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Standard biorelevant media reflect the average gastrointestinal (GI) physiology in healthy volunteers. The use of biorelevant media in in vitro experiments has become an important strategy to predict drug behaviour in vivo and is often combined with in silico tools in order to simulate drug plasma profiles over time. In addition to the healthy population, the effects of disease state or co-administration of other drugs on plasma profiles must be considered to assure drug efficacy and safety. Thus, there is a need for a more accurate representation of the human GI physiology when it is altered by disease or co-administered drugs in in vitro dissolution experiments.
This thesis focused on the development of biorelevant media and dissolution tests reflecting GI physiology in circumstances where the gastric pH is elevated. Diseases linked to an elevated gastric pH are hypochlorhydria and achlorhydria, but these days treatment with acid-reducing agents (ARAs) is the single greatest cause of elevation in gastric pH. pH-dependent drug-drug interactions (DDIs) with ARAs are frequent, as the ARAs are used in a number of diseases using a variety of drugs. As the drugs currently on the market are often poorly soluble and ionisable, their dissolution is highly dependent on the pH of the GI tract, especially the gastric pH.
The thesis research consisted of several steps. In the first step, physiological changes in the human GI tract during the therapy with ARAs were identified. Parameters of the standard biorelevant gastric medium FaSSGF were adjusted to the identified changes to reflect the impact of ARA co-administration on the gastric physiology. The media aim to assess the potential extent of the ARA impact on gastric physiology by introducing biorelevant media pairs, ARA pH 4 and pH 6 media, of which one reflects a lesser, and the other a stronger impact of ARAs.
In the second step these ARA media were implemented in in vitro dissolution set-ups.
The dissolution of poorly soluble ionisable drugs was assessed using one-stage, two-stage and transfer model set-ups, as well as using a more evolved in vitro system TIM-1. Comparison of results from dissolution set-ups using the standard, low pH, gastric biorelevant medium FaSSGF (pH 1.6 or 2), and the same set-ups using ARA pH 4 and pH 6 media, shows a decrease in dissolution rate and extent for weakly basic compounds PSWB 001 and dipyridamole, and an increase in rate and extent of dissolution for the weakly acidic compound raltegravir potassium, when the gastric pH is elevated. Due to different physicochemical properties, the extent of the impact of physiological changes during ARA therapy (when either ARA pH 4 or pH 6 medium is selected) on dissolution varied among the model drugs. Thus, the bracketing approach, which considers a range of the possible ARA co-administration impact on drug dissolution, was confirmed to be best practice in assessing the impact of ARAs.
In the third step, dissolution data from in vitro experiments with ARA media was implemented into in silico models. The predictions using various in silico model approaches in Simcyp™ Simulator (minimal and full PBPK model, dissolution input using DRM and DLM) successfully bracketed in vivo data on drug administration during ARA therapy and correctly predicted an overall decrease in plasma concentration for the two model weakly basic compounds and an increase in plasma concertation for the model weakly acidic compound.
In all assessed scenarios, the ARA methods proved to be an essential part of evaluating and predicting the impact of ARAs on drug pharmacokinetics, and appropriately predicted the extent of a possible impact of ARAs on the drug plasma profiles. Thus, the ARA biorelevant media and dissolution tests were demonstrated to be valuable tools reflecting administration of drugs when the gastric pH is elevated and able to predict the impact of ARA therapy on drug administration.
The ability to evaluate the impact of human (patho) physioloy on drug behaviour in the gastrointestinal tract is of great importance, as the GI conditions play a significant role in drug release and absorption. Thus, there is great interest on the part of the pharmaceutical industry and regulatory agencies to develop best practices in this field, especially for pH-dependent DDIs. The media and dissolution tests developed in this thesis are biorelevant methods appropriate for evaluation of the impact of elevated gastric pH on drug efficacy and safety. Such methods, used as a risk assessment tool, in connection with evaluation of the efficacy window and potential toxicity, may help to increase confidence about decisions as to whether a pH-effect will occur and whether it is relevant or not, prior to conducting clinical studies. They may also enable changes in inclusion/exclusion criteria during recruiting for large-scale efficacy trials. In fact, the biopharmaceutic approach to drug development is becoming standard practice on a number of fronts, including metabolic DDIs, renal and hepatic insufficiency, powering decision-making process and possibly even waiving certain types of clinical studies.
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Resistant microbes are a growing concern. It was estimated that about 33,000 of people die because of the infections caused by multidrug resistant bacteria each year in Europe (ECDC, 2018, https://www.ecdc.europa.eu/). Bacteria can acquire resistance against toxic compounds via different mechanisms and intrinsic active efflux is one of the first mechanisms deployed by bacterial cells. The membrane-localized efflux pumps catalysing this reaction, extract toxic compounds from the interior of the cell and transport these to the outside, thereby maintaining sub-lethal toxin levels in the cytoplasm, periplasm and membranes. Gram-negative three-component efflux pumps, analysed in this study, are composed of an inner membrane protein, a member of the Resistance-Nodulation cell Division (RND) superfamily, an Outer Membrane Factor (OMF) protein and a Membrane Fusion Protein (MFP) that connects the two afore mentioned components into an active efflux pump. The pumps described in this work, AcrAB-TolC and EmrAB-TolC, are drug efflux pumps belonging to the RND and MFS superfamilies, respectively, while CusCBA is an efflux pump that belongs to the RND heavy metal efflux family. Another efflux pump that was used as a model for the design of an in vitro assay for the silver ion transport studies, CopA, belongs to the P-type ATPase superfamily. All pumps analysed in this study are part of the resistance system of Escherichia coli, which is a highly clinically relevant pathogen.
In order to examine the AcrAB-TolC, CopA and CusA efflux pumps, the individual components were separately produced in E. coli, purified to monodispersity and reconstituted in large unilamellar vesicles, LUVs. Means for the optimized production and adequate conditions for efficient reconstitution were presented in this study. The activity of AcrB in LUVs was detected using fluorescence quenching of the dye 8-hydroxy-1,3,6 pyrenetrisulfonate (pyranine), which is incorporated inside the proteoliposomes and is sensitive to the pH changes in its surrounding. The inactive AcrB variant with a substitution in the proton relay network, D407N, showed no activity in proteoliposomes, which correlates with the measurements done in empty liposomes. When AcrA was co-reconstituted with AcrB D407N proteoliposomes it did not restore protein activity. To test the assembly of the AcrAB-TolC pump out of its single components, an in vitro assay was established where the complex assembly was tested with AcrAB- and TolC-containing liposomes. These experiments showed putative AcrAB-TolC formation in the presence or absence of a pump substrate, taurocholate, as well as in the presence of the pump inhibitor, MBX3132. The assembly appeared stable over time and results were invariant in the presence or absence of a pH gradient across the AcrAB-containing membrane.
After determination of the ATPase activity of the P-type ATPase, CopA, in detergent micelles, the protein was reconstituted in LUVs. Quenching of the Ag+-sensitive dye Phen Green SK (PGSK), present on the inside of the CopA-containing proteoliposomes, was observed in presence of ATP and Ag+. Under the same conditions, but in absence of Ag+-ions, quenching was reduced by 80 % after 300 seconds. No PGSK-quenching was observed in control liposomes in the presence of ATP and Ag+. The additional presence of sodium azide led to minimal reduction of the PGSK-quenching as expected since sodium azide is not an inhibitor of P-type ATPases, but the quenching rate was similar to that of the same experimental condition with control liposomes.
The RND superfamily member CusA, as part of the tripartite CusCBA efflux pump, has been proposed to sequester Ag+ or Cu+ from either the cytoplasmic or periplasmic side of the inner membrane. The periplasmic transport of silver ions was implied from an in vitro assay where the quenching of a pH sensitive dye, 9-amino-6-chloro-2-methoxyacridine (ACMA), indicates acidification of the lumen of the proteoliposomes containing CusA when an inwardly directed pH was imposed. The same experiment with the CusA D405N variant, which was previously reported to be an inactive variant, also led to ACMA quenching, although at a slightly lower rate. Under application of an inwardly directed pH and a (negative inside), CusA-containing proteoliposomes showed a strong quenching of the incorporated PGSK dye, suggesting strong Ag+ influx.
The Major Facilitator Superfamily-(MFS-) type EmrAB-TolC pump has an analogous structural setup as the RND-type AcrAB-TolC pump. To examine the efflux of one of its substrates, carbonyl - cyanide m-chlorophenylhydrazone (CCCP), a plate-based susceptibility assay was used. The presence of the EmrAB-TolC pump confers lower susceptibility levels towards CCCP in E. coli, compared to cells not expressing the pump or cells expressing only the MFS component, indicating that EmrAB-TolC extrudes CCCP.
The work done in this study opens up a path towards investigation of drug and metal resistance in vitro. The methodologies to obtain proteoliposomal samples of multicomponent efflux pumps and subsequent measurements of drug/metal ion and H+ fluxes, as well as the determination of pump assembly are crucial for the future research on pump catalysis and transport kinetics. The in vivo drug-plate assays done in this work provide initial insights for future investigations of the drug susceptibility of E. coli expressing the MFS-type tripartite efflux pumps.
Over the last decade, cryo-EM has developed exponentially due to improvements in both hardware (“machine”-based) and software (“algorithm”-based). These improvements have pushed the best achievable resolutions closer to atomic level, bridging “gaps” not covered by other biophysical techniques, and allowing more difficult biological questions to be addressed. Thus, this PhD project was designed and constructed to apply cryo-EM to answer biological questions, while allowing simultaneous cryo-EM method development.
The biological focus of this research is pentameric ligand-gated ion channels (pLGICs), specifically the serotonin receptor type-3 receptor (5HT3R), which also belongs to the Cys-loop receptor family. 5HT3R plays an important role in fast synaptic signal transduction in response to agonist and antagonist binding. Binding to its native ligand results in opening of the channel at the transmembrane domain, allowing cations to pass through, resulting in membrane depolarization and conversion of the chemical signal into an electrical one.
This work consisted mainly of two specific aims. One was focused on conformational investigation of 5HT3R in its ligand-bound open conformation, using cryo-electron microscopy (cryo-SPA), in order to understand the gating mechanism upon ligand activation. The other one was to combine SPA with cryo-ET and STA to push the resolution limitation of conventional cryo-ET and STA workflows.
In the end, three different cryo-EM conformations of membrane-embedded 5HT3R were resolved using cryo-SPA, two structures in resting closed forms, one C5-symmetric and one C1-asymmetric, and one serotonin-bound open form. These three structures presented a number of novel features related to the transition of the receptor to its ion-conductive state. Specifically, the serotonin-bound receptor shows asymmetric opening, which was speculated to occur via an intermediate asymmetric Apo state. In addition to the cryo-SPA work, application of cryo-ET and STA to the study of 5HT3R in native vesicles is described in this thesis. Additional work on methods development, focused on combining SPA and STA techniques, along with preliminary results on tobacco mosaic virus are also detailed and discussed.
Moreover, previously unreported asymmetric arrangements of the subunits of the homopentameric 5HT3R around the pore axis were revealed. The asymmetric open state is stabilized by phospholipids inserted at the interface between subunits, at a site well-documented for the binding of allosteric pLGIC modulators. These results not only give structural support to a large body of functional data on the effects of lipids on the function of this receptor family, but also provide structural guidance for future studies in this field. Meanwhile, the SPA-STA combined methods developed during the course of this work have the potential to help resolve higher resolution tomography-based structures, which would benefit researchers seeking to do in-situ-based structural studies.
Um sich an ändernde Umwelteinflüsse und metabolische Bedürfnisse anpassen zu können, ist es für Zellen essenziell, dass Boten-RNA (engl. messenger RNA, mRNA) stetig und schnell nach der Translation abgebaut wird. In Prokaryoten ist dafür der Proteinkomplex Degradosom verantwortlich, in dem Endo- und Exoribonukleasen RNase E und PNPase das RNA-Transkript in kleinere Fragmente und schließlich einzelne Nukleotide spalten. Die DEAD-Box Helikase RhlB im Komplex dient zusätzlich dazu, mögliche Sekundärstrukturen in der RNA zu entfalten, welche sonst die weitere Degradation behindern würden. Es konnte gezeigt werden, dass RhlB’s sehr geringe katalytische Aktivität – gemessen durch ATP-Verbrauch und Rate an entwundener RNA – signifikant durch die allosterische Bindung an Komplexpartner RNase E erhöht wird. Gleichzeitig deuten andere Studien darauf hin, dass RhlB eine mögliche Selektivität für doppelsträngige RNA-Substrate mit 5‘-Einzelstrang-Überhängen aufweist.
Diese Arbeit liefert neue Erkenntnisse in Bezug auf die Kommunikation zwischen den Degradosom-Komponenten RhlB und RNase E aus E. coli, indem das potenzielle Wechselspiel zwischen RhlBs RNA-Selektivität und der allosterischen Aktivierung durch RNase E untersucht wurde. Der vielseitige Einsatz NMR-spektroskopischer Techniken sowie die Verwendung kurzer RNA-Substrate mit spezifischen Strang-Eigenschaften ermöglicht es, mit einen ungewöhnlichen, RNA-zentrierten Ansatz an diese unzureichend verstandene Protein-Interaktion heranzugehen.
Zunächst wurden hierzu eine Reihe kurzer doppelsträngiger RNA-Konstrukte hergestellt, die sich nicht nur in ihren Einzelstrang-Merkmalen unterscheiden, sondern auch die thermodynamischen Anforderungen eines DEAD-Box Helikase Substrats erfüllen, und gleichzeitig eine ausreichende NMR-spektroskopische Signal-Zuordnung erlauben. Die thermale Stabilität, das Faltungsverhalten sowie die 1H Imino-protonen- und 13C HSQC-Zuordnungen aller geeigneten Konstrukte wurden erfolgreich bestimmt.
Um den Einfluss spezifischer RNA-Substrate sowie die Bindung zweier verschiedener RNase E Fragmente auf RhlBs ATP-Umsatzrate zu untersuchen, wurde sich zunächst eines photometrischen Phosphat-Assays bedient. Damit konnte deutlich gezeigt werden, dass RhlB in Abwesenheit des Komplex-Partners nicht in der Lage ist, signifikante Mengen an ATP umzusetzen, unabhängig davon, welches RNA-Konstrukt eingesetzt wird. Die Bindung der RNase E Fragmente erhöhte signifikant die ATP-Hydrolyse-Rate der Helikase, wobei die größte Aktivierung für den RNA-Duplex mit 5‘-Einzelstrang sowie ein einzelsträngiges Substrat zu beobachten ist. Da diese Ergebnisse deutlich eine RNA-Abhängigkeit beim ATP-Umsatz der Helikase zeigen, wurde untersucht, ob diese Unterschiede ihren Ursprung bereits in der Bindung der spezifischen RNA-Substrate haben. Mittels einer Mischapparatur, die es erlaubt die enzymatische Reaktion direkt im Spektrometer zu initiieren sowie zeitaufgelöster 31P NMR-Experimente konnte die allosterische Aktivierung der ATP-Hydrolyse-Rate von RhlB auch unter NMR-spektroskopischen Messbedingungen nachgewiesen werden.
Da die Ergebnisse des ATPase Assays deutlich eine RNA-Abhängigkeit bei der ATP-Umsatz-Rate der Helikase zeigen, wurde zusätzlich untersucht, ob diese Unterschiede ihren Ursprung in den Affinitäten für die verschiedenen RNA-Substrate haben und ob diese durch die Bindung von RNase E and RhlB beeinflusst werden. Um im gleichen Zuge zu überprüfen, ob die Bindung der RNA an RhlB die RNA-Konformation oder Basenpaarung ändert, werden 1H NMR-Titrationsexperimente durchgeführt. Es konnte erstmals gezeigt werden, dass RhlB eine inhärente Präferenz für Duplexe mit 5‘-Überhang gegenüber Konstrukten mit 3‘-Überhang oder stumpfen Enden besitzt, was sich in einer erhöhten Affinität zeigt. Zusätzlich offenbaren die Messungen, dass RNase Es allosterische Bindung selektiv die Affinität gegenüber Konstrukten mit Einzelstrang-Überhang erhöht, während die Affinität zu RNA Duplexen ohne Überhang sogar verringert wird. Diese Ergebnisse liefern erstmals einen Nachweis, dass RNase E aktiv Einfluss auf RhlBs RNA-Bindung nimmt. Weder die Bindung der RNA and RhlB noch an den RhlB/RNase E Komplex scheint die Basenpaarung oder Konformation der RNA-Substrate zu beeinflussen, da lediglich eine homogene Peak-Verbreitung aller Imino-Protonen-Signale im 1H NMR-Spektrum beobachtet werden konnte.
The electron transport chain (ETC) is used by cells to create an electrochemical proton gradient which can be used by the ATP synthase to produce ATP. ETC, also called respiratory chain, is formed in mitochondria by four complexes (complex I-IV) and mediated by two electron carriers: cytochrome c and ubiquinone. Electrons are passed from one complex to another in a series of redox reactions coupling proton pumping from the negative (N) side of the membrane to the positive (P) side. Complex I can introduce electrons into the ETC by oxidizing NADH to NAD+ and reducing quinone (Q) to quinol (QH2). The process accomplishes pumping of four protons across the membrane. Complex II is another electrons entry point. It catalyzes the oxidation of succinate to fumarate while reducing Q to QH2. Complex III, also called cytochrome bc1 complex, can transfer the electrons from QH2 to cytochrome c and couple to proton pumping. In complex III the Q-cycle contributes four proton translocations: two protons are required for the reduction of one quinone to a quinol and two protons are released to the P side. Complex IV (cytochrome c oxidase), the terminal complex of the ETC, catalyzes the electron transfer to oxygen and pumps four protons to the P side. Structures of ETC complexes are available. However, the structure of a hyperthermophilic cytochrome bc1 complex has not been elucidated till now. Additionally, the dimeric crystal structure of cytochrome c oxidase from bovine has been discussed controversially.
To build up a functional complex, cofactors are required. The active site of A- and B-type cytochrome c oxidases contain the high spin heme a which is synthesized by the integral membrane protein heme A synthase (HAS). HAS can form homooligomeric complexes and its oligomerization is essential for the biological function of HAS. HAS is evolutionarily conserved among prokaryotes and eukaryotes. Despite its importance, little is known about the detailed structural properties of HAS oligomers.
During my PhD studies, I focused on the cytochrome c oxidase (AaCcO), the cytochrome bc1 complex (Aabc1) and the heme A synthase (AaHAS) from Aquifex aeolicus. This organism is one of the most hyperthermophilic ones and can live at extremely high temperatures, even up to 95 °C. Respiratory chain complexes provide energy for the metabolism of organisms, and their structures have been studied extensively in the past few years. However, there has been a lack of atomic structures of complexes from hyperthermophilic and ancient bacteria, so little is known about the mechanism of these macromolecular machines under hyperthermophilic conditions. Therefore, my PhD studies had four main objectives: 1) to structurally and functionally characterize AaCcO, 2) to reveal the mechanism of Aabc1 thermal stability based on its structure, 3) to determine the oligomerization of AaHAS, 4) to provide valuable insights into the relationship between function and oligomerization of AaHAS.
1) Structure of AaCcO
Heme-copper oxidases (HCOs) catalyze the oxygen reduction reaction being the terminal enzymes in the plasma membranes in many prokaryotes or of the aerobic respiratory chain in the inner mitochondrial membrane. By coupling this exothermic reaction to proton pumping across the membrane to the P side, they contribute to the establishment of an electrochemical proton gradient. The energy in the proton electrochemical proton gradient is used by the ATP synthase to generate ATP. HCOs are classified into three major families: A, B and C, based on phylogenetic comparisons. The well-studied aa3-type cytochrome c oxidase from Paracoccus denitrificans (P. denitrificans) represents A-family HCOs. So far, the only available structure of the ba3-type cytochrome c oxidase from Thermus thermophilus represents the B-family of HCOs. This family contains a number of bacterial and archaeal oxidases. The C-family contains only cbb3-type cytochrome c oxidases.
The AaCcO is one of the ba3-type cytochrome c oxidases. Based on the genomic DNA sequence analysis, it has been revealed that A. aeolicus possesses two operons coding for cytochrome c oxidases (two different subunit I genes, two different subunit II genes and one subunit III gene). So far, only subunits CoxB2 and CoxA2 were identified. The presence of the additional subunit IIa was reported in 2012. Moreover, a previous paper reported that AaCcO can use horse heart cytochrome c and decylubiquinol as electron donors and the typical cytochrome c oxidase inhibitor cyanide does not block the reaction completely.
In the course of my PhD studies, I performed heterologous expression of AaCcO in Pseudomonas stutzeri (P. stutzeri) and co-expression with AsHAS in Escherichia coli, respectively. The subcomplex CoxA2 and CoxB2 can be purified from P. stutzeri, however, it lacks heme A. Additionally, a protocol for the heterologous production of cytochrome c555 from A. aeolicus was established. In parallel, I also purified the AaCcO from native membranes according to previously reported methods with some modifications. The activity of AaCcO with its native substrate, cytochrome c555, was 14 times higher than with horse heart cytochrome c.
To enable a detailed investigation and comparison of AaCcO and other cytochrome c oxidases, the cryo-EM structure of AaCcO was determined to 3.4 Å resolution. It shows that the three subunits CoxA2, CoxB2, and IIa are tightly bound together to form a dimer in the membrane. Surprisingly, CoxA2 contains two additional TMHs (TMH13 and TMH14) to enhance the protein stability. The cofactors heme a3, heme b, CuA and CuB are also identified. Interestingly, two molecules of 1,4-naphthoquinone and cardiolipin were observed in the dimer interface. Based on the structure analysis, the AaCcO possesses only the K-pathway for proton delivery to the active site and proton pumping.
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B-cell acute lymphoblastic leukaemia (B-ALL) is characterized by the overproduction of lymphoblasts in the bone marrow (BM), and it is the most common cancer in children while being comparatively uncommon in adults. On the other hand, in chronic myeloid leukaemia (CML), 70% of cases are found in patients older than 50 years, making it uncommon in children. All CML cases and up to 3% of paediatric B- ALL (and 25% of adult B-ALL) cases are due to fusion gene BCR-ABL1, which gives rise to the cytoplasmatic, constitutively active oncoprotein, tyrosine kinase BCR-ABL1 through a reciprocal translocation between chromosomes 9 and 22. The constitutively active BCR-ABL tyrosine kinase leads to deregulation of different signal transduction pathways such as cell growth, proliferation and cell survival. The role of the bone marrow microenvironment (BMM) can mediate disease initiation (only in mice), progression, therapy resistance, and relapse, as has been increasingly recognized over the last two decades. In general, the BMM is a very complex arrangement of various cell types such as osteoblasts, osteoclasts, endothelial cells, adipocytes, mesenchymal stromal cells, macrophages and several others. In addition, the BMM is composed of multiple chemical and mechanical factors and extra cellular matrix (ECM) proteins which contribute to the BMM’s features influencing leukaemia behaviour. Considering the incidence of B-ALL and CML in children and in adults respectively, we hypothesized that the young and/or an aged BMM might also play a previously unrecognized role in the aggressiveness of B-ALL and CML. We proposed that BM, transduced with BCR-ABL1-expressing retrovirus in the murine transduction/transplantation model of B-ALL, transplanted into young versus old recipient mice would lead to a more aggressive disease in young mice, and similarly CML would be more aggressive in old recipient mice. In close recapitulation with the human incidence, induction of CML led to a significantly shorted survival in old recipient mice. On the other hand, induction of B-ALL showed a shortened survival in young compared to old syngeneic mice, as well as in a xenotransplantation model. Among the highly heterogenous composition of the BMM, we implicate young BM macrophages as a supportive niche for B-ALL cells. The results were found to be mostly due to potential soluble factors differentially secreted from young and old macrophages. Therefore, we hypothesized that the chemokine CXCL13, which has been demonstrated to play a role in B cell migration and act as a diagnostic marker in the cerebrospinal fluid of patients with neuroborreliosis, might be responsible for the observed phenotype. CXCL13 was found to be more highly expressed in healthy and leukaemic young mice as well as in conditioned medium of young macrophages. Using a variety of in vitro experiments, CXCL13 showed to significantly increase the proliferation and the migration of leukaemia cells when exposed to young macrophages, and the phenotype was rescued while using a CXCL13 neutralizing antibody. The CXCL13 role was also confirmed in vivo, since macrophage ablation led to a prolongation of survival in young mice and a reduction of CXCL13 levels. The use of an additional mouse model, leukaemia cells with CXCR5 deficiency, led to a significant prolongation of survival of young mice, confirming the importance of the CXCL13-CXCR5 axis in B-ALL. In line with our murine results, we found that human macrophages and CXCL13 levels were higher in pediatric B-ALL patients than in adults. Consistent with our murine data, the expression level of CXCR5 may act as a prognostic marker in B-ALL, as well as a predictive marker for central nervous system relapse in human B-ALL. The overall findings show that a young BMM, and in particular macrophages, influences B-ALL progression. We specifically identified CXCL13, secreted by young macrophages, as a promoter of proliferation of B-ALL cells, influencing survival in B-ALL via CXCR5. The CXCR5-CXCL13 axis may be relevant in human B-ALL, and higher CXCR5 expression in human B-ALL may act as a predictive marker.
The members of the multidrug/oligosaccharidyl-lipid/polysaccharide (MOP) transporter superfamily mediate export of a wealth of molecules of physiological and pharmacological importance. According to the Transporter Classification Database (TCDB), the MOP superfamily is mainly categorized into six distantly related families functionally characterized families: the multidrug and toxic compound extrusion (MATE), the polysaccharide transporter (PST), the oligosaccharidyl-lipid flippase (OLF), the mouse virulence factor (MVF) the agrocin 84 antibiotic exporter (AgnG), and the progressive ankylosis (Ank) family. Among these, the multidrug resistance MATE family transporters are most ubiquitous, being present in all domains of life: Archaea, Bacteria and Eukarya. As secondary active transporters, they utilize transmembrane electrochemical ion gradients of Na+ and/or H+ in order to drive the efflux of xenobiotics or cytotoxic metabolic waste products with specificity mainly for polyaromatic and cationic substrates. Active efflux of drugs and toxic compounds carried out by multidrug transporters is one of the strategies developed by bacterial pathogens to confer multidrug resistance. MATE proteins provide resistance to, e.g., fluoroquinolone, aminoglycoside antibiotics, and anticancer chemotherapeutical agents, thus serving as promising pharmacological targets for tackling a severe global health issue. Based on their amino acid sequence similarity, the MATE family members are classified into the NorM, the DNA-damage-inducible protein F (DinF), and the eukaryotic subfamilies. Structural information on the alternate conformational states and knowledge of the detailed mechanism of the MATE transport are of great importance for the structure-aided drug design. Over the past decade, the crystal structures of representative members of the NorM, DinF and eukaryotic subfamilies have been presented. They all share similar overall architecture comprising 12 transmembrane helices (TMs) divided into two domains, the N-terminal domain (TMs 1-6) and the C-terminal domain (TMs 7-12), connected by a cytoplasmic loop between TM6 and TM7 (Fig. II.1). Since all available MATE family structures are known only in V-shaped outward-facing states with the central binding cavity open towards the extracellular side, a detailed understanding of the complete transport cycle has remained elusive. In order to elucidate the underlying steps of the MATE transport mechanism, structures of distinct intermediates, particularly inward-facing conformation, are required.In my PhD project, structural and functional studies have been performed on a MATE family (DinF subfamily) transporter, PfMATE, from the hyperthermophilic and anaerobic archaeon Pyrococcus furiosus. This protein was produced homologously in Pyrococcus furiosus as well as heterologously in Escherichia coli, and used for the subsequent purification and crystallization trials by the vapor diffusion (VD) and lipidic cubic phase (LCP) method. To the best of my knowledge, PfMATE is the first example of a successful homologous production of a membrane protein in P. furiosus. Due to the very low final amount of the purified protein from the native source, the heterologously produced PfMATE samples were typically used for the extensive structural studies. Crystal structures of PfMATE have been previously determined in an outward-facing conformation in two distinct states (bent and straight) defined on the arrangement of TM1. A pH dependent conformational transition of this helix regulated by the protonation state of the conserved aspartate residue Asp41 was proposed. However, it has been discussed controversially, leading to the hypothesis about TM1 bending to be rather affected by interactions with exogenous lipids (monoolein) present under the crystallization conditions. Based on these open questions, an experimental approach to investigate the role of lipids as structural and functional modulators of PfMATE has been taken in the course of my PhD project. The interplay between membrane proteins and lipids can affect membrane protein topology, structure and function. Considering differences between archaeal and bacterial lipid composition, cultivation of P. furiosus cells and extraction of its lipids was followed by the mass spectrometry (MS) based lipidomics for identification of individual lipid species in the archaeal extract. In order to assess the effects of lipids on PfMATE, different lipid molecules were used for co-purification and co-crystallization trials. This dissertation presents a workflow leading to the structure determination of a MATE transporter in the long sought-after inward-facing state, which has been achieved upon purification and crystallization of the heterologously produced PfMATE in the presence of lipids from its native source P. furiosus. Also, the PfMATE outward-facing state obtained from the crystals grown at the acidic pH conditions sheds light on the previously proposed pH-dependent structural alterations within TM1. It is interesting to note that the inward and outward-facing states of PfMATE were obtained from the crystals grown under similar conditions, but in the presence and absence of native lipids, respectively. This observation supports the hypothesis about physiologically relevant lipids to act as conformational modulators or/and a new class of substrates, expanding the substrate spectrum of the MATE family transporters. Comparative analysis of two PfMATE states reveals that transition from the outward to the inward-facing state involves rigid body movements of TMs 2-6 and 8-12 to form an inverted V, facilitated by a loose binding of TMs 1 and 7 to their respective bundles and their conformational flexibility. Local fluctuations within TM1 in the inward-facing structure, including bending and unwinding in the intracellular half of the helix, invoke its highly flexible nature, which is suitable for ion and substrate gating.
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Currently, due to the misuse of antibiotics, we are facing a major public health problem. The resistance to antibiotics of certain bacterial strains makes the treatment of infections very complex.
In this context, the present thesis project concerns the study of a bacterial efflux complex capable of transporting antibiotics from the cytoplasm to the outside of the cell. This complex is composed of an inner-membrane Major Facilitator Superfamily (MFS) transporter (EmrB, E. coli multidrug resistance), a channel of the outer membrane TolC (Tolerance to Colicin E1) and a periplasmic adapter (EmrA, E. coli multidrug resistance). Unlike RND-type efflux systems (such as AcrAB-TolC), little is known about the MFS-type EmrAB-TolC system. It is therefore important to study the entire complex on a structural and functional level, to analyse the marked differences between these two types of transport systems. The goal of my thesis project was to study at least one EmrAB-TolC complex from a structural point of view. For my studies the aim was to isolate the complex directly from bacteria overexpressing the three protein partners. In a first step, 15 homologous EmrAB-TolC systems were identified and their corresponding genes amplified from genomic DNA of different Gram-negative bacteria. Among the genes of the 15 systems, the genes coding for the E. coli and V. cholerae systems were further studied. The expression vectors encoded fluorescent markers for the monitoring of the expression levels of different proteins and for studying the formation of complexes. In a first step, the different protein expression levels (EmrB-mRFP1 and EmrA-sfGFP) were studied for several expression strains of E. coli by measuring the red and green fluorescence levels and by Western blot (anti-His, Myc, and Strep for EmrB, EmrA, and TolC). The E. coli strain C41(DE3) was best suited for co-expression of EmrAB-TolC. In a second step, the FSEC (Fluorescence detection Size Exclusion Chromatography) methodology was used to identify a complex suitable for structural study. Thus this method enabled the observation that the EmrAB-TolC complex of E. coli was produced in higher amount than that of V. cholerae. The final co-purification protocol consists in perfoming a gentle lysis of the bacteria using lysozyme, then after solubilization with DDM, the purification is started by a Ni2+-NTA affinity chromatography step followed by a size exclusion chromatography step. Finally, the fractions containing the three protein partners are used for the detergent-exchange by amphipol A8-35 before the structural study by electron microscopy. Negative stain EM-micrographs displayed elongated objects with a length of 33 nm in side view. An average image of EmrAB-TolC shows similarities to that of the AcrAB-TolC complex observed under similar conditions. Similarities included the characteristic densities of TolC. Whereas differences were found in the lower part of EmrAB which is thinner than the lower part of AcrAB. The densities visible above the amphipol-ring correspond to EmrA, which displays a channel-like structure as in AcrA. The channel however seems to extend further towards the amphipol belt. Since EmrB does not have an extended periplasmic domain as the RND proteins have, these densities are therefore solely assigned to EmrA. EmrA, on the other side, contacts TolC akin to the interaction of AcrA/MexA to their cognate outer membrane channels (TolC/OprM) in a ‘tip-to-tip’ fashion.
As one of the most widespread infectious diseases in the world, it is currently estimated that approximately 296 million people globally are chronically infected with Hepatitis B virus (HBV), the consequences of HBV infection cause more than 620,000 deaths each year. Although safe and effective HBV vaccines have reduced the incidence of new HBV infections in most countries, there are still around 1.5 million new infections each year. HBV remains a major health problem because there is no large-scale effective vaccination strategy in many countries with a high burden of disease, many people with chronic HBV infection are not receiving effective and timely treatment, and a complete cure for chronic infection is still far from being achieved.
Since its discovery, HBV has been identified as an enveloped DNA virus with a diameter of 42 nm. For efficient egress from host cells, HBV is thought to acquire the viral envelope by budding into multivesicular bodies (MVBs) and escape from infected cells via the exosome release pathway. It is clear that HBV hijacks the host vesicle system to complete self-assembly and propagation by interacting with factors that mediate exosome formation. Consequently, the overlap with exosome biogenesis, using MVBs as the release platform, raises the possibility for the release of exosomal HBV particles. Currently, virus containing exosomal vesicles have been described for several viruses. In light of this, this study explored whether intact HBV-virions wrapped in exosomes are released by HBV-producing cells.
First, this study established a robust method for efficient separation of exosomes from HBV virions by a combination of differential ultracentrifugation and iodixanol density gradient centrifugation. Fractionation of the density gradient revealed that two populations of infectious viral particles can be separated from the culture fluids of HBV-producing cells. The population present in the low-density peak co-migrates with the exosome markers. Whereas the population that appeared in the high-density fractions was the classical HBV virions, which are rcDNA-containing nucleocapsids encapsulated by the HBV envelope.
Subsequently, the characterization of this low-density population was performed, namely the highly purified exosome fraction was systematically investigated. Relying on the detergent sensitivity of the exosome membrane and the outer envelope of the HBV virus, disruption of the exosome structure by treatment with limited detergent revealed the presence of HBsAg in the exosomes. At the same time, mild and limited NP-40 treatment of highly purified exosomes and a further combination of density gradient centrifugation resulted in the stepwise release of intact HBV virions and naked capsids from the exosomes generated by HBV-producing cells. This implies the presence of intact HBV particles encapsulated by the host membrane.
The presence of exosome-encapsulated HBV particles was consequently also verified by suppressing the morphogenesis of MVBs or exosomes. Impairment of MVB- or exosome-generation with small molecule inhibitors has significantly inhibited the release of host membrane-encapsulated HBV particles as well. Likewise, silencing of exosome-related proteins caused a diminution of exosome output, which compromised the budding efficiency of wrapped HBV.
Moreover, electron microscopy images of ultra-thin sections combined with immunogold staining visualized the hidden virus in the exosomal structure. Additionally, the presence of LHBs on the surface of exosomes derived from HBV-expressing cells was also observed.
As expected, these exosomal membrane-wrapped HBV particles can spread productive infection in differentiated HepaRG cells. In HBV-susceptible cells, as LHBs on the membrane surface, this type of exosomal HBV appeared to be uptaken in an NTCP receptor-dependent manner.
Taken together these data indicate that a fraction of intact HBV virions can be released as exosomes. This reveals a so far not described release pathway for HBV. Exosomes hijacked by HBV act as a transporter impacting the dissemination of the virus.
Mechanistic and structural insights into the quality control of the MHC I antigen processing pathway
(2022)
The human body is permanently exposed to its environment and thus to viruses and other pathogens, which require a flexible response and defense. Alongside to the innate immune system, the adaptive immune system provides highly specialized protection against these threats. The major histocompatibility complex class I (MHC I) antigen presentation system is a cornerstone of the adaptive immune system and a major constituent of cellular immunity. Pathogens such as viruses that invade a cell will leave traces in the form of proteins and peptides which are degraded and loaded onto MHC I molecules. MHC I peptide loading is performed by peptide loading complex (PLC) in the membrane of the endoplasmic reticulum as part of a multifaceted and comprehensive quality control machinery. Monitored by multiple layers of quality assurance, the MHC I molecules consequently display the immune status of the cell on its surface. In this context, the captured fragment of the virus serves as a call for help issued by the cell, alerting the adaptive immune system to the infection to mount an appropriate immune response.
The three-dimensional structure as well as the mechanistic details of parts of this complex machinery were characterized in the context of this dissertation. Among other tools, light-modulable nanotools were developed in this thesis, which permit external regulation of cellular processes in temporal and spatial resolution. Furthermore, methods and model systems for the biochemical characterization of cellular signaling cascades, proteins, as well as entire cell organelles were developed, which are likely to influence the field of cellular immunity and protein biochemistry in the future.
This cumulative work comprises a total of six publications whose scientific key advances will be briefly outlined in this abstract. In the introduction, the scientific background as well as the current state of research and methodological background knowledge are conveyed. The results section condenses the main aspects of the publications and links them to each other. Further details can be retrieved from the attached original publications.
In “Semisynthetic viral inhibitor for light control of the MHC I peptide loading complex, Winter, Domnick et al., Angew Chem Int Ed 2022” a photocleavable viral inhibitor of the peptide loading complex was produced by semi-synthesis. This nanotool was shown to be suitable for both purifying the PLC from human Raji cells as well as reactivating it in a light-controlled manner. Thus, this tool establishes the isolation of a fully intact and functional peptide loading complex for biochemical characterization. In addition, a novel flow cytometric analysis pipeline for microsomes was developed, allowing cellular vesicles to be characterized with single organelle resolution, similar to cells.
In “Molecular basis of MHC I quality control in the peptide loading complex, Domnick, Winter et al., Nat Commun 2022” the peptide loading complex was reconstituted into large nanodiscs, and a cryo-EM structural model of the editing module at 3.7 Å resolution was generated. By combining the structural model with in vitro glycan editing assays, an allosteric coupling between peptide-MHC I assembly and glycan processing was revealed, extending the known model of MHC I loading and dissociation from the PLC. These mechanisms provide a prototypical example for endoplasmic reticulum quality control.
In a related context, in “Structure of an MHC I–tapasin–ERp57 editing complex defines chaperone promiscuity, Müller, Winter et al., Nat Commun 2022” a recombinantly assembled editing module comprised of MHC I-tapasin-ERp57 was crystallized for X-ray structural biology. The resulting crystal structure at a resolution of 2.7 Å permitted the precise identification of characteristic features of the editing module and particularly of the peptide proofreading mechanism of tapasin. This study provided pivotal insights into the tapasin-mediated peptide editing of different MHC I allomorphs as well as similarities to TAPBPR-based MHC I peptide proofreading.
In “TAPBPR is necessary and sufficient for UGGT1-mediated quality control of MHC I, Sagert, Winter et al. (in preparation)” novel insights concerning the peptide proofreader TAPBPR and its close interplay with the folding sensor and glucosyltransferase UGGT1 were obtained. It was shown that TAPBPR is an integral part of the second level of endoplasmic quality control and is indispensable for effective MHC I coordination by UGGT1.
In “Light-guided intrabodies for on-demand in situ target recognition in human cells, Joest, Winter et al., Chem Sci 2021” intracellular nanobodies were equipped with a photocaged target recognition domain by genetic code expansion via amber suppression. These intrabodies, acting as high-affinity binding partners endowed with a fluorophore, could be used in a light-triggered approach to instantaneously visualize their target molecule...