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Inorganic phosphate is one of the most abundant and essential nutrients in living organisms. It plays an indispensable role in energy metabolism and serves as a building block for major cellular components such as the backbones of DNA and RNA, headgroups of phospholipids and in posttranslational modifcations of many proteins. Disturbances in cellular phosphate homeostasis have a detrimental effect on the viability of cells. There- fore, both the import and export of phosphate is strictly regulated in eukaryotic cells. In the eukaryotic model organism Saccharomyces cerevisiae, the uptake of phosphate is carried out either by transporters with high affinity or by transporters with low affinity, depending on the cytosolic phosphate concentration. While structures are available for homologues of the high-affinity transporters, no structures of low-affinity transporters have been solved so far. Interestingly, only the low-affinity transporters have a regulatory SPX domain, which is found in various proteins involved in phosphate homeostasis.
In this work, structures of Pho90 from Saccharomyces cerevisiae, a low-affinity phosphate transporter, were solved by cryo-EM, providing insights into its transport mechanism. The dimeric structure resembles the structures of proteins of the divalent anion symporter superfamily (DASS) and of mammalian transporters of the solute carrier 13 (SLC13) family. The transmembrane domain of each protomer consists of 13 helical elements and can be subdivided into scaffold and transport domains. The structure of ScPho90 in the presence of phosphate shows the phosphate binding site within the transporter domain in an outward-open conformation with a bound phosphate ion and two sodium ions. In the absence of phosphate, an asymmetric dimer structure was determined, with one protomer adopting an inward-open conformation. While the dimer contact and the scaffold domain are identical in both conformations, the transport domain is rotated by about 30° and shifted by 11 Å towards the cytoplasmic side, leading to the accessibility of the binding pocket from the cytoplasm. Based on these findings and by comparison with known structures, a phosphate transport mechanism is proposed in the present work that involves substrate binding on the extracellular side, conformational change by a rigid-body motion of the transport domain, in an "elevator-like" motion, and substrate release into the cytoplasm. The regulatory SPX domain is not well resolved in the ScPho90 structures, so that no direct conclusions were drawn about its regulatory mechanism. The findings provide new insights into the function and mechanism of eukaryotic low-affinity phosphate transporters.
While eukaryotic cells express various phosphate import proteins, most eukaryotes have only a single highly conserved and essential phosphate exporter. These exporters show no sequence homology to other transporters of known structure, but also possess a regulatory SPX domain. In this work, the structural basis for eukaryotic phosphate export is investigated by elucidating the structures of the homologous phosphate exporters Syg1 from Saccharomyces cerevisiae and Xpr1 from Homo sapiens, using cryo-EM. The structures of ScSyg1 and HsXpr1 show a conserved homodimeric structure and the transmembrane part of each protomer consists of 10 TM helices. Helix TM1 establishes the dimer contact by means of a glycine zipper motif, which is a known oligomerization motif. Helices TM2-5 form a hydrophobic pocket that has density for a lipid molecule. Whether the lipid binding into the hydrophobic pocket has an allosteric effect on the phosphate export activity or only serves protein stabilization is not known. Helices TM5-10 form a six-helix bundle, which constitutes a putative phosphate translocation pathway in its center. This bundle is formed by the protein sequence annotated as EXS domain.
The respective phosphate translocation pathways of ScSyg1 and HsXpr1 show structural differences. While the translocation pathway in HsXpr1 is accessible from the cytoplasm, in ScSyg1 it is closed by a large loop of the SPX domain. Interestingly, this loop is not conserved in higher eukaryotes and is therefore not present in HsXpr1. Another difference are distinct conformations of helix TM9. In ScSyg1, TM9 adopts a kinked conformation, which results in the translocation pathway being open to the extracellular side. In contrast, TM9 adopts a straight conformation in HsXpr1, resulting in the placement of a highly conserved tryptophane residue in the middle of the translocation pathway. As a result, the translocation pathway in HsXpr1 is closed to the extracellular side.
This thesis investigates the structure of the translocase of the outer membrane (TOM) complex in mitochondria, focusing on the TOM holo complex through single-particle electron cryo-microscopy (cryoEM) complemented by mass spectrometry and computational structure prediction. Mitochondria, crucial for energy production in eukaryotic cells, import most of their proteins from the cytoplasm. These proteins enter through the TOM complex, which in its core form consists of a membrane-embedded homodimer of Tom40 pores, two Tom22 cytoplasmic receptors, and six small TOM stabilizing subunits (Tom7, Tom6, and Tom5). The holo complex includes two additional subunits, Tom70 and Tom20, whose stoichiometry and positioning are less understood due to their easy dissociation during isolation of the complex. CryoEM analysis revealed the high-resolution structure of the Neurospora crassa TOM core complex at 3.3 Å, containing all core subunits, and the presence of a central phospholipid causing the Tom40 dimer to tilt to 20°. Furthermore, a 4 Å resolution map indicated the binding of a precursor protein as it transitions through the translocation barrel. Finally, at 6-7 Å resolution, the structure of the TOM holo complex highlighted Tom20's flexibility as it interacts with the core complex, emphasizing its role in protein translocation. This work provides significant insights into the architecture and functioning of the TOM complex, contributing to the understanding of mitochondrial protein import mechanisms.
Life and biological resilience rely on the execution of precise gene expression profiles. A key mechanism to ensure cellular homeostasis is the regulation of protein synthesis. Recent studies have unveiled an intrinsic regulatory capacity of ribosomes, previously considered mere executors of mRNA translation. Neurons in particular finely regulate protein synthesis, at both global and local levels. This sustains their complex morphology and allows them to rapidly transmit, integrate, and respond to external stimuli. In this thesis, I investigated the neuronal ribosome and how subcellular environments and physiological perturbations shape it, by profiling its molecular composition, functional interconnections, and cellular distribution.
First, I used genetic engineering, biochemical purification, and mass spectrometry, to characterize in an unbiased manner the translation machinery specifically from excitatory and inhibitory neurons of the mouse cortex. I found that neuronal ribosomes commonly interact with RNA-binding proteins, components of the cytoskeleton, and proteins associated with the endoplasmic reticulum and vesicles. In line with the requirement for local protein synthesis in the distal parts of neurons, we observed that neuronal ribosomes preferentially interact with proteins involved in cellular transport. Remarkably, I observed a strong association between ribosomes and pre-synaptic vesicles, which suggests a potential regulatory interaction between local translation and neuronal activity.
Intriguingly, I and others have observed mRNAs encoding for core ribosomal proteins (RPs) among the genes most enriched in neuronal processes. This observation challenges two historical assumptions of ribosome biology: (1) new RPs are incorporated only into newly forming ribosomes, and (2) this incorporation occurs only in the nucleus and perinuclear region. In my PhD, I aimed to directly test these two assumptions and if proven wrong ask whether and why neurons would localize RP mRNAs far from their known assembly site.
Employing a combination of metabolic labeling and highly sensitive mass spectrometry techniques, I discovered that a subset of RPs rapidly and dynamically binds on and off mature ribosomes. Strikingly, this incorporation does not depend on the supply of new ribosomes from the nucleus. Therefore, my data refuted the assumption that ribosomes are built and degraded as a unit and revealed a more dynamic view of these machines, which can actively exchange core components. In particular, I found that the association of certain exchanging RPs is influenced by location (e.g., cell body versus neurites) and cellular state (e.g., post-oxidative stress). Neurons may use this mechanism to repair and/or specialize their protein synthesis machinery in a rapid and context-dependent manner.
Finally, I asked whether some steps of ribosome biogenesis could also take place in distal processes. Although most steps of ribosome assembly occur within the nucleus, the final stages of maturation are known to occur in the cytosol. By combining several imaging and biochemical approaches, I found that cytosolic (but not nuclear) pre-ribosomal particles are present in neuronal processes. Through the incorporation of new RPs into these immature particles, neurons may be able to locally “turn on” previously incompetent ribosomes. This may enable regions near synapses to enhance and customize their translational capacity, independently of the central pool of ribosomes from the cell body. Indeed, I observed that synaptic plasticity induces a maturation of cytosolic pre-ribosomes.
In summary, this thesis shows how neuronal ribosomes can sense cellular states, respond by adjusting their core composition, and in doing so influence the local capacity for protein synthesis. By overturning long-held assumptions in ribosome biology, this work highlights new molecular mechanisms of gene expression and enriches our understanding of the rapid and dynamic strategies cells employ to operate, thrive, and adaptively respond to environmental changes.
This dissertation constitutes a series of successive research papers, starting with the characterization of various optogenetic tools up to the establishment of purely optical electrophysiology in living animals.
Optogenetics has revolutionized neurobiology as it allows stimulation of excitable cells with exceptionally high spatiotemporal resolution. To cope with the increasing complexity of research issues and accompanying demands on experimental design, the broadening of the optogenetic toolbox is indispensable. Therefore, one goal was to establish a wide variety of novel rhodopsin-based actuators and characterize them, among others, with respect to their spectral properties, kinetics, and efficacy using behavioral experiments in Caenorhabditis elegans. During these studies, the applicability of highly potent de- and hyperpolarizers with adapted spectral properties, altered ion specificity, strongly slowed off-kinetics, and inverted functionality was successfully demonstrated. Inhibitory anion channelrhodopsins (ACRs) stood out, filling the gap of long-sought equivalent hyperpolarizing tools, and could be convincingly applied in a tandem configuration combined with the red-shifted depolarizer Chrimson for bidirectional stimulation (Bidirectional Pair of Opsins for Light-induced Excitation and Silencing, BiPOLES). A parallel study aimed to compare various rhodopsin-based genetically encoded voltage indicators (GEVIs) in the worm: In addition to electrochromic FRET-based GEVIs that use lower excitation intensity, QuasAr2 was particularly convincing in terms of voltage sensitivity and photostability in C. elegans. However, classical optogenetic approaches are quite static and only allow perturbation of neural activity. Therefore, QuasAr2 and BiPOLES were combined in a closed-loop feedback control system to implement the first proof-of-concept all-optical voltage clamp to date, termed the optogenetic voltage clamp (OVC). Here, an I-controller generates feedback of light wavelengths to bidirectionally stimulate BiPOLES and keep QuasAr’s fluorescence at a desired level. The OVC was established in body wall muscles and various types of neurons in C. elegans and transferred to rat hippocampal slice culture. In the worm, it allowed to assess altered cellular physiology of mutants and Ca2+-channel characteristics as well as dynamical clamping of distinct action potentials and associated behavior.
Ultimately, the optogenetic actuators and sensors implemented in the course of this cumulative work enabled to synergistically combine the advantages of imaging- and electrode-based techniques, thus providing the basis for noninvasive, optical electrophysiology in behaving animals.
The EMT-transcription factor ZEB1 has been intensively studied in solid cancers, where it is expressed at the invasive front and in cancer-associated fibroblasts (CAFs). In tumour cells, ZEB1 has been involved in multiple steps of cancer progression including stemness, metastasis and therapy resistance, yet its role in the tumour-microenvironment is largely unknown. Here, the role of Zeb1 in CAFs was investigated using mouse models reflecting different tumour stages in immunocompetent fibroblast specific Zeb1 KO mice. Fibroblast-specific depletion of Zeb1 accelerated tumour growth in the inflammation driven AOM/DSS tumour initiation model, reduced tumour growth and invasion in the sporadic AOM/P53 model and reduced liver metastasis in a progressed orthotopic transplantation model. Immunohistochemical and single cell RNA-sequencing analysis showed that Zeb1 ablation resulted in attenuated expression of the myofibroblast marker aSMA and reduced ECM deposition, indicating a shift among fibroblast subpopulations. Modulation of CAFs was furthermore associated with increased inflammatory signaling in fibroblasts resulting in immune infiltration into primary tumours and exaggerated inflammatory signaling in T cells, B cells and macrophages. These changes in the tumour microenvironment were associated with increased efficacy of immune checkpoint inhibition therapy. In summary, Zeb1 expression in CAFs was identified as a potential target to block immunosuppression and metastatic dissemination in colon cancer.
This cumulative thesis discusses the development of optimized force field parameters for Magnesium and resulting improved simulations of Magnesium-RNA interactions, including the in silico exploration of binding sites. This thesis is based on four publications as well as unpublished data. A fifth publication that was written during the time of the Ph.D. is discussed in the Appendix. This publication analyzes monovalent ion-specific effects at mica surfaces.
Nucleic acids in general and RNA in particular are fundamental to life itself. Especially in the folding and function of RNA, metal cations are crucial to screen the negatively charged nucleic acid backbones to allow for complex functional structures. They stabilize the tertiary structure of RNA and even drive its folding. Furthermore, similarly to proteins, RNAs can catalyze multiple reactions, rather than consisting of the 20 amino acids of a protein, RNA constitues of only four different building blocks. Metal cations play an important role here as additional cofactors. One essential ion is Magnesium (Mg2+), commonly referred to as the most important cofactor for nucleic acids. Mg2+ carries two positive charges. Its comparably small size and high charge result in a high charge density that has strong polarizing effects on its surroundings. Furthermore, Mg2+ forms a sharply defined first hydration shell with an integer number of coordinating water molecules. As a result, an exclusion zone exists around the ion within which no water molecules are observed. Moreover, Mg2+ displays a high solvation free energy and a low exchange rate of waters from its first hydration shell. Finally, it contains a strong preference towards oxygens . Together, this makes Mg2+ a particularly well suited interaction partner for the charged non-bridging phosphate oxygens on nucleic acid backbones and explains its crucial biological role.
The immense number of physiological and technological functions and applications indicates the significant scientific attention Mg2+ received. In experimental studies, however, severe difficulties arise for multiple reasons: Mg2+ is spectroscopically silent and cannot be detected directly by resonance techniques like NMR or EPR. Indirect observation is possible, either by detecting changes in the overall RNA structure with and without bound Mg2+, or by replacing the Mg2+ ion with another spectroscopically visible ion. In the latter, however, it cannot be guaranteed that the altered ion does not also alter the interaction site or even the whole structure. Another detection method is X-ray crystallography, but here challenges arise from Mg2+ being almost indistinguish- able from other ions as well as from water if not for very high resolutions and precise stereochemical considerations.
Alternatively, molecular dynamics (MD) simulations can be performed, with the power of adding atomistic insight to the interplay of metal cations and nucleic acids. MD simulations, however, are only as accurate as their underlying interaction models and the development of accurate models for the description of Mg2+ faces challenges especially in describing three properties:
(i) Polarizability. Commonly used simple models like the 12-6 type Lennard-Jones model typically fail to reproduce simultaneously thermodynamic and structural properties of a single ion in water. Alternative strategies include the use of a 12-6-4 type Lennard-Jones potential as proposed by Li and Merz, where the additional r−4 term explicitly accounts for polarization effects. The resulting Lennard-Jones potential is thereby more attractive and more long-ranged than for typical models of the 12-6 type.
(ii) Kinetics. Most Mg2+ models either fully ignore considerations about the timescales on which water exchanges from the first hydration shell of the ion or use inappropriate methodology to calculate the underlying kinetics. A realistic characterization of the involved timescales is imperative to be able to describe a seemingly simple process like the transition from inner-to-outer sphere binding and vice versa. This transition governs most biochemical reactions involving Mg2+ and therefore subsequent processes can only by as fast as the transition itself. However, already the previous step – the exchange of a water from the first hydration shell of the ion – is described my current Mg2+ models up to four orders of magnitude too slowly, which makes the observation of such events on the timescale of a typical simulation difficult or even impossible. Alln ́er et al. [48] as well as Lemkul and MacKerell explicitly considered the exchange rate into their parameter optimization procedure. To compute the rate, both studies applied Transition State Theory along a single reaction coordinate – the distance towards one of the exchanging waters. However, it could be shown that the water exchange from the first hydration shell requires at least the consideration of both exchanging water molecules in order to be able to realistically record the underlying rate using Transition State Theory. Furthermore, the model of Alln ́er et al. significantly underestimates the free energy of solvation of the ion.
(iii) Interactions between Mg2+ and nucleic acids. Typically, ionic force field parame- terization concentrates on the optimization of solution properties. The trans- ferability of these solution optimized parameters towards interactions with biomolecules, however, often fails.
Post-translational modifications (PTMs) of cell fate regulating proteins determine their stability, localization and function and control the activation of cell protective signaling pathways. Particularly in aberrantly dividing cancer cells the surveillance of cell cycle progression is essential to control tumorigenicity. In a variety of carcinomas, lymphomas and leukemias, the tumor-suppressive functions of the apoptosis- and senescence-regulating promyelocytic leukemia protein (PML) is controlled by numerous PTMs. PML poly-ubiquitylation and polySUMOylation at several lysine (K) residues induce PML degradation that is correlated to a progressive and invasive cancer phenotype. Besides several known E3 ubiquitin protein ligases that are involved in PML degradation, less is known about PML-specific deubiquitylases (DUBs), the respective DUB-controlled ubiquitin conjugation sites and the functional consequences of PML (de)ubiquitylation. Here, we show that the pro-tumorigenic DUB USP22 critically regulates PML protein stability by modifying PML residue K394 in advanced colon carcinoma cells in vitro and that this modification also impacts the homeostasis and function of the leukemia-associated mutant variant PML-RARα. We found that ablation of USP22 decreases PML mono-ubiquitylation and correlates with a prolonged protein half-live in colon carcinoma and acute promyelocytic leukemia (APL) cell lines. Additionally, silencing of USP22 enhances interferon and interferon-stimulated gene (ISG) expression in APL cells in vitro, which together with prolonged PML-RARα stability increases the APL cell sensitivity towards differentiation treatment. In accordance with the novel roles of USP22 as suppressor of the interferon response in human intestinal epithelial cells (hIECs), our findings imply USP22-dependent surveillance of PML-RARα stability and interferon signaling in human leukemia cells, revealing USP22 as central regulator of leukemia pathogenesis.
Solute carrier (SLC) are related to various diseases in human and promising pharmaceutical targets but more structural and functional information on SLCs is required to expand their use for drug design and therapy. The 7-transmembrane segment inverted (7-TMIR) fold was identified for the SLC families 4, 23 and 26 in the last decade thus detailed analysis of the structure function relationship of one of these families might also yield insights for the other two. SVCT1 and SVCT2 from the SLC23 family are sodium dependent ascorbic acid transporters in human but structural analysis of the SLC23 family is exclusively based on two homologs – UraA from E. coli and UapA from A. nidulans – yielding two inward-facing and one occluded conformation. In combination with outward-facing conformations from SLC4 transporters, and additional information from the SLC26 family, an elevator transport mechanism for all 7-TMIR proteins was identified but detailed mechanistic features of the transport remain elusive due to the lack of multiple conformations from individual transporters.
To increase the understanding of 7-TMIR protein structure and function in this study, the transport mechanism of SLC23 transporters was analyzed by two strategies including selection of alpaca derived nanobodies and synthetic nanobodies against UraA as prokaryotic model protein of the SLC23 family. The second strategy involved mutagenesis of UraA at functional relevant positions regarding the conformational change during transport. Therefore, available structures of 7-TMIR proteins and less related elevator transporters were analyzed and a common motif identified – the alpha helical inter-domain linkers. The proposed rigid body movement for transport in combination with the characteristic alpha helical secondary structure of the linkers connecting both rigid bodies led to the hypothesis of functional relevance of the linkers and a conformational hinge being located in close proximity to the linkers. These positions were identified and used to modulate the biophysical properties of the transporter. Mutagenesis at three relevant positions led to loss of transport functionality and these UraA variants could be recombinantly produced and purified to further examine the underlying mechanistic effects. The variants UraAG320P and UraAP330G from the periplasmic inter-domain linker showed increased dimerization and thermal stability as well as substrate binding in solution. The substrate affinity of UraAG320P was identified to be 5-fold higher compared to the wildtype. The solvent accessibility of the substrate binding site in UraAG320P and UraAP330G revealed reduced open probability that indicated an altered conformational space compared to UraAWT. This phenomenon was analyzed in more detail by differential hydrogen-deuterium exchange mass spectrometry and the results supported the hypothesis of a reduced open probability and gave further insights into the impact of the two mutations in the periplasmic inter-domain linker in UraA.
This thesis further presents strategies for phage display selection of nanobodies with epitope bias and a post selection analysis pipeline to identify nanobodies with desired binding characteristics. Thereby, whole cell transport inhibition highlighted periplasmic epitope binders and conformational selectivity. A cytoplasmic epitope could be identified by pulldown with inside-out membrane vesicles for one cytoplasmic side binder. Thermal stabilization analysis of the target protein in differential scanning fluorometry was performed in presence of two different nanobodies to identify simultaneous binding by additional thermal stabilization respectively competition by intermediate melting temperatures. Combination of epitope information with simultaneous DSF could be used to identify the stabilization of different UraA conformations by a set of binders and presents a general nanobody selection strategy for other SLCs. Synthetic nanobodies (sybodies) were also included in the analysis pipeline and Sy45 identified as promising candidate for co-crystallization that gave rise to UraAWT crystals in several conditions in presence or absence of uracil. Similar crystals could be obtained in combination with UraAG320P that were further optimized to gain structural information on this mutant. The structure was solved by molecular replacement and the model refined at 3.1 Å resolution confirming the cytoplasmic epitope of Sy45 as predicted by the selection pipeline. The stabilized conformation was inward-facing similar to the reported UapA structure but significantly different to the previously reported inward-facing structure of UraA. The structure further confirmed the structural integrity of the UraA mutant G320P. Despite the monomeric state of UraA in the structure, the gate domain aligned reasonably well with the gate domain of the previously published dimeric UraA structure in the occluded conformation and allowed detailed analysis of the conformational transition in UraA from inward-facing to occluded by a single rigid body movement. Thereby little movement in the gate domain of UraA was observed in contrast to a previously reported transport mechanism. Core domain rotation around a rotation axis parallel to the substrate barrier was found to explain the major part of conformational transition from inward-facing to occluded and experimentally supported the hypothesized mechanism by Chang et al. (2017). Additionally, the conformational hinge around position G320 in UraA could be identified as well as the impact of the backbone rigidity introduced by the highly conserved proline residue at position 330 in UraA on the conformational transition. This position was found to serve as anchoring point the inter-domain linker and determines the coordinated movement of inter-domain linker and core domain. The functional analysis further highlighted the requirement of alpha helical secondary structure within the inter-domain linker that serves as amphipathic structural entity that can adjust to changed core-gate domain distances and angles during transport by extension/compression or bending while preserving the rigid linkage.
The applied strategies to modulate the conformational space of UraA by mutagenesis at the hinge positions in the inter-domain linkers is transferrable to other transporters and might facilitate their structural and functional characterization.
Further, this study discusses the conformational thermostabilization of UraA that is based on increased melting temperatures upon restriction of its conformational freedom. The term ‘conformational thermostabilization’ introduced by Serrano-Vega et al. (2007) could be experimentally supported and the direct correlation between the conformational freedom and thermostabilization was qualitatively analyzed for UraA. The concept of conformational thermostabilization might help in characterization of other dynamic transport systems as well.
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.
Die Beteiligung an Schlüsselfunktionen in zellulären Signalwegen macht Kinasen zu einem vielversprechenden Ansatzpunkt in der Wirkstoffentwicklung bei verschiedenen menschlichen Erkrankungen wie z.B. Krebs oder auch Autoimmun- und Entzündungskrankheiten. Die Prävention von post-translationalen Modifikationen durch Phosphorylierung und somit die Regulierung der nachgeschalteten Signalwege ist das Ziel von Kinaseinhibitoren. Die katalytische Aktivität von Kinasen ist abhängig von ATP, welches im hochkonservierten aktiven Zentrum bindet. Bedingt durch diese kinomweite hohe Konservierung stellt die Entwicklung von hoch selektiven ATP-mimetischen Inhibitoren eine Herausforderung dar. Typische ATP-Mimetika sind flach und die oft hydrophoben Moleküle weisen meist eine große Zahl an frei rotierbaren Bindungen auf. Um das aus dieser Flexibilität hervorgehende Problem der teils mangelnden Selektivität zu umgehen, kann eine bioaktive Konformation des Inhibitors durch Makrozyklisierung fixiert werden. Als Konsequenz dieser konformationellen Einschränkung können die entropischen Kosten während des Bindens reduziert werden und folglich zu einer gesteigerten Affinität gegenüber der Kinase führen.
Der Grundstein dieser Arbeit war der makrozyklische Pyrazolo[1,5-a]pyrimidin basierte FLT3 Kinaseinhibitor ODS2004070 (37). Im Rahmen eines kinomweiten Screenings konnten hohe Affinitäten zu verschiedensten Kinasen detektiert werden, was 37 zu einer guten Leitstruktur für das Design von potenten und selektiven Kinaseinhibitoren machte. Im Rahmen dieser Arbeit blieb das literaturbekannte Pyrazolo[1,5-a]pyrimidin basierte ATP-mimetische Bindemotiv sowie das makrozyklische Grundgerüst 37 bis auf einige wenige Variation unverändert.
Strukturelle Optimierungen zur Fokussierung der Selektivität wurden am sekundären Amin zwischen Bindemotiv und Linker als auch über die freie Carbonsäure durchgeführt. Mit einer Anzahl von mehr als 430 identifizierten Phosphorylierungsstellen ist die pleiotropisch und konstitutiv aktive Casein Kinase 2 (CK2) an verschiedensten zellulären Prozessen wie dem Verlauf des Zellzyklus, der Apoptose oder der Transkription regulatorisch beteiligt. Die Fehlregulation von CK2 wird häufig mit der Pathologie von Krankheiten wie zum Beispiel Krebs assoziiert, was CK2 zu einem vielversprechenden Ziel klinischer Untersuchungen macht.
Im Rahmen des CK2-Projekts war es möglich, durch spezifische Modifikationen an 37, die hoch selektiven und potenten CK2-Inhibitoren 47 und 60 zu entwickeln. Ebenfalls gezeigt wurde, dass kleine strukturelle Veränderungen, wie z.B. Makrozyklisierung, einen signifikanten Effekt auf Selektivität und Potenz des Inhibitors haben kann.
Weiter Untersuchungen der Verbindungen lenkten den Fokus weiterer Arbeiten u.a. auf die Serin/Threonin Kinase 17A (STK17A) oder auch death-associated protein kinase-related apoptosis-inducing protein kinase 1 (DRAK1) genannt. Sie ist Teil der DAPK Familie und gehört zusammen mit anderen Kinasen zu den weniger erforschten Kinasen. Bis heute ist nicht viel über ihre zellulären Funktionen und die Beteiligung an pathophysiologischen Prozessen bekannt. Berichtet wurde jedoch eine Überexpression in verschiedenen Formen von Hirntumoren des zentralen Nervensystems (Gliom). Strukturelle Modifikationen, unter Erhalt des makrozyklischen Grundgerüsts 37, führten zu dem hoch selektiven und potenten DRAK1 Inhibitor 121, der alle Kriterien für eine chemical probe Verbindung erfüllt.
Ein weiteres Ziel dieser Arbeit war die AP-2-assoziierte Protein Kinase 1 (AAK1) aus der NAK Familie, bestehend aus AAK1, BIKE und GAK. Sie ist als potenzielles therapeutisches Ziel für viele verschieden Krankheiten wie z.B. neuropathische Schmerzen, Schizophrenie und Parkinson identifiziert. Durch die Regulierung der Clathrin-mediierten Endozytose ist AAK1 an intrazellulären Bewegungen verschiedener nicht zusammenhängenden RNS- und DNSViren, wie beispielsweise HCV, DENV oder EBOV, beteiligt. Ebenfalls berichtet wurde eine mögliche Assoziation mit dem SARS-CoV-2 Virus, was das Interesse an neuen selektiven AAK1 Inhibitoren verstärkte. Die Entwicklung der hochpotenten und selektiven AAK1 Inhibitoren 61 und 63 basierte ebenfalls auf dem makrozyklischen Grundgerüst 37, das bereits im CK2- und DRAK1-Projekt verwendet wurde.
Zusammenfassend lässt sich sagen, dass es im Rahmen dieser Arbeit gelungen ist, ausgehend von einem höchst unselektiven makrozyklischen Grundgerüst, hochpotente und selektive Kinaseinhibitoren für CK2, DRAK1 und AAK1 zu entwickeln und zu charakterisieren. Im Zuge von Untersuchungen verschiedener Struktur-Wirkungsbeziehungen wurde gezeigt, dass es durch geringfügige strukturelle Modifikationen möglich ist, die kinomweite Selektivität zu variieren und auf eine Kinase zu fokussieren. Diese Arbeit brachte nicht nur die erwähnten Inhibitoren hervor, sondern bildet auch die Grundlage für weitere Projekte zur Entwicklung von hoch potenten und selektiven Verbindungen als potenzielle chemische Werkzeuge für den Einsatz in der Forschung.