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Imaging non-adherent cells by super-resolution far-field fluorescence microscopy is currently not possible because of their rapid movement while in suspension. Holographic optical tweezers (HOTs) enable the ability to freely control the number and position of optical traps, thus facilitating the unrestricted manipulation of cells in a volume around the focal plane. Here we show that immobilizing non-adherent cells by optical tweezers is sufficient to achieve optical resolution well below the diffraction limit using localization microscopy. Individual cells can be oriented arbitrarily but preferably either horizontally or vertically relative to the microscope’s image plane, enabling access to sample sections that are impossible to achieve with conventional sample preparation and immobilization. This opens up new opportunities to super-resolve the nanoscale organization of chromosomal DNA in individual bacterial cells.
The 3,5-methoxy groups in the title compound, C16H23NO4, are almost coplanar with the aromatic ring, whereas the 4-methoxy group is bent out of this plane. The three CH3—O—C—C torsion angles are -1.51 (18), 0.73 (19) and 75.33 (15)°. The cyclohexane ring adopts a chair conformation. In the crystal, molecules are connected by intermolecular N—H ... O hydrogen bonds into chains running along the b axis.
The crystal packing of the title compound, C13H19NO·0.33C7H8, shows a channel at [001], which contains grossly disordered toluene solvent molecules. The angle between the benzene ring and the mean plane of the formamide group is 71.1 (1)°. The amide groups of neighbouring molecules are connected by N—H(...)O hydrogen bonds, forming 21 helical chains propagating along [001]. Molecules are also connected by weak intermolecular C—H(...)O hydrogen bonds, forming 61 helices.
The title compound, [Li3(C4F9O)3(C3H6O)3], features an open Li/O cube with an Li ion missing at one corner. Three of the four bridging O atoms of the cube carry a fluorinated tert-butyl residue, whereas the fourth is part of an acetone molecule. Two of the Li atoms are further bonded to a non-bridging acetone molecule. Two of the lithium ion coordination geometries are very distorted LiO4 tetrahedra; the third could be described as a very distorted LiO3 T-shape with two distant F-atom neighbours. The Li[cdots, three dots, centered]Li contact distances for the three-coordinate Li+ ion [2.608 (14) and 2.631 (12) Å] are much shorter that the contact distance [2.940 (13) Å] between the tetrahedrally coordinated species.
The von Willebrand factor (VWF) is a glycoprotein in the blood that plays a central role in hemostasis. Among other functions, VWF is responsible for platelet adhesion at sites of injury via its A1 domain. Its adjacent VWF domain A2 exposes a cleavage site under shear to degrade long VWF fibers in order to prevent thrombosis. Recently, it has been shown that VWF A1/A2 interactions inhibit the binding of platelets to VWF domain A1 in a force-dependent manner prior to A2 cleavage. However, whether and how this interaction also takes place in longer VWF fragments as well as the strength of this interaction in the light of typical elongation forces imposed by the shear flow of blood remained elusive. Here, we addressed these questions by using single molecule force spectroscopy (SMFS), Brownian dynamics (BD), and molecular dynamics (MD) simulations. Our SMFS measurements demonstrate that the A2 domain has the ability to bind not only to single A1 domains but also to VWF A1A2 fragments. SMFS experiments of a mutant [A2] domain, containing a disulfide bond which stabilizes the domain against unfolding, enhanced A1 binding. This observation suggests that the mutant adopts a more stable conformation for binding to A1. We found intermolecular A1/A2 interactions to be preferred over intramolecular A1/A2 interactions. Our data are also consistent with the existence of two cooperatively acting binding sites for A2 in the A1 domain. Our SMFS measurements revealed a slip-bond behavior for the A1/A2 interaction and their lifetimes were estimated for forces acting on VWF multimers at physiological shear rates using BD simulations. Complementary fitting of AFM rupture forces in the MD simulation range adequately reproduced the force response of the A1/A2 complex spanning a wide range of loading rates. In conclusion, we here characterized the auto-inhibitory mechanism of the intramolecular A1/A2 bond as a shear dependent safeguard of VWF, which prevents the interaction of VWF with platelets.
The core of photosystem I (PS1) is composed of the two related integral membrane polypeptides, PsaA and PsaB, which bind two symmetrical branches of cofactors, each consisting of two chlorophylls and a phylloquinone, that potentially link the primary electron donor and the tertiary acceptor. In an effort to identify amino acid residues near the phylloquinone binding sites, all tryptophans and histidines that are conserved between PsaA and PsaB in the region of the 10th and 11th transmembrane alpha-helices were mutated in Chlamydomonas reinhardtii. The mutant PS1 reaction centers appear to assemble normally and possess photochemical activity. An electron paramagnetic resonance (EPR) signal attributed to the phylloquinone anion radical (A(1)(-)) can be observed either transiently or after illumination of reaction centers with pre-reduced iron-sulfur clusters. Mutation of PsaA-Trp(693) to Phe resulted in an inability to photo-accumulate A(1)(-), whereas mutation of the analogous tryptophan in PsaB (PsaB-Trp(673)) did not produce this effect. The PsaA-W693F mutation also produced spectral changes in the time-resolved EPR spectrum of the P(700)(+) A(1)(-) radical pair, whereas the analogous mutation in PsaB had no observable effect. These observations indicate that the A(1)(-) phylloquinone radical observed by EPR occupies the phylloquinone-binding site containing PsaA-Trp(693). However, mutation of either tryptophan accelerated charge recombination from the terminal Fe-S clusters.
The cytochrome bc1 complex is a dimeric enzyme of the inner mitochondrial membrane that links electron transfer from ubiquinol to cytochrome c by a protonmotive Q cycle mechanism in which ubiquinol is oxidized at one center in the enzyme, referred to as center P, and ubiquinone is rereduced at a second center, referred to as center N. To better understand the mechanism of ubiquinol oxidation, we have examined catalytic activities and pre-steady-state reduction kinetics of yeast cytochrome bc1 complexes with mutations in cytochrome b that we expected would affect oxidation of ubiquinol. We mutated two residues thought to be involved in proton conduction linked to ubiquinol oxidation, Tyr132 and Glu272, and two residues proposed to be involved in docking ubiquinol into the center P pocket, Phe129 and Tyr279. Substitution of Phe129 by lysine or arginine yielded a respiration-deficient phenotype and lipid-dependent catalytic activity. Increased bypass reactions were detectable for both variants, with F129K showing the more severe effects. Substitution with lysine leads to a disturbed coordination of a b heme as deduced from changes in the midpoint potential and the EPR signature. Removal of the aromatic side chain in position Tyr279 lowers the catalytic activity accompanied by a low level of bypass reactions. Pre-steady-state kinetics of the enzymes modified at Glu272 and Tyr132 confirmed the importance of their functional groups for electron transfer. Altered center N kinetics and activation of ubiquinol oxidation by binding of cytochrome c in the Y132F and E272D enzymes indicate long range effects of these mutations.
The effect of a single site mutation of Arg-54 to methionine in Paracoccus denitrificans cytochrome c oxidase was studied using a combination of optical spectroscopy, electrochemical and rapid kinetics techniques, and time-resolved measurements of electrical membrane potential. The mutation resulted in a blue-shift of the heme a alpha-band by 15 nm and partial occupation of the low-spin heme site by heme O. Additionally, there was a marked decrease in the midpoint potential of the low-spin heme, resulting in slow reduction of this heme species. A stopped-flow investigation of the reaction with ferrocytochrome c yielded a kinetic difference spectrum resembling that of heme a(3). This observation, and the absence of transient absorbance changes at the corresponding wavelength of the low-spin heme, suggests that, in the mutant enzyme, electron transfer from Cu(A) to the binuclear center may not occur via heme a but that instead direct electron transfer to the high-spin heme is the dominating process. This was supported by charge translocation measurements where Deltapsi generation was completely inhibited in the presence of KCN. Our results thus provide an example for how the interplay between protein and cofactors can modulate the functional properties of the enzyme complex.
Many interesting and important membrane proteins are hetero-oligomeric. However, besides naturally abundant examples, the structures of relatively few such complexes are known. Partly, this is due to difficulties in expression, stoichiometric assembly, and in the evaluation of their stability prior to crystallization trials. Here we describe a new approach, which allows rapid assessment of protein complex quality, assembly and stoichiometry, simplifying the search for conditions conducive to long-term stability and crystallization. Multicolour fluorescence size-exclusion chromatography (MC-FSEC) is used to enable tracking of individual subunits through expression, solubilization and purification steps. We show how the method has been applied to the heterodimeric transporter associated with antigen processing (TAP) and demonstrate how it may be extended in order to analyse membrane multisubunit assemblies.
Prostaglandin E2 (PGE2) favors multiple aspects of tumor development and immune evasion. Therefore, microsomal prostaglandin E synthase (mPGES-1/-2), is a potential target for cancer therapy. We explored whether inhibiting mPGES-1 in human and mouse models of breast cancer affects tumor-associated immunity. A new model of breast tumor spheroid killing by human PBMCs was developed. In this model, tumor killing required CD80 expression by tumor-associated phagocytes to trigger cytotoxic T cell activation. Pharmacological mPGES-1 inhibition increased CD80 expression, whereas addition of PGE2, a prostaglandin E2 receptor 2 (EP2) agonist, or activation of signaling downstream of EP2 reduced CD80 expression. Genetic ablation of mPGES-1 resulted in markedly reduced tumor growth in PyMT mice. Macrophages of mPGES-1-/- PyMT mice indeed expressed elevated levels of CD80 compared to their wildtype counterparts. CD80 expression in tumor-spheroid infiltrating mPGES-1-/- macrophages translated into antigen-specific cytotoxic T cell activation. In conclusion, mPGES-1 inhibition elevates CD80 expression by tumor-associated phagocytes to restrict tumor growth. We propose that mPGES-1 inhibition in combination with immune cell activation might be part of a therapeutic strategy to overcome the immunosuppressive tumor microenvironment.
Molecular recognition of M1-linked ubiquitin chains by native and phosphorylated UBAN domains
(2019)
Although the Ub-binding domain in ABIN proteins and NEMO (UBAN) is highly conserved, UBAN-containing proteins exhibit different Ub-binding properties, resulting in their diverse biological roles. Post-translational modifications further control UBAN domain specificity for poly-Ub chains. However, precisely, how the UBAN domain structurally confers such functional diversity remains poorly understood. Here we report crystal structures of ABIN-1 alone and in complex with one or two M1-linked di-Ub chains. ABIN-1 UBAN forms a homo-dimer that provides two symmetrical Ub-binding sites on either side of the coiled-coil structure. Moreover, crystal structures of ABIN1 UBAN in complex with di-Ub chains reveal a concentration-dependency of UBAN/di-Ub binding stoichiometry. Analysis of UBAN/M1-linked di-Ub binding characteristics indicates that phosphorylated S473 in OPTN and its corresponding phospho-mimetic residue in ABIN-1 (E484) are essential for high affinity interactions with M1-linked Ub chains. Also, a phospho-mimetic mutation of A303 in NEMO, corresponding to S473 of OPTN, increases binding affinity for M1-linked Ub chains. These findings are in line with the diverse physiological roles of UBAN domains, as phosphorylation of OPTN UBAN is required to enhance its binding to Ub during mitophagy.
Fibroblast growth factor receptor substrate 2 (FRS2α) is a signaling adaptor protein that regulates downstream signaling of many receptor tyrosine kinases. During signal transduction, FRS2 can be both tyrosine and threonine phosphorylated and forms signaling complexes with other adaptor proteins and tyrosine phosphatases. We have here identified flotillin-1 and the cbl-associated protein/ponsin (CAP) as novel interaction partners of FRS2. Flotillin-1 binds to the phosphotyrosine binding domain (PTB) of FRS2 and competes for the binding with the fibroblast growth factor receptor. Flotillin-1 knockdown results in increased Tyr phosphorylation of FRS2, in line with the inhibition of ERK activity in the absence of flotillin-1. CAP directly interacts with FRS2 by means of its sorbin homology (SoHo) domain, which has previously been shown to interact with flotillin-1. In addition, the third SH3 domain in CAP binds to FRS2. Due to the overlapping binding domains, CAP and flotillin-1 appear to compete for the binding to FRS2. Thus, our results reveal a novel signaling network containing FRS2, CAP and flotillin-1, whose successive interactions are most likely required to regulate receptor tyrosine kinase signaling, especially the mitogen activated protein kinase pathway.
Transcription factor IIS (TFIIS) is a protein known for catalyzing the cleavage reaction of the 3′-end of backtracked RNA transcript, allowing RNA polymerase II (Pol II) to reactivate the transcription process from the arrested state. Recent structural studies have provided a molecular basis of protein-protein interaction between TFIIS and Pol II. However, the detailed dynamic conformational changes of TFIIS upon binding to Pol II and the related thermodynamic information are largely unknown. Here we use computational approaches to investigate the conformational space of TFIIS in the Pol II-bound and Pol II-free (unbound) states. Our results reveal two distinct conformations of TFIIS: the closed and the open forms. The closed form is dominant in the Pol II-free (unbound) state of TFIIS, whereas the open form is favorable in the Pol II-bound state. Furthermore, we discuss the free energy difference involved in the conformational changes between the two forms in the presence or absence of Pol II. Additionally, our analysis indicates that hydrophobic interactions and the protein-protein interactions between TFIIS and Pol II are crucial for inducing the conformational changes of TFIIS. Our results provide novel insights into the functional interplay between Pol II and TFIIS as well as mechanism of reactivation of Pol II transcription by TFIIS.
Na+/H+ antiporters are integral membrane proteins that are present in almost every cell and in every kingdom of life. They are essential for the regulation of intracellular pH-value, Na+-concentration and cell volume. These secondary active transporters exchange sodium ions against protons via an alternating access mechanism, which is not understood in full detail. Na+/H+ antiporters show distinct species-specific transport characteristics and regulatory properties that correlate with respective physiological functions. Here we present the characterization of the Na+/H+ antiporter NhaA from Salmonella enterica serovar Thyphimurium LT2, the causing agent of food-born human gastroenteritis and typhoid like infections. The recombinant antiporter was functional in vivo and in vitro. Expression of its gene complemented the Na+-sensitive phenotype of an E. coli strain that lacks the main Na+/H+ antiporters. Purified to homogeneity, the antiporter was a dimer in solution as accurately determined by size-exclusion chromatography combined with multi-angle laser-light scattering and refractive index monitoring. The purified antiporter was fully capable of electrogenic Na+(Li+)/H+-antiport when reconstituted in proteoliposomes and assayed by solid-supported membrane-based electrophysiological measurements. Transport activity was inhibited by 2-aminoperimidine. The recorded negative currents were in agreement with a 1Na+(Li+)/2H+ stoichiometry. Transport activity was low at pH 7 and up-regulation above this pH value was accompanied by a nearly 10-fold decrease of KmNa (16 mM at pH 8.5) supporting a competitive substrate binding mechanism. K+ does not affect Na+ affinity or transport of substrate cations, indicating that selectivity of the antiport arises from the substrate binding step. In contrast to homologous E. coli NhaA, transport activity remains high at pH values above 8.5. The antiporter from S. Typhimurium is a promising candidate for combined structural and functional studies to contribute to the elucidation of the mechanism of pH-dependent Na+/H+ antiporters and to provide insights in the molecular basis of species-specific growth and survival strategies.
Methanogenic archaea share one ion gradient forming reaction in their energy metabolism catalyzed by the membrane-spanning multisubunit complex N5-methyl-tetrahydromethanopterin: coenzyme M methyltransferase (MtrABCDEFGH or simply Mtr). In this reaction the methyl group transfer from methyl-tetrahydromethanopterin to coenzyme M mediated by cobalamin is coupled with the vectorial translocation of Na+ across the cytoplasmic membrane. No detailed structural and mechanistic data are reported about this process. In the present work we describe a procedure to provide a highly pure and homogenous Mtr complex on the basis of a selective removal of the only soluble subunit MtrH with the membrane perturbing agent dimethyl maleic anhydride and a subsequent two-step chromatographic purification. A molecular mass determination of the Mtr complex by laser induced liquid bead ion desorption mass spectrometry (LILBID-MS) and size exclusion chromatography coupled with multi-angle light scattering (SEC-MALS) resulted in a (MtrABCDEFG)3 heterotrimeric complex of ca. 430 kDa with both techniques. Taking into account that the membrane protein complex contains various firmly bound small molecules, predominantly detergent molecules, the stoichiometry of the subunits is most likely 1:1. A schematic model for the subunit arrangement within the MtrABCDEFG protomer was deduced from the mass of Mtr subcomplexes obtained by harsh IR-laser LILBID-MS.
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.
Das Enzym 5-Lipoxygenase (5-LO) spielt eine entscheidende Rolle in der Generierung von Leukotrienen. Diese fungieren als wichtige proinflammatorische Mediatoren. Darüber hinaus ist die 5-LO anhand ihrer N-terminalen Domäne in der Lage mit verschiedenen Proteinen zu interagieren. Unter den Interaktionspartnern befindet sich Dicer, ein Enzym welches für den finalen Schritt der microRNA (miRNA)-Biosynthese verantwortlich ist. MiRNA sind kurze, nicht kodierende RNA Stränge mit einer typischen Länge von etwa 23 Nukleotiden, die an der posttranskriptionalen Regulierung der Proteinbiosynthese beteiligt sind.
Ziel dieser Arbeit war es den Einfluss der 5-LO auf die miRNA-Prozessierung im zellulären Kontext zu untersuchen. Als Modellsystem wurde die MonoMac6 (MM6) Zelllinie ausgewählt. MM6-Zellen exprimieren im undifferenzierten Grundzustand nur geringe Mengen an 5-LO. Erst nach Differenzierung mittels transformierenden Wachstumsfaktors ß (TGFß) und Calcitriol kommt es zur Induktion der 5-LO Proteinbiosynthese. Darüber hinaus war es Basavarajappa et al. möglich die 5-LO-Expression in diesen Zellen mittels RNA-Interferenz stark herunter zu regulieren (Δ5-LO).
Um die Frage der Auswirkungen des 5-LO knockdowns auf die miRNA-Expression analysieren zu können, wurde ein Microarray in differenzierten Kontroll-und Δ5-LO-Zellen durchgeführt.Es wurden 37 miRNAs identifiziert deren Expression 5-LO abhängig ist. Dabei war das Niveau von 30 Vertretern in Abwesenheit der 5-LO erhöht, wohingegen die Expression von sieben miRNAs reduziert war. Unter diesen sieben herunter regulierten miRNAs befanden sich miR-99b-5p und miR-125a-5p, die einem gemeinsamen Cluster entstammen. Als Cluster wird eine Gruppe von miRNAs bezeichnet, die aus einem gemeinsamen primären Transkript (pri-miRNA) hervorgeht. Diese Eigenschaft führte zur Vermutung, dass bereits die Expression dieser pri-miRNA durch die 5-LO reguliert wird. Allerdings zeigte sichim Verlauf dieser Arbeit, dass die Expression der pri-miRNA 5-LO unabhängig verläuft. Im Gegensatz dazu wies die Zwischenstufe zwischen pri-miRNA und reifer miRNA eine reduzierte Expression in Δ5-LO Zellen auf. Für die Prozessierung dieser sogenannten precursor miRNAs (pre-miRNA) ist die Ribonuklease III Drosha verantwortlich, welche die pre-miRNA aus der jeweiligen pri-miRNAs chneidet. Das verringerte pre-miR-99b-und pre-miR-125a-Niveau ist daher ein Hinweis darauf, dass überDicerhinausmöglicherweise ebenfalls die Drosha Aktivität mittels 5-LO reguliert wird.
Des Weiteren wurde untersucht iniefern Leukotriene beziehungsweise 5-LO-Inhibitoren die Expression von miR-99b-5p und miR-125a-5p beeinflussen. Dabei stellte sich heraus, dass das miRNA-Niveau unabhängig von der vorhandenen Leukotrien-Menge ist. Das 5-LO aktivierende Protein (FLAP) besitzt dahingegen einen mit der 5-LO vergleichbaren Einfluss auf die reife miRNA. FLAP ist ein weiterer Interaktionspartner der 5-LO und essentiell für die Leukotrien-Biosynthese in vivo. Anhand von Protein-Lokalisationsstudien mittels Immunofluoreszenz konnte gezeigt werden, dass FLAP außerdem in der Lage zu sein scheint die Relokalisation der 5-LO aus dem Zytoplasma in den Nukleus einzuschränken. Im Zytoplasma ist die 5-LO in der Lage mit Dicer zu interagieren. Daten bezüglich einer Interaktion zwischen Drosha und 5-LO im Zellkern liegen bisher nicht vor. Eine etwaige Interaktion könnte allerdings helfen die reduzierten pre-miRNA Spiegel in Abwesenheit der 5-LO zu erklären.
Im Laufe dieser Arbeit wurden weiterhin die Auswirkungen von proinflammatorischen Lipopolysacchariden (LPS) auf die Prozessierung von miR-99b-5p und miR-125a-5p analysiert. Ausschließlich in Anwesenheit von 5-LO zeigte sich eine differenzierungsunabhängig gesteigerte Biosynthese der pri-und der reifen miRNA. Allerdings konnte kein Einfluss von LPS auf die 5-LO-Lokalisation beziehungsweise Expression festgestellt werden. Aufgrund dessen sind weiterführende Studien, die den Zusammenhang zwischen LPS induzierter miR-99b-5p- beziehungsweise miR-125a-5p-Biosynthese und 5-LO herstellen, nötig.
Abschließend hat sich diese Arbeit mit den Zielgenen der durch 5-LO regulierten miRNAs auseinandergesetzt. Es konnte gezeigt werden, dass in Abwesenheit von miR-99b-5p und miR-125a-5p die Freisetzung der beiden durch LPS stimulierten Zytokine Interleukin 6 (IL-6) und Tumornekrosefaktor α (TNFα) gesteigert ist. Interessanterweise besitzt TNFα einen stimulierenden Effekt auf die Leukotrien-Biosynthese. Allerdings konnte kein direkter Zusammenhang zwischen miR-99b-5p/miR-125a-5p Expression, TNFα und der 5-LO Aktivität hergestellt werden. Der Einsatz von miR-99b-5p-und miR-125a-5p-Inhibitoren zeigte keine Auswirkungen auf die Leukotrien-Biosynthese nach LPS Stimulation. Im Gegensatz dazu konnte in unstimulierten Zellen eine signifikante Aktivitätssteigerung in Abwesenheit von miR-125a-5p festgestellt werden. Diese Beobachtungen legen nahe, dass miR-125a-5p einen TNFα unabhängigen Einfluss auf die 5-LO Aktivität besitzt. In LPS stimulierten Zellen kommt es möglicherweise zu Überlagerungen dieses Effektes.
Zusammenfassend konnte in dieser Arbeit gezeigt werden, dass 5-LO eine regulierende Funktion auf die Reifung der beiden miRNAs miR-99b-5p und miR-125a-5p aufweist. Dieser Effekt könnte einer direkten Interaktion zwischen 5-LO und Dicer zuzuschreiben sein. Des Weiteren konnte gezeigt werden, dass die Regulierung der Expression bestimmter miRNAs mittels 5-LO nicht auf deren kanonischer enzymatischer Aktivität beruht. Diese Ergebnisse schlagen eine neue Richtung der 5-LO-Forschung ein und können in Zukunft dazu beitragen 5-LO vermittelte Effekte besser charakterisieren zu können.
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.
Drug-induced liver injury (DILI) has become a major problem for patients and for clinicians, academics and the pharmaceutical industry. To date, existing hepatotoxicity test systems are only poorly predictive and the underlying mechanisms are still unclear. One of the factors known to amplify hepatotoxicity is the tumor necrosis factor alpha (TNFα), especially due to its synergy with commonly used drugs such as diclofenac. However, the exact mechanism of how diclofenac in combination with TNFα induces liver injury remains elusive. Here, we combined time-resolved immunoblotting and live-cell imaging data of HepG2 cells and primary human hepatocytes (PHH) with dynamic pathway modeling using ordinary differential equations (ODEs) to describe the complex structure of TNFα-induced NFκB signal transduction and integrated the perturbations of the pathway caused by diclofenac. The resulting mathematical model was used to systematically identify parameters affected by diclofenac. These analyses showed that more than one regulatory module of TNFα-induced NFκB signal transduction is affected by diclofenac, suggesting that hepatotoxicity is the integrated consequence of multiple changes in hepatocytes and that multiple factors define toxicity thresholds. Applying our mathematical modeling approach to other DILI-causing compounds representing different putative DILI mechanism classes enabled us to quantify their impact on pathway activation, highlighting the potential of the dynamic pathway model as a quantitative tool for the analysis of DILI compounds.
Air pollution of particulate matter (PM) from traffic emissions has a significant impact on human health. Risk assessments for different traffic participants are often performed on the basis of data from local air quality monitoring stations. Numerous studies demonstrated the limitation of this approach. To assess the risk of PM exposure to a car driver more realistically, we measure the exposure to PM in a car cabin with a mobile aerosol spectrometer in Frankfurt am Main under different settings (local variations, opened versus a closed window) and compare it with data from stationary measurement. A video camera monitored the surroundings for potential PM source detection. In-cabin concentrations peaked at 508 µg m−3 for PM10, 133.9 µg m−3 for PM2.5, and 401.3 µg m−3 for coarse particles, and strongly depended on PM size and PM concentration in ambient air. The concentration of smaller particles showed low fluctuations, but the concentration of coarse particles showed high fluctuations with maximum values on busy roads. Several of these concentration peaks were assigned to the corresponding sources with characteristic particle size distribution profiles. The closure of the car window reduced the exposure to PM, and in particular to coarse particles. The mobile measured PM values differed significantly from stationary PM measures, although good correlations were computed for finer particles. Mobile rather than stationary measurements are essential to assess the risk of PM exposure for car passengers.
Mitochondria are important for cellular health and their dysfunction is linked to a variety of diseases, especially neurodegeneration. Thus, the renewal and degradation of dysfunctional mitochondria is crucial for the well-being of organisms. The selective digestion of damaged mitochondria via the lysosome (mitophagy), is the main pathway to do so.
In my dissertational work, I investigated the connection between protein misfolding, protein import into mitochondria and the degradation of mitochondria via mitophagy. Here, I present a new model for the initiation of mitophagy without collapse of the membrane potential. This model provides the link between protein import into mitochondria, stress signal transduction to the cytosol and the mitochondrial stress sensor PINK1. To comprehensively examine how mitophagy can be triggered, I performed a genome-wide CRISPR knockout screen utilizing the mitophagy reporter mitochondrial mKEIMA. Thereby, I observed numerous novel gene deletions that induce mitophagy. Prominently, I identified an accumulation of gene deletions of the protein import and of protein quality control factors. I validated several of those and examined HSPA9 (mitochondrial HSP70) and LONP1 (a mitochondrial matrix AAA protease) in more detail, regarding their effect on mitophagy and protein import. For this, I used an established fluorescence-based, mitochondrial-targeted EGFP, as well as a newly-developed pulsed-SILAC mass spectrometry approach (mePRODmt). Depletions of both genes resulted in reduced protein import and PINK1-dependent mitophagy. Strikingly, I did not observe any loss of mitochondrial membrane potential, which was hitherto believed to be essential for activation of PINK1-mediated mitophagy. Literature shows that certain mitochondrial stressors can also induce mitophagy without mitochondrial membrane depolarization, which I confirmed with my assays. Next, I characterized the impact of LONP1 and HSPA9 depletion, which are involved in proteostasis maintenance, and the mtHSP90 inhibitor GTPP on mitochondrial protein folding in more detail. GTPP treatment and LONP1 depletion both resulted in the accumulation of an insoluble protein fraction, as judged by proteomic analysis. This insoluble protein fraction enriched several components of the presequence translocase-associated motor PAM, including TIMM44. TIMM44 acts as a link between the translocon, the import pore of the inner mitochondrial membrane (TIM) complex and the PAM complex. Thus, I hypothesized that TIMM44 dissociates from the TIM complex upon protein folding stress, when it becomes part of the insoluble protein fraction. To validate this model, I measured the TIMM44 interactome upon proteostasis disturbance using proximity labeling. Indeed, interaction of TIMM44 with the import pore was almost completely abolished, explaining the loss of matrix-targeted import upon protein folding stress. From these findings, I reasoned that an import reduction mediated by the PAM complex would likely also inhibit the degradation of PINK1. Consistent with this hypothesis, I observed that mitophagy induced by HSPA9 or LONP1 deletion was prevented when PINK1 was genetically deleted. In comparison, non-processed PINK1 was stabilized on mitochondria in wild type cells when mitochondrial protein import was impaired. On this basis, I drew the conclusion that the loss of mitochondrial import was the stress signal, which leads to the stabilization of PINK1, as it could not be processed anymore via the inner mitochondrial membrane protease PARL. PINK1 auto-activates itself upon accumulation and signals to the cytosol that this mitochondrion is damaged. Mitophagy is subsequently initiated by the ubiquitin kinase activity of PINK1. As a result, the autophagy apparatus gets activated, damaged mitochondria are engulfed by a double membrane and removed via lysosomal digestion. This proposed model is, to the best of my knowledge, the first to provide an explanation for protein folding stress-induced and protein import inhibition-triggered mitophagy without mitochondrial depolarization. The model thus extends the PINK1/PARKIN-dependent mitophagy pathway to milder stresses and clears some of the open questions in the field. Furthermore, this work is also important, because protein misfolding stress and dysfunctional mitochondria are two hallmarks of neurodegeneration. In particular, mitochondrial protein import inhibition during Parkinson’s and Huntington disease might be driver of mitochondrial dysfunction. Hence, I hope and anticipate that the newly developed protein import method, mePRODmt, and the proposed model will be beneficial to further characterize underlying processes and to establish which factors prevent or drive these disorders on molecular level.
Mistakes in translation of messenger RNA into protein are clearly a detriment to the recombinant production of pure proteins for biophysical study or the biopharmaceutical market. However, they may also provide insight into mechanistic details of the translation process. Mistakes often involve the substitution of an amino acid having an abundant codon for one having a rare codon, differing by substitution of a G base by an A base, as in the case of substitution of a lysine (AAA) for arginine (AGA). In these cases one expects the substitution frequency to depend on the relative abundances of the respective tRNAs, and thus, one might expect frequencies to be similar for all sites having the same rare codon. Here we demonstrate that, for the ADP-ribosylation factor from yeast expressed in E. coli, lysine for arginine substitutions frequencies are not the same at the 9 sites containing a rare arginine codon; mis-incorporation frequencies instead vary from less than 1 to 16%. We suggest that the context in which the codons occur (clustering of rare sites) may be responsible for the variation. The method employed to determine the frequency of mis-incorporation involves a novel mass spectrometric analysis of the products from the parallel expression of wild type and codon-optimized genes in 15N and 14N enriched media, respectively. The high sensitivity and low material requirements of the method make this a promising technology for the collection of data relevant to other mis-incorporations. The additional data could be of value in refining models for the ribosomal translation elongation process.
A wide variety of enzymatic pathways that produce specialized metabolites in bacteria, fungi and plants are known to be encoded in biosynthetic gene clusters. Information about these clusters, pathways and metabolites is currently dispersed throughout the literature, making it difficult to exploit. To facilitate consistent and systematic deposition and retrieval of data on biosynthetic gene clusters, we propose the Minimum Information about a Biosynthetic Gene cluster (MIBiG) data standard.
Essentially any behavior in simple and complex animals depends on neuronal network function. Currently, the best-defined system to study neuronal circuits is the nematode Caenorhabditis elegans, as the connectivity of its 302 neurons is exactly known. Individual neurons can be activated by photostimulation of Channelrhodopsin-2 (ChR2) using blue light, allowing to directly probe the importance of a particular neuron for the respective behavioral output of the network under study. In analogy, other excitable cells can be inhibited by expressing Halorhodopsin from Natronomonas pharaonis (NpHR) and subsequent illumination with yellow light. However, inhibiting C. elegans neurons using NpHR is difficult. Recently, proton pumps from various sources were established as valuable alternative hyperpolarizers. Here we show that archaerhodopsin-3 (Arch) from Halorubrum sodomense and a proton pump from the fungus Leptosphaeria maculans (Mac) can be utilized to effectively inhibit excitable cells in C. elegans. Arch is the most powerful hyperpolarizer when illuminated with yellow or green light while the action spectrum of Mac is more blue-shifted, as analyzed by light-evoked behaviors and electrophysiology. This allows these tools to be combined in various ways with ChR2 to analyze different subsets of neurons within a circuit. We exemplify this by means of the polymodal aversive sensory ASH neurons, and the downstream command interneurons to which ASH neurons signal to trigger a reversal followed by a directional turn. Photostimulating ASH and subsequently inhibiting command interneurons using two-color illumination of different body segments, allows investigating temporal aspects of signaling downstream of ASH.
Experimental results are presented for 180 in silico designed octapeptide sequences and their stabilizing effects on the major histocompatibility class I molecule H-2Kb. Peptide sequence design was accomplished by a combination of an ant colony optimization algorithm with artificial neural network classifiers. Experimental tests yielded nine H-2Kb stabilizing and 171 nonstabilizing peptides. 28 among the nonstabilizing octapeptides contain canonical motif residues known to be favorable for MHC I stabilization. For characterization of the area covered by stabilizing and non-stabilizing octapeptides in sequence space, we visualized the distribution of 100,603 octapeptides using a self-organizing map. The experimental results present evidence that the canonical sequence motives of the SYFPEITHI database on their own are insufficient for predicting MHC I protein stabilization.
The knowledge of three-dimensional structures of biomolecules is fundamental for the understanding of their function. Nuclear magnetic resonance (NMR) spectroscopy represents besides X-ray crystallography one of the two most widely used techniques to study macromolecules at atomic resolution. Its application has long been a laborious task that could take months and required the expertise of an experienced scientist, however, owing to the tremendous effort that has been put into the development of respective computer algorithms, structure determination by NMR spectroscopy of small- to medium sized proteins is nowadays routinely performed. CYANA is one widely used software package, which combines the majority of individual steps towards a three-dimensional structure. The most common application of the program, however, restricts to the combined automated NOE assignment and structure calculation based on NOESY peak lists and an existing chemical shift assignment. Completely automated structure determination starting from NMR spectra is to date technically possible with CYANA, however, not yet routinely applied. In order to achieve this long-term goal, the individual steps need to become more robust with regard to data imperfections such as peak overlap, spectral artifacts or a limited amount of NMR data. The work presented in this thesis should be placed within the context of increasing the reliability and improving the accuracy of structures determined by CYANA on the basis of solution- as well as solid-state NMR data.
The chapter “Systematic evaluation of combined automated NOE assignment and structure calculation with CYANA” comprises an extensive study on the robustness of the combined automated NOE assignment and structure calculation algorithm based on experimental solution NMR data sets that were modified in multiple ways to mimic different kinds of data imperfections. The results show that the algorithm is remarkably robust with regard to imperfections of the NOESY peak lists and the chemical shift tolerances but susceptible to lacking or erroneous resonance assignments, in particular for nuclei that are involved in many NOESY cross peaks.
In the chapter “Peakmatch – A simple and robust tool for peaklist matching” a method to achieve self-consistency of the chemical shift referencing among a set of peak lists is presented. The Peakmatch algorithm matches a set of peak lists to a specified reference peak list, neither of which have to be assigned, by optimizing an assignment-free match-score function. The algorithm has been extensively tested on the basis of experimental NMR data sets of five different proteins. The results show that peak lists from many different types of spectra can be matched reliably as long as they contain at least two corresponding dimensions.
NMR structures are represented by bundles of conformers whose spread indicates the precision of the atomic coordinates. However, there is as yet no reliable measure of structural accuracy, i.e. how close NMR conformers are to the “true” structure. Instead, the precision of structure bundles is widely (mis)interpreted as a measure of structural quality. Attempts to increase the precision thus often yield tight structure bundles where the precision overestimates the accuracy. To overcome this problem, the chapter “Increased reliability of NMR protein structures by consensus structure bundles” introduces a new protocol for NMR structure determination with the software package CYANA that produces bundles of conformers with a realistic precision that is throughout a large number of test data sets a much better estimate of the structural accuracy than the precision of conventional structure bundles.
Solid-state NMR is a powerful technique to study molecules which are not amenable to either solution NMR or X-ray crystallography. Despite the reporting of individual atomic resolution structures of membrane proteins and amyloid fibrils based on solid-state NMR data, the application is far from routine. One major obstacle that hinders structure determination by solid-state NMR is the overall lower quality of the solid-state NMR spectra. It is therefore necessary to increase the robustness of the computer algorithms in order to improve the results when using lower quality solid-state NMR spectra. The chapter “Structure calculations of the model protein GB1 from solid-state NMR data” presents structure calculations on the basis of a set of two-dimensional solid-state NMR experiments of the model protein GB1. The most important result obtained from these test calculations is that the limitation of structural accuracy can be attributed to inaccurate distance information resulting from the limited correlation between peak intensities and distance, which is especially severe in spin diffusion-based solid-state NMR experiments.
The chapter “Full relaxation matrix-based correction of relayed polarization transfer for solid-state NMR structure calculation” therefore introduces a method which corrects experimental peak intensities for spin diffusion in order to improve the distance information from solid-state NMR spectra. The results show that the structural accuracy can be significantly improved when using the corrected distance information, however, strongly dependent on the preliminary structural model that is required as input for the method.
Proteomic analysis is the large-scale identification and characterization of proteins including post translational modifications. Proteomics encompasses a number of approaches including bottom-up and top-down workflows which are widely used independently and complementary as tools for the successful study of protein species. However, up to the present day these techniques have not been able to overcome every analytical limitation. Mass spectrometry has played a vital role alongside proteomics in providing the required analytical means of detecting protein amounts down to the atomole range. Soft ionization methods such as matrix assisted laser desorption/ionization (MALDI) and electrospray ionization (ESI) have permitted the transfer of peptides and intact proteins into the gas phase without extensive degradation. The introduction of recent developments in MALDI technology such as the highly sensitive 4-chloro-alpha-cyanocinnamic acid matrix (Cl-CCA) as well as the commercial availability of a MALDI-LTQ-Orbitrap which boosts peptide mass accuracy below 3 parts per million (ppm), have offered new prospective in protein analysis. The aim of the current study is to incorporate these new aspects and provide further advancements in gel-based as well as gel-free proteomic workflows.
Peptides of proteolytically digested proteins are routinely analyzed by means of peptide mass fingerprinting (PMF) often combined with MS/MS analyses to complement and substantiate PMF results by peptide sequence information. The most widely used protease for enzymatic digestion is trypsin, since it exhibits a very specific cleavage behavior limited to C-terminal hydrolyses after basic amino acids. However, less specific enzymes such as chymotrypsin, elastase and pepsin have emerged as useful tools in the analysis of particular protein classes e.g. membrane, cereal, and phosphorylated proteins. In this work a comprehensive bottom-up proteomic investigation including in-solution and in-gel protein digestions of analytes covering small to large, acidic to basic, and hydrophobic to hydrophilic proteins in combination with a series of less specific enzymes are presented in order to show the superiority of the novel MALDI matrix Cl-CCA. The Cl-CCA matrix proved to be highly superior compared to standard α-cyano-4-hydroxycinnamic acid (CHCA) since an average detection of more than 2- to 3-fold peptide amount was possible depending on the used protease and, therefore, resulting in strongly increased sequence coverage. Additionally, protein identification of chymotrypsin and elastase in-gel digested protein standards was evaluated. The MALDI-LTQ-Orbitrap providing peptide mass accuracy below and up to 3 ppm in combination with Cl-CCA as matrix and newly optimized digestion conditions led to unambiguous protein identifications of all chymotryptic digests outperforming its tryptic counterparts in the case of hydrophobic bacteriorhodopsin and α-globin from hemoglobin A (α-HgbA). In addition, significantly higher sequence coverage and increased number of detected peptides was acquired. Moreover, a proposed workaround for elastase digestions was capable of providing a solution for successful identification results.
Apart from digestions of singly separated proteins, solution isoelectic focusing (sIEF) was evaluated. OFFGEL fractionation is an efficient means of fractionating peptides and proteins according to their isoelectric point (pI) values through immobilized pH gel (IPG) strips after which samples are recovered in solution. Consequently, an issue of peptide recovery arises as a category of peptides relatively insoluble to the recovery solution should be present. A method was developed including the scraping of gel matrix from the IPG strips and peptide extraction using acetonitrile as organic solvent in combination with analytical techniques such as nLC-MALDI-MS/MS for peptide identification. The nature of the peptide species remaining in-gel was analysed and attributed to peptide solubility. A general trend in which a high percentage of neutral and hydrophobic peptides remaining entrapped in the IPG gel strip was observed.
The present work also examines a new top-down proteomic workflow involving protein elution from cleavable gels containing the labile crosslinker ethylene-glycol-diacrylate (EDA). Protein amounts of as low as 100 ng loaded onto EDA gels were detected using MALDI-TOF MS in the linear acquisition mode. Proteins from 8.5 up to 78 kDa were successfully measured including a hydrophobic 15 kDa core protein attaining a GRAVY score of +0.079. Additionally, the method was compatible with one dimensional protein separation as well as for 2-D IEF/SDS-PAGE. Lastly, two methods for protein identification were tested and found to be compatible to the proposed technique.
Metal-ion binding and metal-ion induced folding of the adenine-sensing riboswitch aptamer domain
(2007)
Divalent cations are important in the folding and stabilization of complex RNA structures. The adenine-sensing riboswitch controls the expression of mRNAs for proteins involved in purine metabolism by directly sensing intracellular adenine levels. Adenine binds with high affinity and specificity to the ligand binding or aptamer domain of the adenine-sensing riboswitch. The X-ray structure of this domain in complex with adenine revealed an intricate RNA-fold consisting of a three-helix junction stabilized by long-range base-pairing interactions and identified five binding sites for hexahydrated Mg2+-ions. Furthermore, a role for Mg2+-ions in the ligand-induced folding of this RNA was suggested. Here, we describe the interaction of divalent cations with the RNA–adenine complex in solution as studied by high-resolution NMR spectroscopy. Paramagnetic line broadening, chemical shift mapping and intermolecular nuclear Overhauser effects (NOEs) indicate the presence of at least three binding sites for divalent cations. Two of them are similar to those in the X-ray structure. The third site, which is important for the folding of this RNA, has not been observed previously. The ligand-free state of the RNA is conformationally heterogeneous and contains base-pairing patterns detrimental to ligand binding in the absence of Mg2+, but becomes partially pre-organized for ligand binding in the presence of Mg2+. Compared to the highly similar guanine-sensing riboswitch, the folding pathway for the adenine-sensing riboswitch aptamer domain is more complex and the influence of Mg2+ is more pronounced.
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.
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.
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 human MET receptor tyrosine kinase contributes to vertebrate development and cell proliferation. As a proto‐oncogene, it is a target in cancer therapies. MET is also relevant for bacterial infection by Listeria monocytogenes and is activated by the bacterial protein internalin B. The processes of ligand binding, receptor activation, and the diffusion behavior of MET within the plasma membrane as well as its interconnections with various cell components are not fully understood. We investigated the receptor diffusion dynamics using single‐particle tracking and imaging fluorescence correlation spectroscopy and elucidated mobility states of resting and internalin B‐bound MET. We show that internalin B‐bound MET exhibits lower diffusion coefficients and diffuses in a more confined area in the membrane. We report that the fraction of immobile receptors is larger for internalin B‐bound receptors than for resting MET. Results of single‐particle tracking in cells treated with various cytotoxins depleting cholesterol from the membrane and disrupting the actin cytoskeleton and microtubules suggest that cholesterol and actin influence MET diffusion dynamics, while microtubules do not have any effect.
The synthesis and single crystal structure of a new cocrystal, which is composed of OHphenolic∙∙∙OHphenolic∙∙∙Naminalic supramolecular heterosynthons assembled from 4-tert-butylphenol and the macrocyclic aminal TATU, is presented. This cocrystal was prepared by solvent-free assisted grinding, which is a commonly used mechanochemical method. Crystal structure, supramolecular assembly through hydrogen bonding interactions as well as the physical and spectroscopic properties of the title cocrystal are presented in this paper.
Solvent-free treatment of 1,3,6,8-tetraazatricyclo[4.3.1.13,8]undecano (TATU) with 4-chloro-3,5-dimethylphenol led to the formation of the title co-crystal, C7H14N4·2C8H9ClO. The asymmetric unit contains one aminal cage molecule and two phenol molecules linked via two O-H...N hydrogen bonds. In the aminal cage, the N-CH2-CH2-N unit is slightly distorted from a syn periplanar geometry. Aromatic [pi]-[pi] stacking between the benzene rings from two different neighbouring phenol molecules [centroid-centroid distance = 4.0570 (11) Å] consolidates the crystal packing.
FUSE Binding Protein 1 (FUBP1) is a transcriptional regulator, which is overexpressed in various cancer entities, including hepatocellular carcinoma (HCC) and colorectal cancer (CRC). It fulfills pro-proliferative and anti-apoptotic functions in cancer cells, resulting in increased proliferation and reduced sensitivity towards apoptotic stimuli.
Previously, camptothecin (CPT) and its clinically used analog 7-ethyl 10hydroxycamptothecin (SN-38) were shown to inhibit FUBP1 in biophysical interaction displacement assays (AlphaScreen; surface plasmon resonance, SPR), and first insights into the cellular effects of FUBP1 inhibition were obtained. CPT and SN-38 are known to potently inhibit topoisomerase 1 (TOP 1), and until today, these inhibitors were thought to be specific for this target. This could be disproved by our FUBP1 binding studies. An open issue, which is addressed in this thesis, was the contribution of FUBP1 inhibition to SN-38-mediated apoptosis apoptosis.
During this thesis, a low micromolar efficacy of CPT/SN-38-induced inhibition of FUBP1 binding to the Far Upstream Sequence Element (FUSE) oligonucleotide of p21 was determined. Furthermore, FUBP1 was for the first time shown to directly interact with a potential FUSE sequence upstream of the transcription start in pro-apoptotic gene BIK. In proof of-principle experiments, an effective inhibition of the binding of FUBP1 to the FUSE BIK DNA by CPT/SN-38 was verified.
One of the main goals of this thesis was to further elucidate the contribution of cellular FUBP1-inhibition by CPT/SN-38 to the anti-cancer potential of these substances. For this purpose, the TOP 1 mutant and TOP 1 wild type colorectal cancer sub-cell lines HCT116 G7 and HCT116 S were used. CPT/SN-38 was shown to induce apoptosis in single and combinatorial treatments with mitomycin c (MMC), independently of the TOP 1 mutation status of the cells. Furthermore, a prominent induction of a FUBP1 target gene signature was observed upon treatment of both cell lines with CPT/SN-38. Consequently, CPT/SN-38 was able to fulfill its anticancer effects in these cells, although TOP 1 could not be the main target in the mutant cell line.
In a second approach to gain indirect evidence for FUBP1 dependent effects of CPT/SN-38, the TOP 1-specific inhibitors topotecan (TTN) and β lapachone (BL) were used for the treatment of HCC and CRC cell lines. Interestingly, the TOP 1 inhibitors TTN and BL exhibited a reduced potency in apoptosis induction compared to the dual (FUBP1 and TOP 1) inhibitor SN-38.
Finally, two independent screens for a specific FUBP1 inhibitor were performed. In the first approach, a small number of structural and functional CPT-derivatives that exhibited a reduced inhibitory potential against TOP 1, were tested for their ability to interfere with the FUBP1/FUSE binding. Two particular indenoisoquinoline derivatives revealed potent in vitro inhibition of FUBP1 with low micromolar IC50 values.
In a second approach, previously identified candidate FUBP1 inhibitors that had been isolated from the Maybridge Hit Finder library served as lead structures for a structure activity relationship (SAR) study of the inhibition of FUBP1 binding to the FUSE oligonucleotide. After two cycles of optimization, a medium-potent FUBP1 inhibitor was obtained that induced effective deregulation of FUBP1 target genes in cell culture experiments.
Proton-pumping complex I of the mitochondrial respiratory chain is among the largest and most complex membrane protein complexes. The enzyme contributes substantially to oxidative energy-conversion in eukaryotic cells. Its malfunctions are implicated in many hereditary and degenerative disorders. Here, we report the X-ray structure of mitochondrial complex I at 3.6- 3.9 Å resolution describing in detail the central subunits that execute the bioenergetic function. A continuous axis of basic and acidic residues running centrally through the membrane arm connects the ubiquinone reduction site in the hydrophilic arm to four putative proton-pumping units. The binding position for a substrate analogous inhibitor and blockage of the predicted ubiquinone binding site provide a model for the ‘deactive’ form of the enzyme. The proposed transition into the active form is based on a concerted structural rearrangement at the ubiquinone reduction site rendering support for a two-state stabilization-change mechanism of protonpumping.
The light-harvesting complex of photosystem II (LHC-II) is the major antenna complex in plant photosynthesis. It accounts for roughly 30% of the total protein in plant chloroplasts, which makes it arguably the most abundant membrane protein on Earth, and binds about half of plant chlorophyll (Chl). The complex assembles as a trimer in the thylakoid membrane and binds a total of 54 pigment molecules, including 24 Chl a, 18 Chl b, 6 lutein (Lut), 3 neoxanthin (Neo) and 3 violaxanthin (Vio). LHC-II has five key roles in plant photosynthesis. It: (1) harvests sunlight and transmits excitation energy to the reaction centres of photosystems II and I, (2) regulates the amount of excitation energy reaching each of the two photosystems, (3) has a structural role in the architecture of the photosynthetic supercomplexes, (4) contributes to the tight appression of thylakoid membranes in chloroplast grana, and (5) protects the photosynthetic apparatus from photo damage by non photochemical quenching (NPQ). A major fraction of NPQ is accounted for its energy-dependent component qE. Despite being critical for plant survival and having been studied for decades, the exact details of how excess absorbed light energy is dissipated under qE conditions remain enigmatic. Today it is accepted that qE is regulated by the magnitude of the pH gradient (ΔpH) across the thylakoid membrane. It is also well documented that the drop in pH in the thylakoid lumen during high-light conditions activates the enzyme violaxanthin de-epoxidase (VDE), which converts the carotenoid Vio into zeaxanthin (Zea) as part of the xanthophyll cycle. Additionally, studies with Arabidopsis mutants revealed that the photosystem II subunit PsbS is necessary for qE. How these physiological responses switch LHC-II from the active, energy transmitting to the quenched, energy-dissipating state, in which the solar energy is not transmitted to the photosystems but instead dissipated as heat, remains unclear and is the subject of this thesis. From the results obtained during this doctoral work, five main conclusions can be drawn concerning the mechanism of qE: 1. Substitution of Vio by Zea in LHC-II is not sufficient for efficient dissipation of excess excitation energy. 2. Aggregation quenching of LHC-II does not require Vio, Neo nor a specific Chl pair. 3. With one exception, the pigment structure in LHC-II is rigid. 4. The two X-ray structures of LHC-II show the same energy transmitting state of the complex. 5. Crystalline LHC-II resembles the complex in the thylakoid membrane. Models of the aggregation quenching mechanism in vitro and the qE mechanism in vivo are presented as a corollary of this doctoral work. LHC-II aggregation quenching in vitro is attributed to the formation of energy sinks on the periphery of LHC-II through random interaction with other trimers, free pigments or impurities. A similar but unrelated process is proposed to occur in the thylakoid membrane, by which excess excitation energy is dissipated upon specific interaction between LHC-II and a PsbS monomer carrying Zea. At the end of this thesis, an innovative experimental model for the analysis of all key aspects of qE is proposed in order to finally solve the qE enigma, one of the last unresolved problems in photosynthesis research.
Mechanism of Na+-dependent citrate transport from the structure of an asymmetrical CitS dimer
(2015)
The common human pathogen Salmonella enterica takes up citrate as a nutrient via the sodium symporter SeCitS. Uniquely, our 2.5 Å x-ray structure of the SeCitS dimer shows three different conformations of the active protomer. One protomer is in the outside-facing state. Two are in different inside-facing states. All three states resolve the substrates in their respective binding environments. Together with comprehensive functional studies on reconstituted proteoliposomes, the structures explain the transport mechanism in detail. Our results indicate a six-step process, with a rigid-body 31° rotation of a helix bundle that translocates the bound substrates by 16 Å across the membrane. Similar transport mechanisms may apply to a wide variety of related and unrelated secondary transporters, including important drug targets.
Measles virus glycoprotein-based lentiviral targeting vectors that avoid neutralizing antibodies
(2012)
Lentiviral vectors (LVs) are potent gene transfer vehicles frequently applied in research and recently also in clinical trials. Retargeting LV entry to cell types of interest is a key issue to improve gene transfer safety and efficacy. Recently, we have developed a targeting method for LVs by incorporating engineered measles virus (MV) glycoproteins, the hemagglutinin (H), responsible for receptor recognition, and the fusion protein into their envelope. The H protein displays a single-chain antibody (scFv) specific for the target receptor and is ablated for recognition of the MV receptors CD46 and SLAM by point mutations in its ectodomain. A potential hindrance to systemic administration in humans is pre-existing MV-specific immunity due to vaccination or natural infection. We compared transduction of targeting vectors and non-targeting vectors pseudotyped with MV glycoproteins unmodified in their ectodomains (MV-LV) in presence of α-MV antibody-positive human plasma. At plasma dilution 1:160 MV-LV was almost completely neutralized, whereas targeting vectors showed relative transduction efficiencies from 60% to 90%. Furthermore, at plasma dilution 1:80 an at least 4-times higher multiplicity of infection (MOI) of MV-LV had to be applied to obtain similar transduction efficiencies as with targeting vectors. Also when the vectors were normalized to their p24 values, targeting vectors showed partial protection against α-MV antibodies in human plasma. Furthermore, the monoclonal neutralizing antibody K71 with a putative epitope close to the receptor binding sites of H, did not neutralize the targeting vectors, but did neutralize MV-LV. The observed escape from neutralization may be due to the point mutations in the H ectodomain that might have destroyed antibody binding sites. Furthermore, scFv mediated cell entry via the target receptor may proceed in presence of α-MV antibodies interfering with entry via the natural MV receptors. These results are promising for in vivo applications of targeting vectors in humans.
Potential energy, dipole moment, and electronic transition moment functions for the A 3Πand X3Σ- states of PH have been calculated from highly correlated electronic wavefunctions. The electric dipole moments in the vibrational ground state of PH are calculated to be 0.637 Debye (A 3Π) and 0.403 Debye (X3Σ-). The predicted rates of spontaneous emission between low lying vibrational states of the X state lie in the range of 46 to 109 sec-1 (PH) and 12 to 30 sec-1 (PD). The calculated radiative lifetime of the v' = 0 level in the A 3Π state of 400 ns is lower by about 10 percent than the most recent experimental value. The classical intersection of the 5Σ- and the A 3Πstate has been calculated to lie between v' = 2 and 3 with an expected uncertainty of about 500 cm−1, whereas the onset of the rotationally dependent predissociation lies at v' = 0, J' = 11.
Chlamydia are obligate intracellular bacteria that cause variety of human diseases. Host cells infected with Chlamydia are protected against many different apoptotic stimuli. The induction of apoptosis resistance is thought to be an important immune escape mechanism allowing Chlamydia to replicate inside the host cell. Infection with C. trachomatis activates the Raf/MEK/ERK pathway and the PI3K/AKT pathway. Here we show that inhibition of these two pathways by chemical inhibitors sensitized C. trachomatis infected cells to granzyme B-mediated cell death. Infection leads to the Raf/MEK/ERK-mediated up-regulation and PI3K-dependent stabilization of the anti-apoptotic Bcl-2 family member Mcl-1. Consistently, interfering with Mcl-1 up-regulation sensitized infected cells for apoptosis induced via the TNF receptor, DNA damage, granzyme B and stress. Our data suggest that Mcl-1 up-regulation is primarily required to maintain apoptosis resistance in C. trachomatis-infected cells.
In der vorliegenden Arbeit werden Verfahren der Mathematik und Informatik entwickelt und eingesetzt, um Struktur, Dynamik und biologische Aktivität aus NMR spektroskopischen und empirischen Parametern zu bestimmen. Dolastatin 10 und Epothilon A sind potentielle Wirkstoffe gegen Krebs, da sie durch Wechselwirkung mit Tubulin die Zellteilung unterbinden. Die 3D Struktur beider Wirkstoffe in Lösung und die Struktur von an Tubulin gebundenem Epothilon A wird aus NMR spektroskopischen Parametern bestimmt. Dolastatin 10 liegt in einem konformationellen Gleichgewicht zwischen der cis -- und trans -- Konformation in der ungewöhnlichen Aminosäure DAP vor. Beide Konformationen des flexiblen Pentapeptids können bestimmt werden mit RMSD = 1.423 Å für das cis -- Konformer und RMSD = 1.488 Å für das trans -- Konformer. Während das trans -- Konformer gestreckt vorliegt, faltet das cis -- Konformer am DAP zurück. Epothilone A ist durch einen Makrozyklus weniger flexibel und sowohl die an Tubulin gebundene Struktur (RMSD = 0.537 Å) als auch freie Form (RMSD = 0.497 Å) kann mit geringen RMSD -- Werten bestimmt werden. Die Struktur der freien Form, welche in Lösung hauptsächlich vorliegt, ist mit der Röntgenstruktur weitgehend identisch. In der an Tubulin gebundenen Form wird eine essentielle Umorientierung der Seitenkette beobachtet, die für die Wechselwirkung mit Tubulin entscheidend ist. Dipolare Kopplungen eines Proteins sind geeignet, eine 3D Homologiesuche in der PDB durchzuführen, da die relative Orientierung von Sekundärstrukturelementen und Domänen durch sie beschrieben wird 85 . Die frühe Erkennung 3D homologer Proteinfaltungen eröffnet die Möglichkeit, die Bestimmung von Proteinstrukturen zu beschleunigen. Eine Homolgiesuche unter Nutzung dipolarer Kopplungen ist in der Lage, Proteine oder zumindest Fragmente mit ähnlicher 3D Struktur zu finden, auch wenn die Primärsequenzhomologie gering ist. Darüber hinaus wird eine Transformation für experimentelle dipolare Kopplungen entwickelt, die die indirekte Orientierungsinformation eines Vektors relativ zu einem externen Tensor in den möglichen Bereich für den Projektionswinkel zwischen zwei Vektoren und somit in eine intramolekulare Strukturinformation übersetzt. Diese Einschränkungen können in der Strukturbestimmung von Proteinen mittels Molekulardynamik genutzt werden 92 . Im Gegensatz zu allen existierenden Implementierungen wird die Konvergenz der Rechnung durch die auf diese Weise eingeführten dipolare Kopplungsinformation kaum beeinflusst. Die dipolaren Kopplungen werden trotzdem von den errechneten Strukturen erfüllt. Auch ohne die Nutzung bereits bekannter Protein oder Fragmentstrukturen kann so ein erheblicher Teil der NOE -- Information substituiert werden. Die Dynamik des Vektors, der die beiden wechselwirkenden Dipole verbindet, beeinflusst den Messwert der dipolaren Kopplung. Dadurch wird Information über die Dynamik von Molekülen auf der µsZeitskala zugänglich, die bisher nur schwer untersucht werden konnte. Die Messung dipolarer Kopplungen für einen Vektor in verschiedenen Orientierungen erlaubt die Analyse seiner Bewegung 89 . Im besonderen ist die Ableitung eines modellfreien Ordnungsparameters 2 S möglich. Weiterhin lassen sich ebenso modellfrei eine mittlere Orientierung des Vektors, axialsymmetrische Anteile und nichtaxialsymmetrische Anteile der Dynamik ableiten und auswerten. Die Anwendung der so entwickelten Protokolle auf experimentelle Daten 90 lässt Proteine deutlich dynamischer erscheinen als auf der Zeitskala der Relaxationsexperimente zu erkennen ist. Der mittlere Ordnungsparameter sinkt von 0.8 auf 0.6. Dies entspricht einer Erhöhung des Öffnungswinkels der Bewegung von ca. 22 ° auf ca. 33°. Die Bewegungen weichen teilweise bis zu 40% und im Mittel 15% von der Axialsymmetrie ab. Neuronale Netze erlauben eine schnelle (ca. 5000 chemische Verschiebungen pro Sekunde) und exakte (mittleren Abweichung von 1.6 ppm) Berechnung der 13 C NMR chemischen Verschiebung 115 . Dabei kombinieren sie die Vorteile bisher bekannter Datenbankabschätzungen (hohe Genauigkeit) und Inkrementverfahren (hohe Geschwindigkeit). Das 13 C NMR Spektrum einer organischen Verbindung stellt eine detaillierte Beschreibung seiner Struktur dar. Resultate des Strukturgenerators COCON können durch den Vergleich des experimentellen mit den berechneten 13 C NMR Spektren auf ca. 1 o/oo der vorgeschlagenen Strukturen eingeschränkt werden, die eine geringe Abweichung zum experimentellen Spektrum haben 122 . Die Kombination mit einer Substrukturanalyse erlaubt weiterhin die Erkennung wahrscheinlicher, geschlossener Ringsysteme und gibt einen Überblick über die Struktur des generierten Konstitutionssubraumes. Genetische Algorithmen können die Struktur organischer Moleküle ausgehend von derer Summenformel auf eine Übereinstimmung mit dem experimentellen 13 C NMR Spektrum optimieren. Die Konstitution von Molekülen wird dafür durch einen Vektor der Bindungszustände zwischen allen Atom -- Atom Paaren beschrieben. Selbige Vektoren sind geeignet, in einem genetischen Algorithmus als genetischer Code von Konstitutionen betrachtet zu werden. Diese Methode erlaubt die automatisierte Bestimmung der Konstitution von Molekülen mit 10 bis 20 Nichtwasserstoffatomen 123 . Symmetrische neuronale Netze können fünf bzw. sieben dimensionale, heterogene Parameterrepräsentationen der 20 proteinogenen Aminosäuren unter Erhalt der wesentlichen Information in den dreidimensionalen Raum projizieren 134 . Die niederdimensionalen Projektionen ermöglichen eine Visualisierung der Beziehungen der Aminosäuren untereinander. Die reduzierten Parameterrepräsentationen sind geeignet, als Eingabe für ein neuronales Netz zu dienen, welches die Sekundärstruktur eines Proteins mit einer Genauigkeit von 66 % im Q 3 -- Wert berechnet. Neuronale Netzte sind aufgrund ihrer flexiblen Struktur besonders geeignet, quantitative Beziehungen zwischen Struktur und Aktivität zu beschreiben, da hier hochgradig nichtlineare, komplexe Zusammenhänge vorliegen. Eine numerische Codierung der über 200 in der Literatur beschriebenen Epothilonderivate erlaubt es, Modelle zur Berechnung der Induktion der Tubulin Polymerisation (R = 0.73) und der Inhibierung des Krebszellenwachstums (R = 0.94) zu erstellen 136 . Die trainierten neuronalen Netze können in einer Sensitivitätsanalyse genutzt werden, um die Bindungsstellen des Moleküls zu identifizieren. Aus der Berechnung der Aktivität für alle Moleküle des durch die Parameter definierten Strukturraums ergeben sich Vorschläge für Epothilonderivate, die bis zu 1 000 mal aktiver als die bisher synthetisierten sein könnten.
The gas phase ion chemistry of the simplest known phosphorus ylide, trimethylmethylenephosphorane, has been studied in the mass range m/e=2 - 186 and the pressure range 10-7-10-4 Torr. The most abundant product ion, m/e = 104, (CH3)2C2H5PCH2'+ is formed by a methylene group transfer reaction of the molecular ion. Almost all of the other product ions formed from the molecular ion can be subsumed under the general formula (CH3)3PCHPRn+ (R = H, CH3; n=1,2,3). The reactions indicate that the molecular ion has lost its ylide character almost completely. The protonated molecule is formed almost exclusively by a reaction of the fragment ion m/e = 75. This reaction and the CH3PH group transfer reaction indicate a cyclic structure (CH3) HP(CH2)2+ for this ion. A cyclic structure is also assumed for the ion m/e = 73, PC3H6+, which undergoes P and PH transfer reactions. The reactions of the ion m/e = 47 are consistent with the structure CH3PH+. The ICR and mass spectra are given, some metastable decompositions are discussed.
The analysis of biomolecular macrocomplexes requires certain preconditions to be fulfilled. The preparation of biomolecular samples usually results in low yields. Due to this constraint of low availability any method should provide a sufficient sensitivity to cope with typical sample amounts. Biomolecules also often show a reduced stability, i.e. a propensity for fragmentation upon ionisation, which requires reasonable soft methods for the investigation. Furthermore macromolecular complexes usually are composed by means of non-covalent interactions presenting additional demands on the softness. This holds true for specific complexes like protein-ligand or DNA double strand binding. For the formation of non-covalent, specific complexes the biomolecules’ native structure and environment are a basic prerequisite and hence crucial. Therefore it is desirable during analysis to keep the biomolecules in a native environment to preserve their structure and weak interactions. One suitable method for analysing biomolecules is mass spectrometry. Mass spectrometry is capable of high throughput screening as well as determining masses with high accuracy and high sensitivity. Especially since the availability of MALDI-MS and ESI-MS mass spectrometry evolved to a versatile tool to investigate biomolecular complexes. Both, MALDI- and ESI-MS are sufficiently soft methods to observe fragile biomolecules. Yet both methods have their advantages and disadvantages. During the recent years an alternative mass spectrometric approach has been developed in our group, termed LILBID-MS (Laser Induced Liquid Bead Ionisation/Desorption). In LILBID microdroplets of aqueous solution containing buffer, salt and further additives among the analyte molecules are injected into vacuum and irradiated one-by-one by mid-IR laser pulses. The absorption of the energy by the water leads to a rapid ablation of the preformed analyte ions. LILBID is highly tolerant for the addition of salts and detergents allowing to study biomolecular complexes in a native environment. As LILBID-MS is soft enough to avoid fragmentation, specific non-covalent complexes can be analysed directly from their native environment by this method. In addition dissociation can be induced on demand by increasing the laser intensity which allows for the study of subunit compositions. A further prominent property of LILBID is the possibility to study hydrophobic membrane proteins due to the tolerated use of detergents. During the course of this work, several instrumental improvements mostly concerning ion focussing and beam steering were introduced. Together with refinements of different modes of measurement the result is a significantly improved signal-to-noise ratio as well as a further improvement in sensitivity. In addition the accessible m/z range for a given flight time has been vastly increased. The new possibilities that LILBID now offers for the study of biomolecular complexes were investigated. The ability to detect specific binding in LILBID-MS was investigated by means of nucleic acids and their interaction with proteins. It could be shown that the stability of a 16bp dsDNA corresponds to that in solution phase regarding the dependency on concentration and type of the salts used. In addition a competitive experiment with the well-known transcription factor p50 was used to demonstrate the detection of sequence-specific binding with LILBID. The improved sensitivity allowed to detect single stranded DNA at nanomolar concentrations and even the 2686bp plasmid pUC19 could be easily detected without fragmentation using a concentration of only 80nM. In case of the transcription factor p63 the mass spectrometric analysis could help to identify a new model of activation and inhibition. For the first time known quarternary structures of membrane proteins like the light-driven proton pump bacteriorhodopsin and the potassium channel KcsA could be detected with mass spectrometry. For the light-driven proton pump proteorhodopsin the type and the concentration of the used detergents significantly influenced the stability of this protein as well as the preferred quarternary structure.
The mass spectra and the ion molecule reactions of methylphosphine, dimethylphosphine and dimethyldeuterophosphine have been studied by ion cyclotron resonance spectrometry. About 50 ion molecule reaction are observed for each compound. The product ions can be classified as ions with two phosphorus atoms: P2R5+, P2R3+, P2R2+ and P2R+ (R = CH3 or H), as phosphonium and phosphinium ions and ions resulting from collision dissociations and charge exchange reactions. Tertiary ions with three phosphorus atoms like CH3P3H2+ (from CH3PH2) and (CH3)4P3H2 (from (CH3)2PH) have also been detected. The mechanisms of the ion molecule reactions, rearrangements, P -H- and C-H-reactivities and product ion structures are discussed, using in the case of dimethylphosphine the results obtained with the deuterated compound. Rate constants of formation of the more abundant product ions from the molecular ion and the CH3P+ ion, both odd electron particles, have been determined. The reactions with dimethylphosphine have much smaller rate constants than the reactions with methylphosphine.
Pulsed electron-electron double resonance (PELDOR) is a pulsed EPR method that can reliably and precisely provide structural information regarding duplex RNAs and DNAs by measuring long-range distances (1.5-7 nm) utilizing distance-dependent magnetic dipole-dipole interaction between two nitroxide spin labels. In this thesis the application field of PELDOR spectroscopy has been expanded. For the first time the global architecture of tertiary folded RNA has been mapped in vitro. Moreover, the first application of PELDOR for determining structural aspects of RNA and DNA molecules inside cells has been presented. RNA has the central role in cellular processes and gene regulation. It can adopt complex three dimensional structures, which in combination with its conformational dynamics is essential for its function as biological catalyst, structural scaffold and regulator of gene expression. Riboswitches are cis-acting RNA segments that modulate gene expression by direct binding of small molecules with high affinity and specificity. Neomycin-responsive riboswitch is an engineered riboswitch developed by combination of in vitro selection and in vivo screening. Upon insertion into the 5‟ untranslated region of mRNA and binding the cognate ligand it is able to inhibit translational initiation in yeast. Using enzymatic probing the secondary structure had been postulated comprising global stem-loop architecture with a terminal and an internal loop. In the first part of this thesis, the global conformational arrangement of this 27 nucleotides long RNA element has been studied by means of site-directed spin labeling and PELDOR spectroscopy. Spin-labeled neomycin-responsive riboswitch mutants were synthesized via a Sonogashira cross-coupling reaction between 5-membered pyrroline ring based nitroxide radical (TPA) and 5-iodo-uridine. The labeling positions were chosen outside of the binding pocket and UV melting curves revealed that spin-labeling neither disturbs the secondary structure nor interferes with ligand binding. Efficient ligand binding was proven by thermal stabilization of 20.3±3.3 oC upon addition of neomycin, as well as by cw EPR spectra. PELDOR time traces with long observation time windows and with good signal to noise ratio and modulation depth were recorded for all double-labeled samples allowing a reliable data analysis. The fact that there were no shifts in the measured distances upon addition of neomycin implied the existence of a prearranged tertiary structure of the neomycin-sensing riboswitch without a significant global conformational change induced by ligand binding. Measured distances were in very good agreement with the NMR structure of the ligand-bound state of the riboswitch indicating the intrinsic propensity of the global RNA architecture toward its energetically favored ligand-bound form at low temperature. The results harvested in this work represent the first application of PELDOR for mapping the global structure of a tertiary folded RNA. In the second part of this thesis the possibility of applying PELDOR on nucleic acids (NAs) in cellular environment has been investigated. It was shown before that global NA structure depends on matrix conditions, such as concentration of ions and small molecules, molecular crowding, viscosity and interactions with proteins. Therefore, PELDOR spectroscopy on a double-labeled 12-base pair DNA duplex, the 14-mer cUUCGg tetraloop hairpin RNA and the 27-mer neomycin-sensing riboswitch has been used to obtain long-range distance constraints on such systems in Xenopus laevis oocytes and to compare them with in vitro measurements. The reduced lifetime of nitroxide spin labels under cellular conditions has been a major challenge in these measurements. Investigation of nitroxide reduction kinetics in-cell has revealed that the 5-membered pyrrolidine and pyrroline rings are significantly slower reduced compared to 6-membered piperidine ring based nitroxides. Due to prolonged lifetime of the TPA nitroxides covalently attached to NA molecules PELDOR signals could be measured with good signal-to-noise ratios up to 70 minutes of incubation time. The partial loss of coupled spin labels due to nitroxide reduction only led to a decrease in the modulation depth upon increasing the incubation time. No alterations in the measured distances between in vitro and in-cell experiments implies the existence of stable overall conformations of the 14-mer cUUCGg tetraloop hairpin RNA and the 27-mer neomycin-sensing riboswitch, whereas the 12-bp duplex DNA experiences stacking in-cell but retaining the secondary structure. Thus, for the first time nanometer distance measurements were performed inside cells, clearly laying a foundation for the application of PELDOR spectroscopy to study biological processes in cells, such as diffusion, interaction with proteins and other factors or chemical reactions.
5-lipoxygenase (5-LO) is an enzyme with a substantial role in inflammatory processes. In vitro kinase assays using [32P]-ATP in combination with mutagenesis have revealed that serine residues 271, 523 and 663 can be phosphorylated by MK2, PKA and ERK2 kinases, respectively. A few available reports regarding 5-LO protein sequence have covered up to 30% of the sequence after amino acid sequencing including Ser663. In LCMS/MS analyses of 5-LO tryptic digests from different cellular sources different peptides have been detected; however, none of the three phosphorylations has been detected and only Ser663 was included in the covered sequence.
As there was no comprehensive mass spectrometric analysis of 5-LO, the purpose of this study was to optimize the experimental conditions under which detection of the aforementioned phosphorylation events, as well as other possible post-translational modifications (PTMs), would be feasible. Matrix-Assisted Laser Desorption/Ionization Mass Spectrometry (MALDI-MS) was used for peptide analysis of 5-LO cleaved either by chemical reagents or by proteases. Sequence coverage of 5-LO could be enhanced to be close to completion by combination of results from digestions by trypsin, AspN and chymotrypsin. In-gel trypsin digestion followed by in-solution AspN digestion proved to be a useful sample treatment for reproducible detection of the Ser271-containing peptide.
Nevertheless, in none of the examined cleavage protocols the sequence around Ser523 was detected reproducibly or with acceptable signal intensity for subsequent peptide fragmentation. Propionic anhydride and sulfo-NHS-SS-biotin cross-linker (EZ-linkTM), were used for derivatization of lysine side chains and hindrance of lysine residue recognition by trypsin. Phosphopeptide enrichment became possible after tryptic digestion of these samples, not only due to formation of an individual Ser523-containing peptide, but also because TiO2-mediated enrichment, which is performed in acidic pH, was not impaired by positively charged free lysine side chains. Additionally, biotinylation of lysine residues was exploited for an intermediate enrichment step of the lysine containing peptides, prior to TiO2 phosphopeptide enrichment.
MALDI-MS analysis after in-vitro phosphorylation of 5-LO by the three kinases showed that Ser271 was phosphorylated in the MK2 and PKA kinase assays, while Ser523 was phosphorylated only in the PKA kinase assay. Surpisingly, no phosphopeptides were detected in the in-vitro kinase assays with ERK2, even though the unmodified counterpart of the Ser663-containing peptide was easily detected. The detection limit for each of the three phosphorylation sites was determined by the use of custom made phosphopeptides and an amount of 0.06 pmol of phosphopeptide in 1 μg 5-LO (representing 0.5% phosphorylation rate) was sufficient in all cases for successful enrichment and detection by MS.
In-vitro kinase assays with [32P]-ATP were performed for some kinases that were expected to phosphorylate 5-LO according to in-silico data. Three members of the Src tyrosine kinase family (Fgr, Hck and Yes) and the Ser/Thr specific kinase DNA-PK used 5-LO as their substrate and mainly residues at the N-terminal part of 5-LO were detected phosphorylated by MS (e.g. Y42, Y53). Additional in-vitro assays for recombinant 5-LO modification included incubation with glutathione or compound U73122, previously described as inhibitor of 5-LO.
Since in-vitro assays might have generated artifacts, a method for 5-LO purification from human cells was sought, in order to examine the modification state of the protein in the cellular context. ATP-agarose affinity purification and anti-5-LO immunoprecipitation proved inappropriate for sample purification for MALDI-MS analysis. Consequently, two human cell lines that are able to express 5-LO (Rec-1 Blymphocytes and MM6 monocytes) were transduced with a DNA cassette that contained recombinant human 5-LO sequence with an attached N-terminal FLAG-tag. Anti-FLAG immunoprecipitation was then performed effectively in cell lysates and the precipitated FLAG-5-LO was separated by SDS-PAGE before MALDI-MS analysis.
The examined cell stimuli were expected to result to phosphorylation of 5-LO at Ser523 by PKA in Rec-1 cells and to phosphorylation of Ser271 and/or Ser663 in MM6 cells by activated MK2 and ERK2, respectively. Additionally, under the conditions of MM6 cell stimulation, Fgr, Hck and Yes kinases, which phosphorylated 5-LO in vitro, were expected to be activated and the possibility of 5-LO phosphorylation on tyrosine was investigated. Although immunoblotting results indicated that all the aforementioned phosphorylation events existed in the examined samples, MALDI-MS analysis verified only phosphorylation on Ser271 in differentiated MM6 cells, interestingly regardless of cell stimulation.
Finally, the primary amine derivatization procedure by EZ-linkTM was utilized for MS analysis of lysine rich proteins. In the past, chemical propionylation of histones had been employed prior to trypsin digestion; however it was easily confused in MS with combinations of other PTMs (e.g. acetylation, methylation). Moreover, propionylation is a PTM for histone H3 and this information was lost. Consequently, the EZ-link reagent was more useful for analysis of histones, as unambiguous assignment of PTMs and detection of native propionylation on bovine H3 became possible.
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.