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The insertion of membrane proteins requires proteinaceous complexes in the cytoplasm, the membrane, and the lumen of organelles. Most of the required complexes have been described, while the components for insertion of β‐barrel‐type proteins into the outer membrane of chloroplasts remain unknown. The same holds true for the signals required for the insertion of β‐barrel‐type proteins. At present, only the processing of Toc75‐III, the β‐barrel‐type protein of the central chloroplast translocon with an atypical signal, has been explored in detail. However, it has been debated whether Toc75‐V/ outer envelope protein 80 (OEP80), a second protein of the same family, contains a signal and undergoes processing. To substantiate the hypothesis that Toc75‐V/OEP80 is processed as well, we reinvestigated the processing in a protoplast‐based assay as well as in native membranes. Our results confirm the existence of a cleavable segment. By protease protection and pegylation, we observed intermembrane space localization of the soluble N‐terminal domain. Thus, Toc75‐V contains a cleavable N‐terminal signal and exposes its polypeptide transport‐associated domains to the intermembrane space of plastids, where it likely interacts with its substrates.
Makorins are evolutionary conserved proteins that contain C3H-type zinc finger modules and a RING E3 ubiquitin ligase domain. In Drosophila, maternal Makorin 1 (Mkrn1) has been linked to embryonic patterning but the mechanism remained unsolved. Here, we show that Mkrn1 is essential for axis specification and pole plasm assembly by translational activation of oskar (osk). We demonstrate that Mkrn1 interacts with poly(A) binding protein (pAbp) and binds specifically to osk 3’ UTR in a region adjacent to A-rich sequences. Using Drosophila S2R+ cultured cells we show that this binding site overlaps with a Bruno1 (Bru1) responsive element (BREs) that regulates osk translation. We observe increased association of the translational repressor Bru1 with osk mRNA upon depletion of Mkrn1, indicating that both proteins compete for osk binding. Consistently, reducing Bru1 dosage partially rescues viability and Osk protein level in ovaries from Mkrn1 females. We conclude that Mkrn1 controls embryonic patterning and germ cell formation by specifically activating osk translation, most likely by competing with Bru1 to bind to osk 3’ UTR.
The hydrogen-dependent carbon dioxide reductase is a soluble enzyme complex that directly utilizes hydrogen (H2) for the reduction of carbon dioxide (CO2) to formate in the first step of the acetyl-coenzyme A- or Wood-Ljungdahl pathway (WLP). HDCR consists of 2 catalytic subunits, a hydrogenase and a formate dehydrogenase (FDH) and two small subunits carrying iron-sulfur clusters. The enzyme complex has been purified and characterized from two acetogenic bacteria, from the mesophile Acetobacterium woodii and, recently, from the thermophile Thermoanaerobacter kivui. Physiological studies toward the importance of the HDCR for growth and formate metabolism in acetogens have not been carried out yet, due to the lack of genetic tools. Here, we deleted the genes encoding HDCR in T. kivui taking advantage of the recently developed genetic system. As expected, the deletion mutant (strain TKV_MB013) did not grow with formate as single substrate or under autotrophic conditions with H2 + CO2. Surprisingly, the strain did also not grow on any other substrate (sugars, mannitol or pyruvate), except for when formate was added. Concentrated cell suspensions quickly consumed formate in the presence of glucose only. In conclusion, HDCR provides formate which was essential for growth of the T. kivui mutant. Alternatively, extracellularly added formate served as terminal electron acceptor in addition to CO2, complementing the growth deficiency. The results show a tight coupling of multi-carbon substrate oxidation to the WLP. The metabolism in the mutant can be viewed as a coupled formate + CO2 respiration, which may be an ancient metabolic trait.
Brain metastases are the most common intracranial tumor in adults and are associated with poor patient prognosis and median survival of only a few months. Treatment options for brain metastasis patients remain limited and largely depend on surgical resection, radio- and/or chemotherapy. The development and pre-clinical testing of novel therapeutic strategies require reliable experimental models and diagnostic tools that closely mimic technologies that are used in the clinic and reflect histopathological and biochemical changes that distinguish tumor progression from therapeutic response. In this study, we sought to test the applicability of magnetic resonance (MR) spectroscopy in combination with MR imaging to closely monitor therapeutic efficacy in a breast-to-brain metastasis model. Given the importance of radiotherapy as the standard of care for the majority of brain metastases patients, we chose to monitor the post-irradiation response by magnetic resonance spectroscopy (MRS) in combination with MR imaging (MRI) using a 7 Tesla small animal scanner. Radiation was applied as whole brain radiotherapy (WBRT) using the image-guided Small Animal Radiation Research Platform (SARRP). Here we describe alterations in different metabolites, including creatine and N-acetylaspartate, that are characteristic for brain metastases progression and lactate, which indicates hypoxia, while choline levels remained stable. Radiotherapy resulted in normalization of metabolite levels indicating tumor stasis or regression in response to treatment. Our data indicate that the use of MR spectroscopy in addition to MRI represents a valuable tool to closely monitor not only volumetrical but also metabolic changes during tumor progression and to evaluate therapeutic efficacy of intervention strategies. Adapting the analytical technology in brain metastasis models to those used in clinical settings will increase the translational significance of experimental evaluation and thus contribute to the advancement of pre-clinical assessment of novel therapeutic strategies to improve treatment options for brain metastases patients.
Die vorliegende kumulative, publikationsbasierte Disserationsschrift zum Thema „Diversität und Zoogeographie metazoischer Fischparasiten aus dem Südpolarmeer“ gibt einen zusammenfassenden Überblick über die von mir verfasseten ausgewählten drei (ISI-)Publiaktionen. Diese sind im Anhang (Kapitel 6) in chronologischer Reihenfolge aufgeführt. Die Verweise zu den Publikationen sind im Text mit den römischen Ziffern I-III (s.u.) gekennzeichnet. Die für die Promotion relevanten Publikationen wurden wie folgt publiziert:
I Münster J, Kochmann J, Klimpel S, Klapper R, Kuhn T (2016) Parasite fauna of Antarctic Macrourus whitsoni (Gadiformes: Macrouridae) in comparison with closely related macrourids. Parasites & Vectors 9:403
II Münster J, Kochmann J, Grigat J, Klimpel S, Kuhn T (2017) Parasite fauna of the Antarctic dragonfish Parachaenichthys charcoti (Perciformes: Bathydraconidae) and closely related Bathydraconidae from the Antarctic Peninsula, Southern Ocean. Parasites & Vectors 10:235
III Kuhn T, Zizka VMA, Münster J, Klapper R, Mattiucci S, Kochmann J, Klimpel S (2018) Lighten up the dark: metazoan parasites as indicators for the ecology of Antarctic crocodile icefish (Channichthyidae) from the north-west Antarctic Peninsula. PeerJ 6, e4638
Diese drei Publikationen sind im Ergebnisteil (Kapitel 2) separat zusammengefasst und folgend im gemeinsamen Kontext diskutiert (Kapitel 3).
To survive and thrive in nature, animals need to adapt their behavior to their environment. Behavioral adaptation is primarily due to changes within the brain and involves changes in the brain proteome (the collection of proteins in the brain). However, thus far very few studies have examined the proteomic changes during behavioral adaptation. Hence, with this work I set out to determine the proteomic changes induced in the brain of zebrafish larvae undergoing behavioral adaptation. Specifically, I examined the changes induced by adaptation to the natural challenge of strong water currents. To this end I took advantage of an assay developed by my collaborators Luis Castillo and Soojin Ryu. In this assay 5 days old zebrafish larvae were exposed to strong water currents. Subsequently they exhibited a reduction in cortisol response and initial locomotion, and increased rheotaxis, as defined by increased swimming directly against the water current when re-exposed to the water current. I employed this assay to investigate the changes to the larval zebrafish brain proteome during behavioral adaptation. Furthermore, I developed a method for extracting larval brains and prepare them for mass-spectrometric analysis. This work not only allowed the comparison of the brain proteome of naïve and behaviorally-adapted larvae, but also resulted in the most comprehensive proteome of the zebrafish brain observed to date and the first proteome of the larval zebrafish brain. In total 4309 proteins were identified in the brain. When the proteome of naïve and behaviorally adapted larvae were compared 41 proteins were found to be more abundant and 16 to be less abundant in the pre-exposed larvae. Of these 57 proteins, 28 have previously been found to have functions in the brain, 17 with functions identified in other tissues, and 12 proteins that have yet to be described. From examining the most relevant function of each protein I propose a speculative model in which the larval brain undergoes behavioral adaptation and becomes less susceptible to stress (reduction in mecp2 and hsp90 protein), form new neuronal connections (regulation of arid1b, fmn2b, ptpra, mycbp2, and pcyt2), modulate existing connections (regulation of asic1b, calsenilin, ptpra, aplp2, dag1, olfm1b, mycbp2, smad3a, and acvr2a abundance), undergo spatial learning in form of navigating the water vortex (increases in calsenilin, ptpra, and pcyt2), show an elevation in protein turnover (increases in lamp2, Ublcp1, larp4b, and ublcp1), have increased and regulated energy production (increases or reduction in rpia, ldhbb, and mitochondrial proteins; nfs1, eci1, MRPS2B, MRPL4, and mrps2), and a decrease in neurogenesis (reduction in smad3a, and ric8a).
To further investigate proteomic changes during behavioral adaptation, I investigated the translational response by metabolically labeling the larval forebrain with ANL and visualizing the labeled proteins using the fluorescent non-canonical amino acid tagging (FUNCAT). I detected a general increase in translation within the forebrain as a result of the water vortex adaptation, which correlated well with the range of changes observed in the brain proteome. Specifically, a region within the forebrain correlated with a region in the adult zebrafish that is homologous to the mammalian limbic region.
Taken together these results show that during behavioral adaptation, protein synthesis is significantly increased in the larval forebrain, and that throughout the brain regulation of the proteome includes proteins that could support the following functions: changes or modifications in neuronal connectivity, the stress response, spatial learning, changes in energy metabolism and changes in neurogenesis.
Lastly, I set out to provide a new tool for zebrafish researchers. Together with Güney Akbalik I introduced metabolic labeling of newly synthesized RNA using 5-ethynyluridine (EU) and subsequent visualization with a copper catalyzed clickreaction to the zebrafish larvae. With 5 hours of EU incubation I was able to visualize newly synthesized RNA and identify pentylenetetrazole-induced transcriptional increases. With this I showed that EU labeling could be implemented to examining transcriptional changes within the brain of zebrafish larvae.
Metabolic engineering can serve to convert microorganisms to
microbial cell factories with the goal of producing various chemicals. Commonly used strategies to modify metabolic pathways include deletions and overexpression of genes, as well as the introduction of heterologous genes or genes which have been optimized for the host organism or for a reaction of interest. Aside from these classic metabolic engineering strategies, researchers have also implemented pathway compartmentalization strategies, which mimic nature’s strategies of colocalizing enzymes for pathway optimization.
In this thesis, classic metabolic engineering strategies were combined with pathway compartmentalization strategies. For pathway compartmentalization, mitochondria and peroxisomes were harnessed, and additionally a new strategy to create artificial subcellular organelles was evaluated. In the latter approach, the so-called Zera peptide was fused to the enzymes of interest. Zera consists of the first 113 amino acids of the plant storage protein γ-Zein (Zea mays). Natively, plant storage proteins accumulate in endoplasmic reticulum (ER)-derived vesicles in plant seeds and serve as an amino acid source for the germinating plant. In this thesis, it was shown that Zera also induces the formation of artificial, ER-derived vesicles in Saccharomyces cerevisiae. Furthermore, it was shown that Zera fusion enzymes remained active, albeit with sometimes reduced activity.
In line with the goal of compartmentalizing pathways in these artificial, Zera-induced vesicles, a new tool was developed to determine the pH in the ER of S. cerevisiae and in the ER-derived vesicles. pHluorin, a pH-sensitive green fluorescent protein (GFP) variant, is commonly used to analyze the cytosolic pH or the pH of subcellular organelles. In this thesis, it was shown that pHluorin has very low fluorescence intensity and pH sensitivity in the ER and in Zera-induced ER-derived vesicles. Therefore, a superfolder variant of pHluorin was developed which allows reliable pH measurements in these compartments and can be used to analyze whether the organellar or vesicular pH suits a pathway of interest....
The adult mammalian heart is a non-regenerative organ that fails to recover neither functionally nor structurally after insults. Although, reports show that the presences of mitotic nuclei after pathological or physiological cardiac stress in humans, it is widely accepted that the regenerative capacity of the human heart is immensely inadequate to restore the loss of cardiomyocytes (CMs) (Beltrami et al., 2001; Kajstura et al., 1998). Consequently, myocardial infarctions (MIs) are the primary cause of cardiovascular morbidity and mortality. MIs is the irreversible loss of cardiac myocytes due to prolonged myocardial ischemia caused by an imbalance of the metabolic demand of the myocardium and myocardial blood flow (Whelan et al., 2010). Patients with MIs often die prematurely because of heart failure, resulting from irreversible scar formation on the ventricular wall and undermined heart function (Jessup and Brozena, 2003). Despite early intervention and advancements of medical devices for prevention, MIs are still untreatable, unless the heart transplantation approach considered, which is very limited by heart donation (Augoustides and Riha, 2009). Therefore, there is a high demand for standard therapy for heart failure that can restore the loss of CMs, prompt myocardial regeneration, and eventually, reduce morbidity and mortality rate of the disease.
Contrary to the adult mammalian heart, zebrafish display an extraordinary capacity for heart regeneration after the cardiac insult (Poss et al., 2002). This regenerative response relies on the ability of CMs to proliferate and replenish the lost tissue. Zebrafish is indeed one of the most commonly used experimental models for developmental and regenerative biology studies (Gemberling et al., 2013; Gonzalez-Rosa et al., 2017). For decades, the process of cardiac regeneration has been investigated using various cardiac injury models. The most commonly used and well-established injury methods are ventricular apical resection (Poss et al., 2002; Raya et al., 2003), cryoinjury (Chablais et al., 2011; Schnabel et al., 2011), as well as genetic and chemical ablation of heart cells (Curado et al., 2007; Wang et al., 2011). The origin of new cells is one of the most fundamental questions to be addressed during organ regeneration in any regenerative organism, and understanding of such phenomenon is crucial to design effective therapeutic strategies for non-regenerative organisms (Gonzalez-Rosa et al., 2017; Tanaka and Reddien, 2011).
Despite the robust cardiac regenerative potential, to date, only a handful of lineage tracing experiments have been reported in zebrafish heart regeneration. It was proposed that the cellular source of the renewed cardiac tissue might arise from progenitor or stem cells (Lepilina et al., 2006), through CMs dedifferentiation (Jopling et al., 2010; Kikuchi et al., 2010), transdifferentiation from other cell types in the heart tissue, and/or direct proliferation of the existing CMs (Kikuchi and Poss, 2012). Fate-mapping studies using transgenic lines driven by the myl7 promoter have shown that pre-existing CMs contribute to myocardial regeneration. However, myl7 expression is activated at early developmental stages in cardiac progenitor cells and hence precluding the identification of genuinely mature CMs in adult stages. Therefore, the cellular origin of the regenerating CMs remains elusive. Moreover, CM heterogeneity in the developing and adult zebrafish heart has never been explored to provide full insight into the process of regeneration. Therefore, I set out to identify genes exclusively expressed by either immature or mature CMs, generate promoter-driven reporter and CreERT2 lines to characterize the reporters during zebrafish heart development, and regeneration, and eventually to determine the contribution of the immature CMs to the regenerating CMs....
Ubiquitin and the ubiquitin-like protein ATG8 are covalently attached to their respective targets via a coordinated cascade involving E1 activating, E2 conjugating and E3 ligating enzymes. Whereas ubiquitin is conferred to proteins as mono- and/or polymer(s) to alter their stability, localization and/or activity, the ubiquitin-like modifier (UBL) ATG8 is conjugated to the phospholipid phosphatidylethanolamine (PE). The best understood function of ATG8 is during autophagy where ATG8-PE conjugates are incorporated into both layers of incipient autophagosomes and serve as multipurpose docking sites for autophagosomal cargo receptors as well as regulatory factors (termed adaptors) that drive formation and maturation of autophagosomes. Mammalian cells harbor six ATG8 family members that can be subclassified into the LC3- and GABARAP-family and that can all be lipidated. However, it is currently unclear to what extent these proteins are functionally redundant or fulfil unique roles.
Cullin-RING ligase complexes (CRLs) are modular E3 ubiquitin ligases that comprise a RING-finger protein that associates with the ubiquitin-charged E2 enzyme, a substrate recruiting module as well as a cullin scaffold as a linker between RING protein and substrate adaptor. Whereas SCF (SKP1-CUL1-F-box protein) complexes, the most studied CRLs, harbor cullin-1 (CUL1) as scaffold and F-box proteins as substrate binding modules, CUL3-containing CRL complexes employ cullin-3 (CUL3), RING-box protein 1 (RBX1) and BTB proteins as substrate adaptors. Here, the BTB domain serves as binding interface for CUL3 and is usually complemented by an additional protein-protein interaction domain such as MATH or Kelch that mediates binding to the substrate of the E3 ligase complex.
Besides ubiquitylation, guanine nucleotide binding is another common way to regulate protein activity and signaling in cells. Here, small Rho GTPases cycle between active and inactive states by binding of the guanine nucleotides GTP or GDP with the help of regulatory proteins. Whereas GTPase-activating proteins (GAP) render RAC1 inactive by facilitating GTP hydrolysis, guanine exchange factors (GEF) such as T-lymphoma invasion and metastasis-inducing protein 1 (TIAM1) activate RAC1 by stimulating the exchange of GDP to GTP. Local control of RAC1 activity is essential to allow a specific cellular response to stimuli such as growth factors or migratory impulses.
This study reports an unexpected link between the GABARAP subfamily of mammalian ATG8 proteins, the ubiquitin proteasome system and RAC1 through the ubiquitylation of the RAC1 GEF TIAM1. The Kelch repeat and BTB domain-containing proteins 6 (KBTBD6) and 7 (KBTBD7) were established as heterodimeric substrate adaptors for CUL3. Interestingly, a thorough proteomic analysis revealed a number of putative substrates but, out of 11 substrate candidates tested, only the RAC1 GEF TIAM1 appeared to be influenced by depletion of CUL3KBTBD6/KBTBD7. Binding studies showed that KBTBD7 binds TIAM1 via the Kelch repeats and that this binding was markedly enhanced when CUL3 activation was abolished upon treatment with the neddylation inhibitor MLN4924. Also, total TIAM1 abundance was increased upon CUL3KBTBD6/KBTBD7 depletion and accumulation of TIAM1 upon proteasome inhibition suggested that TIAM1 is degraded via the proteasome. In vivo ubiquitylation assays and denaturing immunoprecipitations as well as mass spectrometrical analysis confirmed that CUL3KBTBD6/KBTBD7 ubiquitylates TIAM1 at two distinct lysines (K1404 and K1420) close to its C-terminus.
Previously, KBTBD6 and KBTBD7 were found as interactors of several members of the human ATG8 family of proteins in a proteomic study analyzing the human autophagy network. This association was confirmed in the present work. Furthermore, peptide array technology and mutational analysis revealed that KBTBD6 and KBTBD7 employ a classical ATG8-family interacting motif (AIM; also referred to as LC3-interacting region or LIR) as binding interface. The AIMs of KBTBD6 (W-V-R-V) and KBTBD7 (W-V-Q-V) fulfil the consensus AIM sequence motif (F/W/Y1-X2-X3-I/L/V4) and are preceded by several acidic residues and serines. A series of structural and cell biological experiments revealed a binding preference for the GABARAP subfamily of human ATG8 proteins and most importantly, a requirement of the GABARAP-KBTBD6 and -KBTBD7 interaction for TIAM1 ubiquitylation. The finding that TIAM1 binding to KBTBD6 and KBTBD7 AIM mutants was diminished raised the possibility that GABARAP binding mediates the recruitment of CUL3KBTBD6/KBTBD7 to membranes where TIAM1 is localized. Interestingly, colocalization of KBTBD6, GABARAPL1 and TIAM1 in punctuate structures could be observed. Since only a very small fraction of GABARAPL1 colocalized with LC3B, and colocalization between KBTBD6 and LC3B was not observed, these vesicular structures are most likely distinct from autophagosomes. Furthermore, TIAM1 ubiquitylation was reduced when GABARAP, but not LC3B, was depleted or when lipidation of GABARAP was prevented.
Stabilization of TIAM1 upon KBTBD6 and/or KBTBD7 depletion led to elevated TIAM1-dependent RAC1 activity, altered actin morphology with increased cortical actin and loss of vinculin foci. Re-introduction of wild-type KBTBD6 or KBTBD7 but not AIM mutants reverted all these phenotypes. Moreover, depletion of KBTBD6 or KBTBD7 in human breast cancer cells massively increased their invasiveness, whereas TIAM1 knockdown had the opposite outcome. All physiological effects of KBTBD6 and KBTBD7 depletion were inhibited by additional depletion of TIAM1 or RAC1 confirming that the phenotypes observed are indeed mediated by the CUL3KBTBD6/KBTBD7-TIAM1-RAC1 signaling pathway. Intriguingly, KBTBD6 and KBTBD7 were not subject to autophagosomal degradation, thereby establishing a new function for GABARAP proteins beyond autophagosomal degradation in providing a signaling platform for recruitment of the E3 ligase CUL3KBTBD6/KBTBD7 in close proximity to its substrate TIAM1, enabling localized ubiquitylation.
Local restricted control of RAC1 activity by ubiquitylation has been described for TIAM1-RAC1 signaling previously. Examples are HECT, UBA and WWE domain-containing protein 1 (HUWE1)-mediated TIAM1 ubiquitylation that occurs predominantly at cell-cell-junctions in response to hepatocyte growth factor stimulation in MDCKII cells or inhibition of RAC1 activity by the RAC1 GAP protein BCR (breakpoint cluster region) at the leading edge of astrocytes through binding to the TIAM1-Par (polarity) complex. SCFBTRC mediates ubiquitylation of TIAM1 in response to mitogens or DNA damage, though it has not been explored whether this regulation is spatially restricted. Thus, this study adds a novel layer of complexity to the spatial regulation of RAC1 signaling by implicating membrane-bound human ATG8 proteins in this process.
Also, this study is the first report specifically implicating the GABARAP proteins in cellular signaling events. It will be interesting to explore whether the concept of localized signaling mediated by GABARAPs applies to other substrates of CUL3KBTBD6/KBTBD7 and membranerelated signaling processes in which GABARAP proteins are involved. Controlling RAC1 activity at GABARAP-decorated membranes might also be important for trafficking events or autophagy since it was described that RAC1 has an inhibitory function on autophagy. Therefore, spatial restricted ubiquitylation of TIAM1 resulting in specific deactivation of RAC1 could promote the autophagic process when locally needed. Although the catalytic mTOR inhibitor Torin1 and the lysosomal H+ ATPase inhibitor BafilomycinA1 promoted TIAM1 ubiquitylation by increasing the pool of membrane-conjugated GABARAP, but other signals that stimulate GABARAP-KBTBD6/KBTBD7 association and subsequent TIAM1 ubiquitylation are to be identified. Besides, determining the KBTBD6/KBTBD7 binding site in TIAM1 or uncovering a deubiquitylating enzyme (DUB) that locally counteracts the ubiquitylation of TIAM1 will enable a better comprehension of the complete localized signaling cascade.
Impact of F1Fo-ATP-synthase dimer assembly factors on mitochondrial function and organismic aging
(2018)
In aerobic organisms, mitochondrial F1Fo-ATP-synthase is the major site of ATP production. Beside this fundamental role, the protein complex is involved in shaping and maintenance of cristae. Previous electron microscopic studies identified the dissociation of F1Fo-ATP-synthase dimers and oligomers during organismic aging correlating with a massive remodeling of the mitochondrial inner membrane. Here we report results aimed to experimentally proof this impact and to obtain further insights into the control of these processes. We focused on the role of the two dimer assembly factors PaATPE and PaATPG of the aging model Podospora anserina. Ablation of either protein strongly affects mitochondrial function and leads to an accumulation of senescence markers demonstrating that the inhibition of dimer formation negatively influences vital functions and accelerates organismic aging. Our data validate a model that links mitochondrial membrane remodeling to aging and identify specific molecular components triggering this process.