 modification circuit in yeast elongator tRNAs. We also show that m1A58 is efficiently introduced on unmodified tRNAiMet, and does not depend on prior modifications. Finally, we show that the m1A58 single modification has tremendous effects on the structural properties of yeast tRNAiMet, with the tRNA elbow structure being properly assembled only when this modification is present. This rationalizes on structural grounds the degradation of hypomodified tRNAiMet lacking m1A58 by the nuclear surveillance and RTD pathways.
Cyclophilins, or immunophilins, are proteins found in many organisms including bacteria, plants and humans. Most of them display peptidyl-prolyl cis-trans isomerase activity, and play roles as chaperones or in signal transduction. Here, we show that cyclophilin anaCyp40 from the cyanobacterium Anabaena sp. PCC 7120 is enzymatically active, and seems to be involved in general stress responses and in assembly of photosynthetic complexes. The protein is associated with the thylakoid membrane and interacts with phycobilisome and photosystem components. Knockdown of anacyp40 leads to growth defects under high-salt and high-light conditions, and reduced energy transfer from phycobilisomes to photosystems. Elucidation of the anaCyp40 crystal structure at 1.2-Å resolution reveals an N-terminal helical domain with similarity to PsbQ components of plant photosystem II, and a C-terminal cyclophilin domain with a substrate-binding site. The anaCyp40 structure is distinct from that of other multi-domain cyclophilins (such as Arabidopsis thaliana Cyp38), and presents features that are absent in single-domain cyclophilins.
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.
Caspase-2 is the evolutionary most conserved member of the caspase family and was shown to be involved in genotoxic stress induced apoptosis, control of aneuploidy, and ageing related metabolic changes. However, its role in apoptosis seems redundant due to the observation, that knockout does not inhibit apoptotic signalling exclusively. Instead, knockout of caspase-2 leads to tumor susceptibility in vivo, which led to the assumption, that caspase-2 has non-apoptotic functions and can act as a tumor suppressor. The underlying mechanism of the tumor suppressor activity of caspase-2 has not been clarified so far. Furthermore, caspase-2, has a prominent, and as pro-enzyme exclusive localisation in the nucleus and other subcellular compartments, implicating a distinct and location specific role.
In this study, a novel caspase-2 specific substrate, termed p54nrb, was identified. P54nrb is harbouring a caspase-2 specific cleavage site at the aspartate residue D422, and cleavage of p54nrb leads apparently to disruption of its putative DNA binding domain at the C-terminus.
P54nrb is a nuclear multifunctional RNA and DNA binding protein, known for roles in transcriptional regulation, DNA unwinding and repair, RNA splicing, and retention of defective RNA. Overexpression of p54nrb has been observed in several human cancers, such as cervix carcinoma, melanoma, and colon carcinoma.
Data from this study revealed, that depletion of p54nrb in tumor cell lines results in a loss of resistance to drug induced cell death and to reduced capability of anchorage independent growth, which is functionally equivalent to a reduced tumorigenic potential. Meanwhile, p54nrb depletion alone is not cytotoxic.
The investigation of p54nrb dependent gene regulations by high resolution quantitative proteomics uncovered an altering expression of multiple tumorigenic genes. For two of these candidates, the tumorigenic protease cathepsin-Z and the anti-apoptotic gelsolin, p54nrb dependent expression was detected universally in all three investigated tumor cell lines, cervix carcinoma, melanoma, and colon carcinoma. Additionally, a direct interaction of p54nrb with the cathepsin Z and gelsolin encoding DNA, but not with their corresponding mRNA, could be demonstrated.
Conjointly, this study unveils a novel mechanistic feature of caspase-2 as a tumor suppressor. The caspase-2—p54nrb axis can orchestrate the levels of several tumorigenic proteins and thereby determine the cell death susceptibility and long-term tumor survival. These findings might be of great value for future therapeutic interventions and for overcoming drug resistance of tumors.
The photodynamic inactivation of nucleic acids with pyronin, methylene blue, thiopyronin and furocoumarines has been studied. The template efficiency of DNA in RNA-Polymerase reaction was found to be decreased after the treatment of DNA with these compounds. However, the magnitude of their inhibiting capacity varied from one compound to the other. Psoralen and thiopyronin were found to be the most active inhibitors followed by xanthotoxin and methylene blue respectively. At a lower temperature the inhibiting capacity of thiopyronin was considerably decreased but that of psoralen remained nearly unaffected. We have also tried to show evidence for a complimentary code in t-RNA through a specific destruction of guanine with thiopyronin.
The peptide loading complex (PLC) is a central machinery in adaptive immunity ensuring antigen presentation by major histocompatibility complex class I (MHC I) molecules to immune cells. If nucleated cells present foreign antigenic peptides from various origins (e.g., viral infected or cancer cells) on their cell surface they are targeted and eliminated by effector cells of the immune system to protect the organism against the hazard. The antigen presentation process starts with proteasomal degradation. Peptide loading and quality control of most, if not all, MHC I is performed by the PLC. Despite the main components, architecture, and general functions of this labile and multi-subunit assembly have been described, knowledge about the inner mechanics of MHC I loading and quality control in the PLC is limited. Detailed structural insights into the interactions and functions of key elements are lacking. In this PhD thesis, structural and functional aspects of the PLC in peptide loading and quality control of MHC I are unraveled, and the PLC was analyzed from an evolutionary perspective.
First, composition and architecture of native PLC isolated from different mammalian species was analyzed. Comparison of detergent-solubilized PLC from cow and sheep spleens with PLC isolated from human source showed a compositional conservation in mammals, with the central components TAP, ERp57, tapasin, calreticulin, and the MHC I heterodimer were conserved in these species. Negative-stain electron microscopy (EM) analyses revealed an identical overall architecture of PLCs from human, sheep, and cow with two major densities at opposing sides of the plane of the detergent micelle corresponding to endoplasmic reticulum (ER) luminal and cytosolic domains. Interestingly, the glucose-regulated protein 78 (GRP78) was associated only with the PLC from sheep and cow as revealed by mass spectrometry. This ER chaperone is involved in initial folding steps of MHC I but was not co-purified with human PLC, rendering it an interesting target for future functional and in-depth structural studies.
The human PLC was stabilized by reconstitution in membrane mimicking systems that replace the detergent, which is necessary to solubilize the complex. This stabilization allowed detailed structural analysis by single-particle cryogenic electron microscopy (cryo-EM). The structure of the MHC I editing module in the PLC, composed of tapasin, ERp57, calreticulin, MHC I, and β-2-microglobulin (β2m), was solved at an overall resolution of 3.7 Å. Within the structure, two important features were visualized: (i) the editing loop of tapasin, which is directly involved in peptide proofreading of MHC I; (ii) the A-branch of the Asn86 tethered N-linked glycan on MHC I. Both features are crucial elements in the quality control and peptide editing process on MHC I. The editing loop interacts with the peptide binding groove in MHC I. It disturbs the interaction between a cargo peptide C terminus and the F-pocket in the binding groove by displacing Tyr84 and the helices α1 and α2. The helix displacement widens the F-pocket which allows a faster peptide exchange on MHC I. The glycan is bound in its monoglucosylated form (Glc1Man9GlcNAc2) by the lectin domain of calreticulin. The A-branch of this glycan is stretched between MHC I Asn86 and the lectin domain, leading to the hypothesis that the glycan will be released from calreticulin once MHC I is loaded with a favored peptide (pMHC I).
For investigation of the glycan status of MHC I, intact protein liquid chromatography coupled mass spectrometry (LC-MS) was performed under denaturating conditions. An allosteric coupling between peptide loading and removal of the terminal glucose by α-Glucosidase II (GluII) was discovered. In addition, the PLC remained fully intact after peptide loading, which demonstrated GluII action on the PLC once MHC I is loaded.
With establishing GluII as transient interaction partner, this work deepens the knowledge of the molecular sociology of the PLC and how the PLC is involved in the endoplasmic reticulum quality control (ERQC). Further investigation of the ER aminopeptidases ERAP1 and ERAP2 showed that these enzymes neither alone nor together stably interact with the PLC. In contrast, both work independent from the PLC on free peptides in the ER.
LC-MS analysis of the PLC components revealed a very unusual glycosylation pattern of tapasin. Tapasin was observed with N-linked glycans ranging from the full glycan (Man9GlcNAc2) to heavily trimmed glycans, where only a single GlcNAc remained attached to Asn233. In the PLC, tapasin is probably shielded from degradation by ERQC and can remain functional and intact without a full N-linked glycan.
Bei der UV-Bestrahlung von Uracil-[5.6-3H] bilden sich je nach eingestrahlter Energie dimeres Uracil und Uracil-Wasseranlagerungsprodukt [5.6-Dihydro-6-hydroxyuracil] als radioaktive Photoprodukte. Während bei der Synthese des Wasseranlagerungsproduktes ein beträchtlicher sekundärer Isotopeneffekt wirksam wird, verändert sich die Radioaktivität des dimeren Uracils gegenüber der des Ausgangsuracils kaum.
Wird das Wasseranlagerungsprodukt durch Erwärmen zu Uracil zurückgewandelt, so dehydratisiert das Molekül ebenfalls unter Mitwirkung eines Isotopeneffektes. Wird das Uracildimere zu Uracil rückgewandelt, so beobachtet man keinen Isotopeneffekt.
Bei der Bestrahlung von Uracil in Tritium-haltigem Wasser werden nur sehr geringe Radioaktivitäten in die Photoprodukte eingebaut. Der Isotopeneffekt beträgt ca. 8. — Durch Synthese der Photoprodukte aus spezifisch an C-5 oder C-6 Tritium-markiertem Uracil bzw. durch Bromierung von 5.6-Tritium-markiertem Uracil bzw. dessen Photoprodukten zu den 5-Brom-Derivaten erhält man Hinweise, daß der Geschwindigkeits-bestimmende Schritt der Wasseraddition an C-6 des Uracils verläuft. Die inversen sekundären Isotopeneffekte betragen für Tritium an C-6 etwa 0,65, für Tritium an C-5 dagegen nur 0,95.
The transient receptor potential (TRP) ankyrin type 1 (TRPA1) channel is highly expressed in a subset of sensory neurons where it acts as an essential detector of painful stimuli. However, the mechanisms that control the activity of sensory neurons upon TRPA1 activation remain poorly understood. Here, using in situ hybridization and immunostaining, we found TRPA1 to be extensively co-localized with the potassium channel Slack (KNa1.1, Slo2.2, or Kcnt1) in sensory neurons. Mice lacking Slack globally (Slack−/−) or conditionally in sensory neurons (SNS-Slack−/−) demonstrated increased pain behavior after intraplantar injection of the TRPA1 activator allyl isothiocyanate. By contrast, pain behavior induced by the TRP vanilloid 1 (TRPV1) activator capsaicin was normal in Slack-deficient mice. Patch-clamp recordings in sensory neurons and in a HEK cell line transfected with TRPA1 and Slack revealed that Slack-dependent potassium currents (IKS) are modulated in a TRPA1-dependent manner. Taken together, our findings highlight Slack as a modulator of TRPA1-mediated, but not TRPV1-mediated, activation of sensory neurons.
Keywords: TRPA1; slack; dorsal root ganglia; pain; mice
Bei saurer Hydrolyse wird aus den 5-Halogenuracildesoxyribosiden die DR ** etwa 3 -4-mal rascher abgespalten als aus TdR oder UdR. CdR wird unter den gleichen Bedingungen 16-fach schneller hydrolysiert. Im Gegensatz dazu ist die Ribose im Cytidin um ein Mehrfaches fester gebunden als im Uridin. Im TdR-Dimeren wird durch die Absättigung der 5.6-Doppelbindung die Stabilität der N-glykosidischen Bindung stark erniedrigt. Aus diesen Befunden ergibt sich ein Hinweis auf die Elektronendichte-Verteilung im Pyrimidinring und damit eine chemische Basis für das mutagene Verhalten verschiedener unnatürlicher Desoxyriboside.
G-quadruplexes (G4), found in numerous places within the human genome, are involved in essential processes of cell regulation. Chromosomal DNA G4s are involved for example, in replication and transcription as first steps of gene expression. Hence, they influence a plethora of downstream processes. G4s possess an intricate structure that differs from canonical B-form DNA. Identical DNA G4 sequences can adopt multiple long-lived conformations, a phenomenon known as G4 polymorphism. A detailed understanding of the molecular mechanisms that drive G4 folding is essential to understand their ambivalent regulatory roles. Disentangling the inherent dynamic and polymorphic nature of G4 structures thus is key to unravel their biological functions and make them amenable as molecular targets in novel therapeutic approaches. We here review recent experimental approaches to monitor G4 folding and discuss structural aspects for possible folding pathways. Substantial progress in the understanding of G4 folding within the recent years now allows drawing comprehensive models of the complex folding energy landscape of G4s that we herein evaluate based on computational and experimental evidence.
Specialized surveillance mechanisms are essential to maintain the genetic integrity of germ cells, which are not only the source of all somatic cells but also of the germ cells of the next generation. DNA damage and chromosomal aberrations are, therefore, not only detrimental for the individual but affect the entire species. In oocytes, the surveillance of the structural integrity of the DNA is maintained by the p53 family member TAp63α. The TAp63α protein is highly expressed in a closed and inactive state and gets activated to the open conformation upon the detection of DNA damage, in particular DNA double-strand breaks. To understand the cellular response to DNA damage that leads to the TAp63α triggered oocyte death we have investigated the RNA transcriptome of oocytes following irradiation at different time points. The analysis shows enhanced expression of pro-apoptotic and typical p53 target genes such as CDKn1a or Mdm2, concomitant with the activation of TAp63α. While DNA repair genes are not upregulated, inflammation-related genes become transcribed when apoptosis is initiated by activation of STAT transcription factors. Furthermore, comparison with the transcriptional profile of the ΔNp63α isoform from other studies shows only a minimal overlap, suggesting distinct regulatory programs of different p63 isoforms.
Age-related multifactorial diseases, such as the neurodegenerative Alzheimer’s disease (AD), still remain a challenge to today’s society. One mechanism associated with AD and aging in general is mitochondrial dysfunction (MD). Increasing MD is suggested to trigger other pathological processes commonly associated with neurodegenerative diseases. Silibinin A (SIL) is the main bioactive compound of the Silymarin extract from the Mediterranean plant Silybum marianum (L.) (GAERTN/Compositae). It is readily available as a herbal drug and well established in the treatment of liver diseases as a potent radical scavenger reducing lipid peroxidation and stabilize membrane properties. Recent data suggest that SIL might also act on neurological changes related to MD. PC12APPsw cells produce low levels of human Aβ and thus act as a cellular model of early AD showing changed mitochondrial function. We investigated whether SIL could affect mitochondrial function by measuring ATP, MMP, as well as respiration, mitochondrial mass, cellular ROS and lactate/pyruvate concentrations. Furthermore, we investigated its effects on the mitochondrial membrane parameters of swelling and fluidity in mitochondria isolated from the brains of mice. In PC12APPsw cells, SIL exhibits strong protective effects by rescuing MMP and ATP levels from SNP-induced mitochondrial damage and improving basal ATP levels. However, SIL did not affect mitochondrial respiration and mitochondrial content. SIL significantly reduced cellular ROS and pyruvate concentrations. Incubation of murine brain mitochondria with SIL significantly reduces Ca2+ induced swelling and improves membrane fluidity. Although OXPHOS activity was unaffected at this early stage of a developing mitochondrial dysfunction, SIL showed protective effects on MMP, ATP- after SNP-insult and ROS-levels in APPsw-transfected PC12 cells. Results from experiments with isolated mitochondria imply that positive effects possibly result from an interaction of SIL with mitochondrial membranes and/or its antioxidant activity. Thus, SIL might be a promising compound to improve cellular health when changes to mitochondrial function occur.
Es wird das Mikrowellenspektrum von Fluorwasserstoffassoziaten im X-und K-Band bei -70 °C und 0,01 Torr gemessen und analysiert. Dazu wird ein erstelltes Frequenzprogramm für den asymmetrischen Kreisel verwendet, sowie ein Extrapolationsprogramm, das eine in der Literatur angegebene druck-und temperaturabhängige Verteilung der Fluorwasserstoffassoziate auf für Mikrowellenspektroskopie geeignete Drücke und Temperaturen umzurechnen erlaubt. Es zeigt sich, daß planare hexamere und heptamere Fluorwasserstoffassoziate vorliegen mit F-F-F-Winkeln von etwa 104° und H-F-Bindungslängen von 0,9997 Å bzw. 0,9640 Å. Die Längen der Wasserstoff brücken sind 1,4998 Å bzw. 1,6105 Å. Ein Vergleich der Bindungslängen zeigt, daß bei Anlagerung von H-F an (HF)6 eine Kontraktion der Fluorwasserstoffbindung um 3,5% und eine Dilatation der Wasserstoffbrückenbindung um 1% stattfindet. Dieses Ergebnis steht im Einklang mit der oben erwähnten Assoziatverteilung, die eine Minderung der Kettenstabilität beim Übergang von hexamerer zu heptamerer Kette erwarten läßt.
The extremophile Alvinella pompejana, an annelid worm living on the edge of hydrothermal vents in the Pacific Ocean, is an excellent model system for studying factors that govern protein stability. Low intrinsic stability is a crucial factor for the susceptibility of the transcription factor p53 to inactivating mutations in human cancer. Understanding its molecular basis may facilitate the design of novel therapeutic strategies targeting mutant p53. By analyzing expressed sequence tag (EST) data, we discovered a p53 family gene in A. pompejana. Protein crystallography and biophysical studies showed that it has a p53/p63-like DNA-binding domain (DBD) that is more thermostable than all vertebrate p53 DBDs tested so far, but not as stable as that of human p63. We also identified features associated with its increased thermostability. In addition, the A. pompejana homolog shares DNA-binding properties with human p53 family DBDs, despite its evolutionary distance, consistent with a potential role in maintaining genome integrity. Through extensive structural and phylogenetic analyses, we could further trace key evolutionary events that shaped the structure, stability, and function of the p53 family DBD over time, leading to a potent but vulnerable tumor suppressor in humans.
RNAs are key players in life as they connect the genetic code (DNA) with all cellular processes dominated by proteins. The dynamics study of RNA modifications has become an important part of epitranscriptomics field, as they are reversible and dynamically regulated far more than originally thought. Several evidences portrait a catalog of RNA modifications and their links to neurological disorders, cancers, and other diseases. Therefore, a deeper investigation of RNA modifications dynamics including their specific profile, biosynthesis, maturation and degradation is required for pioneering disease diagnostics and potential therapeutics development.
Mammalian tissues reveal diverse physiology and functions, despite sharing identical genomes and overlapping transcription profiles. So far, most research on this diversity were referred to variable transcriptomic processing among tissues and differential post-translational modifications that tune the activity of ubiquitous proteins to each tissue’s needs. However, study of epitranscriptome dynamics relevance to tissues’ functions is not yet revealed. There are a few reports on mouse RNA modification profiles, which are focused on only one type of RNA and limited types of modifications. The first part of my dissertation aims to generate a comprehensive tissue-specific as well as RNA species-specific investigation of all existing RNA modifications, as well as investigating potential codon as an effector of translation diversity among tissues. Using isotope dilution mass spectrometry, I created a library including absolute quantification of 24 tRNA modifications, and up to 22 rRNA modifications. I find an almost identical pattern of modifications in 28S- and 18S-rRNA subunits, but different levels of most modifications in 5.8S-rRNA or tRNA among highly metabolic active organs to e.g. heart or spleen. The findings suggest a high degree of similarity between quantities of modifications between presented data to all previous literature, confirming that it is a suitable model to study the tissue-based RNA modification patterns.
The most noticeable difference exhibited was tRNA modifications, which suggests a discerning tRNA engagement in translation between different organs. This can be a good start for investigation of codon bias in enriched genes of specific tRNA modifications among different tissues that may cause differential translation pattern, causing organs diversity. Moreover, 5.8S rRNA data showed an organ-specific pattern, which proposes functional diversity of this rRNA subunit among different organs. Future studies must investigate the possible implications of organ-specific 5.8S rRNA modifications functions, to elucidate the core of the observed variations.
Abundance of RNA modifications is carefully regulated in cells. Part of this regulation is achieved by activity of enzymes removing RNA modifications, named RNA erasers. Literature has provided proof of demethylation activity of AlkBH family on different types of RNA. For instance, AlkBH5 is known to remove m6A in mRNA, and both AlkBH3 and AlkBH1 are reported to demethylate m1A and m3C in tRNA. So far, RNA erasers are mainly studied in vitro and direct in vivo studies are missing.
Mass spectrometry is a promising approach in the identification and quantification of many RNA modifications. However, mass spectrometric analysis by nature, offers only a static view of nucleic acid modifications, and fails to account for their cellular dynamics. Nucleic Acid Isotope Labeling coupled Mass Spectrometry (NAIL-MS) was developed as a powerful technique which differentiates among remaining, co-transcriptional and post-transcriptional incorporation of a target RNA modification. This temporal resolution captures the dynamic nature of RNA modifications, and offers absolute and relative quantification of all existing nucleosides in any given RNA sequence, including different isotopologues and isotopomers.
The objective of this study was to uncover the first “direct” iv vivo data on AlkBH1, 3 and 5 activities in demethylating each of their specific substrates. I investigated the RNA modification changes through pulse-chase experiments in collaboration with my colleagues Dr. Kayla Borland and Dr. Felix Hagelskamp. A remarkable observation was that AlkBH3 protein -but not AlkBH1- was overexpressed under methylating reagent treatment in vivo. These findings suggest that AlkBH3 -but not AlkBH1- is a methylation damage induced enzyme, that potentially triggers ASCC-AlkBH3 alkylation repair complex after aberrant methylation damage by MMS treatment. However, using NAIL-MS method, we could not detect any significant effect on demethylation activity of the enzymes in tRNA, rRNA or mRNA towards the possible substrates m6A, m1A, m3C, m5C and m7G in vivo. These distinct outcomes can be partially explained by probable existence of other unidentified demethylases that compensate for AlkBHs demethylation activity; or more probably, demethylation may still arise by remaining active AlkBHs to restore the original levels of the observed RNA modifications, since a stronger KD or a complete knockout of AlkBHs genes was not possible. Further research on fully knocked out AlkBHs genes can provide stronger evidence on unidentified demethylation activities in HEK cells.
YEATS-domain-containing MLLT1 is an acetyl/acyl-lysine reader domain, which is structurally distinct from well-studied bromodomains and has been strongly associated in development of cancer. Here, we characterized piperazine-urea derivatives as an acetyl/acyl-lysine mimetic moiety for MLLT1. Crystal structures revealed distinct interaction mechanisms of this chemotype compared to the recently described benzimidazole-amide based inhibitors, exploiting different binding pockets within the protein. Thus, the piperazine-urea scaffold offers an alternative strategy for targeting the YEATS domain family.
Dysfunction of YEATS-domain-containing MLLT1, an acetyl/acyl-lysine dependent epigenetic reader domain, has been implicated in the development of aggressive cancers. Mutations in the YEATS domain have been recently reported as a cause of MLLT1 aberrant reader function. However, structural basis for the reported alterations in affinity for acetyled/acylated histone has remained elusive. Here, we report the crystal structures of both insertion and substitution present in cancer, revealing significant conformational changes of the YEATS-domain loop 8. Structural comparison demonstrates that such alteration not only altered the binding interface for acetylated/acylated histones, but the sequence alterations in the T1 loop may enable dimeric assembly consistent inducing self-association behavior. Nevertheless, we show that also the MLLT1 mutants can be targeted by developed acetyllysine mimetic inhibitors with affinities similarly to wild type. Our report provides a structural basis for the altered behaviors and potential strategy for targeting oncogenic MLLT1 mutants.
G-protein-coupled receptors (GPCRs) from the largest family of receptors in the human body. They contain seven transmembrane helices. There are roughly 800-900 GPCR genes expressed in humans encoded by 4-5% of the human genome. These receptors are the most important signal transducers and play a crucial role in cell physiology and pathology, by using various extracellular stimuli to start complex intracellular signaling. GPCRs interact with a wide variety of stimuli from small molecules (photons, ions, amines) to large molecules (peptides, small proteins), and trigger downstream cascade effects by interacting with G-proteins, GPCR kinases, and ß-arrestin. Because of their crucial roles in many cellular functions, GPCRs are the most important drug targets for the pharmaceutical industry. Approximately 30% of the clinically approved drugs available in the market are against GPCRs. In this work achieved successful expression and purification of GPCRs from class-C and class-A families. Combined with biochemical experiments, DNP-ssNMR, and molecular simulation helped to decipher the mechanism of crosstalk between the allosteric modulator, and the orthosteric binding sites of the peptide receptor. The main findings and major highlights of this dissertation are outlined in the following paragraphs.
The calcium-sensing receptor (CaSR) belongs to the GPCR class-C family and contains a large extracellular domain. This receptor regulates Ca2+ homeostasis in blood and its absorption in the kidney and bone. To understand the molecular and structural mechanisms of these receptors their cDNAs were cloned into the pPICZ and pOET1 vectors to express them in Pichia pastoris and in Sf9 insect cells respectively. The CaSR was successfully expressed heterologously in Pichia pastoris and in the insect cell with high yield. The purified receptor purified in LMNG shows no aggregation in a monomeric state. Further optimization was performed to use it for cryo-EM sample preparation and structure determination. In 2nd part of the thesis, different mini G (mini Gs, mini Gi, mini Gqs, and mini Gsi) DNA constructs were made and expressed in E. coli. It's challenging to obtain active GPCR structures due to the instability of G-protein or G-protein-bound receptors. In this work, all mini-G proteins and chimera mini-G-protein-maltose binding protein (MBP) were cloned and expressed in E. coli and purified with a His-trap column with high purity.
In the last part of the thesis, to decipher the mechanism of allosteric modulation of orthosteric binding sites in the bradykinin receptor was produced and characterized in insect cells. Angiotensin I converting enzyme inhibitors (ACEIs), are very important drugs and are widely used for the treatment of hypertension, congestive heart failure, and diabetic neuropathy. These drugs target primarily the catalytic zinc center of the ACE. It has been shown that enalaprilat, a well-known ACEI, binds to a proposed zinc-binding site on hB1R and even directly activates the receptor. To obtain information on the influence of ACEIs on the receptor-peptide complex, and to have a better understanding of the molecular mechanism and structural plasticity of the bradykinin receptor and PAM, we used the three commercially available ACEIs captopril, enalaprilat, and lisinopril for our studies. An important result of this thesis is that though enalaprilat, captopril, and lisinopril all have similar functional properties in humans, each one regulates the orthosteric binding site of hB1R in a unique way. These findings provide atomic insights into the allosteric modulation of the bradykinin receptor. This study along with the effects of ACEI on the binding sites of receptors also deciphers the effects of the Zn2+ as well as the crosstalk between zinc binding sites and ACEI compounds. The binding of allosteric modulators induces distinct endogenous binding, which might aid in creating new possibilities in the pharmaceutical field.
Chromosomal translocations (CTs) are a genetic hallmark of cancer. They could be identified as recurrent genetic aberrations in hemato-malignancies and solid tumors. More than 40% of all "cancer genes" were identified in recurrent CTs. Most of these CTs result in the production of oncofusion proteins of which many have been studied over the past decades. They influence signaling pathways and/or alter gene expression. However, a precise mechanism for how these CTs arise and occur in a nearly identical fashion in individuals remains to be elucidated. Here, we performed experiments that explain the onset of CTs: proximity of genes able to produce prematurely terminated transcripts, which leads to the production of transspliced fusion RNAs, and finally, the induction of DNA double-strand breaks which are subsequently repaired via EJ repair pathways. Under these conditions, balanced chromosomal translocations could be specifically induced.
The lung tumor microenvironment plays a critical role in the tumorigenesis and metastasis of lung cancer, resulting from the crosstalk between cancer cells and microenvironmental cells. Therefore, comprehensive identification and characterization of cell populations in the complex lung structure is crucial for development of novel targeted anti-cancer therapies. Here, a hierarchical clustering approach with multispectral flow cytometry was established to delineate the cellular landscape of murine lungs under steady-state and cancer conditions. Fluorochromes were used multiple times to be able to measure 24 cell surface markers with only 13 detectors, yielding a broad picture for whole-lung phenotyping. Primary and metastatic murine lung tumor models were included to detect major cell populations in the lung, and to identify alterations to the distribution patterns in these models. In the primary tumor models, major altered populations included CD324+ epithelial cells, alveolar macrophages, dendritic cells, and blood and lymph endothelial cells. The number of fibroblasts, vascular smooth muscle cells, monocytes (Ly6C+ and Ly6C–) and neutrophils were elevated in metastatic models of lung cancer. Thus, the proposed clustering approach is a promising method to resolve cell populations from complex organs in detail even with basic flow cytometers.
Riboswitch RNAs regulate gene expression by conformational changes induced by environmental conditions and specific ligand binding. The guanidine-II riboswitch is proposed to bind the small molecule guanidinium and to subsequently form a kissing loop interaction between the P1 and P2 hairpins. While an interaction was shown for isolated hairpins in crystallization and electron paramagnetic resonance experiments, an intrastrand kissing loop formation has not been demonstrated. Here, we report the first evidence of this interaction in cis in a ligand and Mg2+ dependent manner. Using single-molecule FRET spectroscopy and detailed structural information from coarse-grained simulations, we observe and characterize three interconvertible states representing an open and kissing loop conformation as well as a novel Mg2+ dependent state for the guanidine-II riboswitch from E. coli. The results further substantiate the proposed switching mechanism and provide detailed insight into the regulation mechanism for the guanidine-II riboswitch class. Combining single molecule experiments and coarse-grained simulations therefore provides a promising perspective in resolving the conformational changes induced by environmental conditions and to yield molecular insights into RNA regulation.
RNA research is very important since RNA molecules are involved in various gene regulatory mechanisms as well as pathways of cell physiology and disease development.1 RNAs have evolved from being considered as carriers of genetic information from DNA to proteins, with the three major types of RNA involved in protein synthesis, including messenger RNA (mRNA), transfer RNA (tRNA), and ribosomal RNA (rRNA).2 In addition to the RNAs involved in protein synthesis numerous regulatory non-coding RNAs (ncRNAs) have been discovered in the transcriptome. The regulatory ncRNAs are classified into small ncRNAs (sncRNAs) with transcripts less than 200 nucleotides (nt) and long non-coding RNAs (lncRNAs) with more than 200 nt.3
LncRNAs represent the most diverse and versatile class of ncRNAs that can regulate cellular functions of chromatin modification, transcription, and post-transcription through multiple mechanisms.4 They are involved in the formation of RNA:protein, RNA:RNA and RNA:DNA complexes as part of their gene regulatory mechanism.4,5 The RNA:DNA interactions can be divided into RNA:DNA heteroduplex formation, also called R-loops, and RNA:DNA:DNA triplex formation. In triplex formation, RNA binds to the major groove of double-stranded DNA through Hoogsteen or reverse Hoogsteen hydrogen bonding, resulting in parallel or anti-parallel triplexes, respectively. In vitro studies have confirmed the formation of RNA:DNA:DNA triplexes.6 However, the extent to which these interactions occur in cells and their effects on cellular function are still not understood, which is why these structures are so exciting to study (Chapter I RNA:DNA:DNA Triplexes).
This cumulative thesis investigates several functional and regulatory important RNAs. The first project involves the improved biochemical and biophysical characterization of RNA:DNA:DNA triplex formation between lncRNAs of interest and their target genes. Triplex formation was confirmed by a series of experiments including electromobility shift assays (EMSA), thermal melting assays, circular dichroism (CD), and liquid state nuclear magnetic resonance (NMR) spectroscopy. The following is a summary of the main findings of these publications.
In research article 5.1, the oxygen-sensitive HIF1α-AS1 was identified as a functionally important triplex-forming lncRNA in human endothelial cells using a combination of bioinformatics techniques, RNA/DNA pulldown, and biophysical experiments. Through RNA:DNA:DNA triplex formation, endogenous HIF1α-AS1 decreases the expression of several genes, including EPH receptor A2 (EPHA2) and adrenomedullin (ADM), by acting as an adaptor for the repressive human silencing hub (HUSH) complex, which has been studied by our collaborators in the groups of Leisegang and Brandes.
2) Triplex formation between HIF1α-AS1 and the target genes EPHA2 and ADM was investigated in biochemical and biophysical studies. The EMSA results indicated that HIF1α-AS1 forms a low mobility RNA:DNA:DNA triplex complex with the EPHA2 DNA target sequence. The CD spectrum of the triplex showed distinct features compared to the EPHA2 DNA duplex and the RNA:DNA heteroduplex. Melting curve analysis revealed a biphasic melting transition for triplexes, with a first melting point corresponding to the dissociation of the RNA strand with melting of the Hoogsteen hydrogen bonds. The second, higher melting temperature corresponds to the melting of stronger Watson-Crick base pairing. Stabilized triplexes were formed using an intramolecular EPHA2 DNA duplex hairpin construct in which both DNA strands were attached to a 5 nucleotide (nt) thymidine linker. This approach allowed improved triplex formation with lower RNA equivalents and higher melting temperatures. By NMR spectroscopy, the triplex characteristic signals were observed in the 1H NMR spectrum, the imino signals in a spectral region between 9 and 12 ppm resulting from the Hoogsteen base pairing. To elucidate the structural and sequence specific Hoogsteen base pairs 2D 1H,1H-NOESY measurements of the EPHA2 DNA duplex and the HIF1α-AS1:EPHA2 triplex were performed. The 1H,1H-NOESY spectrum of the HIF1α-AS1:EPHA2 triplex with a 10-fold excess of RNA was semi-quantitatively analyzed for changes in the DNA duplex spectrum. We discovered, strong and moderate attenuation of cross peak intensities in the imino region of the NOESY spectrum. This attenuation was proposed to result from weakening of Watson-Crick base pairing by Hoogsteen hydrogen bonding induced by RNA binding. The Hoogsteen interactions can be mapped based on the analysis of the cross peak attenuation in the NOESY spectra, which we used to generate a structural model of the RNA:DNA:DNA triplex. These biophysical results support the physiological function of HIF1α as a triplex-forming lncRNA that recruits the HUSH-epigenetic silencing complex to specific target genes such as EPHA2 and ADM, thereby silencing their gene expression through RNA:DNA:DNA triplex formation.
A key event in cellular physiology is the decision between membrane biogenesis and fat storage. Phosphatidic acid (PA) is an important intermediate at the branch point of these pathways and is continuously monitored by the transcriptional repressor Opi1 to orchestrate lipid metabolism. In this study, we report on the mechanism of membrane recognition by Opi1 and identify an amphipathic helix (AH) for selective binding of PA over phosphatidylserine (PS). The insertion of the AH into the membrane core renders Opi1 sensitive to the lipid acyl chain composition and provides a means to adjust membrane biogenesis. By rational design of the AH, we tune the membrane-binding properties of Opi1 and control its responsiveness in vivo. Using extensive molecular dynamics simulations, we identify two PA-selective three-finger grips that tightly bind the PA phosphate headgroup while interacting less intimately with PS. This work establishes lipid headgroup selectivity as a new feature in the family of AH-containing membrane property sensors.
A key event in cellular physiology is the decision between membrane biogenesis and fat storage. Phosphatidic acid (PA) is an important lipid intermediate and signaling lipid at the branch point of these pathways and constantly monitored by the transcriptional repressor Opi1 to orchestrate lipid metabolism. Here, we report on the mechanism of membrane recognition by Opi1 and identify an amphipathic helix (AH) for the selective binding to membranes containing PA over phosphatidylserine (PS). The insertion of the AH into the hydrophobic core of the membrane renders Opi1 sensitive to the lipid acyl chain composition as an important factor contributing to the regulation of membrane biogenesis. Based on these findings, we rationally designed the membrane binding properties of Opi1 to control its responsiveness in the physiological context. Using extensive molecular dynamics (MD) simulations, we identified two PA-selective three-finger grips that tightly bind the phosphate headgroup, while interacting less intimately and more transiently with PS. This work establishes lipid headgroup selectivity as a new feature in the family of AH-containing membrane property sensors.
RNA sequencing analyses are often limited to identifying lowest p value transcripts, which does not address polygenic phenomena. To overcome this limitation, we developed an integrative approach that combines large-scale transcriptomic meta-analysis of patient brain tissues with single-cell sequencing data of CNS neurons, short RNA sequencing of human male- and female-originating cell lines, and connectomics of transcription factor and microRNA interactions with perturbed transcripts. We used this pipeline to analyze cortical transcripts of schizophrenia and bipolar disorder patients. Although these pathologies show massive transcriptional parallels, their clinically well-known sexual dimorphisms remain unexplained. Our method reveals the differences between afflicted men and women and identifies disease-affected pathways of cholinergic transmission and gp130-family neurokine controllers of immune function interlinked by microRNAs. This approach may open additional perspectives for seeking biomarkers and therapeutic targets in other transmitter systems and diseases.
RNA-sequencing analyses are often limited to identifying lowest p-value transcripts, which does not address polygenic phenomena. To overcome this limitation, we developed an integrative approach that combines large scale transcriptomic meta-analysis of patient brain tissues with single-cell sequencing data of CNS neurons, short RNA-sequencing of human male- and female-originated cell lines, and connectomics of transcription factor- and microRNA-interactions with perturbed transcripts. We used this pipeline to analyze cortical transcripts of schizophrenia and bipolar disorder patients. While these pathologies show massive transcriptional parallels, their clinically well-known sexual dimorphisms remain unexplained. Our method explicates the differences between afflicted men and women, and identifies disease-affected pathways of cholinergic transmission and gp130-family neurokine controllers of immune function, interlinked by microRNAs. This approach may open new perspectives for seeking biomarkers and therapeutic targets, also in other transmitter systems and diseases.
The SLC26 family of transporters maintains anion equilibria in all kingdoms of life. The family shares a 7 + 7 transmembrane segments inverted repeat architecture with the SLC4 and SLC23 families, but holds a regulatory STAS domain in addition. While the only experimental SLC26 structure is monomeric, SLC26 proteins form structural and functional dimers in the lipid membrane. Here we resolve the structure of an SLC26 dimer embedded in a lipid membrane and characterize its functional relevance by combining PELDOR/DEER distance measurements and biochemical studies with MD simulations and spin-label ensemble refinement. Our structural model reveals a unique interface different from the SLC4 and SLC23 families. The functionally relevant STAS domain is no prerequisite for dimerization. Characterization of heterodimers indicates that protomers in the dimer functionally interact. The combined structural and functional data define the framework for a mechanistic understanding of functional cooperativity in SLC26 dimers.
Membrane receptor clustering is fundamental to cell–cell communication; however, the physiological function of receptor clustering in cell signaling remains enigmatic. Here, we developed a dynamic platform to induce cluster formation of neuropeptide Y2 hormone receptors (Y2R) in situ by a chelator nanotool. The multivalent interaction enabled a dynamic exchange of histidine-tagged Y2R within the clusters. Fast Y2R enrichment in clustered areas triggered ligand-independent signaling as determined by an increase in cytosolic calcium and cell migration. Notably, the calcium and motility response to ligand-induced activation was amplified in preclustered cells, suggesting a key role of receptor clustering in sensitizing the dose response to lower ligand concentrations. Ligand-independent versus ligand-induced signaling differed in the binding of arrestin-3 as a downstream effector, which was recruited to the clusters only in the presence of the ligand. This approach allows in situ receptor clustering, raising the possibility to explore different receptor activation modalities.
Membrane receptors are central to cell-cell communication. Receptor clustering at the plasma membrane modulates physiological responses, and mesoscale receptor organization is critical for downstream signaling. Spatially restricted cluster formation of the neuropeptide Y2 hormone receptor (Y2R) was observed in vivo; however, the relevance of this confinement is not fully understood. Here, we controlled Y2R clustering in situ by a chelator nanotool. Due to the multivalent interaction, we observed a dynamic exchange in the microscale confined regions. Fast Y2R enrichment in clustered areas triggered a ligand-independent downstream signaling determined by an increase in cytosolic calcium, cell spreading, and migration. We revealed that the cell response to ligand-induced activation was amplified when cells were pre-clustered by the nanotool. Ligand-independent signaling by clustering differed from ligand-induced activation in the binding of arrestin-3 as downstream effector, which was recruited to the confined regions only in the presence of the ligand. This approach enables in situ clustering of membrane receptors and raises the possibility to explore different modalities of receptor activation.
The introduction of a trigonal boron atom into a polyaromatic hydrocarbon (PAH) core is an extremely powerful tool to provide organic scaffolds with optoelectronic properties as well as optimal packing in the solid state. However, boron-doped PAHs (B-PAHs) often display low processability due to their poor solubility. The distortion of the molecular scaffold provides a suitable strategy to enhance the solubility properties of B-PAHs while maintaining good stacking properties and sufficient electronic conjugation.
Extreme distortion of the molecular structure can be achieved in helical-shaped PAHs, namely helicenes which are screw-shaped inherently chiral polycycles, formed by ortho-fused aromatic or heteroaromatic rings. The presence of a helical structure in B-PAHs is expected to strongly influence their physico-chemical properties leading to compounds characterized by peculiar features promising for applications in next generation functional materials. Despite the great potential of this class of compounds, only few examples of borahelicenes have been reported in the literature and those mainly consist of carbohelicene-based structures. However, the considerable structural diversity achievable by introducing different boraheterocycles (oxaborine, borole, borepin) and other heteroaromatic rings (thiophene, furan, pyrrole) into the same helical scaffold, suggests that a large variety of compounds with intriguing features could be accessible via currently unexplored synthetic routes. The design, synthesis, and properties investigation of new boraheterohelicenes (BHHs) is therefore a relevant research topic and is the object of this PhD project, aimed to obtain several BHHs with structural diversity, as well as to study their reactivity, electrochemical and photophysical features for better understanding their potential as building blocks for material science.
The thesis work was carried out in part at the University of Milan in the laboratories of Prof. Emanuela Licandro and in part at the Goethe Universität Frankfurt am Main under the supervision of Prof. Dr. Matthias Wagner, within a co-tutelle programme. Owing to the long-standing expertise of Prof. Licandro group in the synthesis of tetrathia helicenes and that of Prof. Dr. Wagner group in the synthesis of boron-doped PAHs (e.g. boron helicene 4BH; Figure 1), I conceived this PhD project designing a series of thiahelicenes containing one or more B-O bond into the helical scaffold.Tetrathia helicenes, consisting of thiophene and benzene rings fused in an alternating fashion, are configurationally stable heterohelicenes which exist as pair of enantiomers.
This class of molecules is particularly interesting since it merges the properties of oligothiophenes with those of helicenes, giving rise to systems with peculiar electronic and chiroptical properties which make them appealing building blocks for applications in manifold fields of science, including optoelectronics, catalysis and biology.
The introduction of trigonal boron atom into a thiahelicene scaffold gives rise to a novel class of unexplored boron π-conjugated molecules with potentially interesting features.
The present Ph.D. thesis was therefore intended to provide a meaningful contribution in the development of innovative and versatile syntheses of BO-doped tetrathia helicenes as well as the study of their stereochemical and optoelectronic properties to identify potential applications of these systems in material science. The first selected structures containing one or two oxaborine rings in the helical scaffold are shown in figure 2. The presence of the bulky mesityl group at the boron atom is necessary to ensure stability to the molecule.
It is noteworthy that compound 2 is the skeletal isomer of 1, as the direction of the B-O bond is opposite in the two molecules. In the course of the research work, after the evaluation of the photophysical properties of 1, helicene 2 was designed to get information on the structure-property relationship and evaluate how the position of the BO-bond into the helical scaffold can influence the electronic properties of BO-doped thiahelicenes.