Generation of a NG2-EYFP mouse for studying the properties of NG2-expressing cells

A range of vectors were made in which the EYFP gene or the Cre gene were inserted in the start codon of the NG2 gene. The NG2-EYFP vectors were used to generate NG2-EYFP “knockin” mice by homologous recombination. The F1 generation showed lack of EYFP expression, due to NeoR cassette interference. Excision of the NeoR, by breeding the F1 generation to ELLA-Cre mice allowed proper expression of EYFP. NG2-EYFP heterozygous mice were characterized in detail for astrocytic, neurogenic and oligodendrocytic properties through antibody labeling. NG2-EYFP+ cells did not label for the astrocyte marker GFAP, but some cells did express S100 Beta. The cells did not label with any neuronal markers like Beta III tubulin, Neun, and double cortin, but many of the NG2-EYFP+ cells made intimate contacts to the neurons. These contacts are widespread throughout the grey and white matter of the brain. The NG2-EYFP+ cells did label for oligodendrocyte markers like PDGFα-R, NG2, Olig2, O4, and Sox 10. There were a few cells termed phantom cells that did label for NG2, but had no EYFP expression. This could have been caused by improper excision of the NeoR cassette in the F2 generation. The heterozygous mouse is a tool to allow the characterization of the in vivo properties of the NG2+ cells. Breeding of these mice to homozygosity yielded an NG2-knockout mouse, which was also subjected to initial characterization. The NG2-EYFP homozygous showed equivalent cell labeling results to the NG2-EYFP heterozygous mouse, but the phantom cells disappeared in the knockout. The results show that the NG2 cells are a heterogenous population that does not express astrocytic or neuronal markers. The homozygous mouse is an ideal tool to further dissect the properties of the cells, lacking NG2 in vivo.

LRP1 modulates APP trafficking and APP metabolism within compartments of the secretory pathway. Increased AICD generation is ineffective in nuclear translocation and transcriptional activation

LRP1 modulates APP trafficking and metabolism within compartments of the secretory pathway The amyloid precursor protein (APP) is the parent protein to the amyloid beta peptide (Abeta) and is a central player in Alzheimer’s disease (AD) pathology. Abeta liberation depends on APP cleavage by beta- and gamma-secretases. To date, only a unilateral view of APP processing exists, excluding other proteins, which might be transported together and/or processed dependent on each other by the secretases described above. The low density lipoprotein receptor related protein 1 (LRP1) was shown to function as such a mediator of APP processing at multiple steps. Newly synthesized LRP1 can interact with APP, implying an interaction between these two proteins early in the secretory pathway. Therefore, we wanted to investigate whether LRP1 can mediate APP trafficking along the secretory pathway, and, if so, whether it affects APP processing. Indeed, we demonstrate that APP trafficking is strongly influenced by LRP1 transport through the endoplasmic reticulum (ER) and Golgi compartments. LRP1-constructs with ER- and Golgi-retention motifs (LRP-CT KKAA, LRP-CT KKFF) had the capacity to retard APP trafficking at the respective steps in the secretory pathway. Here, we provide evidence that APP metabolism occurs in close conjunction with LRP1 trafficking, highlighting a new role of lipoprotein receptors in neurodegenerative diseases. Increased AICD generation is ineffective in nuclear translocation and transcriptional activity A sequence of amyloid precursor protein (APP) cleavages gives rise to the APP intracellular domain (AICD) together with amyloid beta peptide (Abeta) and/or p3 fragment. One of the environmental factors identified favouring the accumulation of AICD appears to be a rise in intracellular pH. This accumulation is a result of an abrogated cleavage event and does not extend to other secretase substrates. AICD can activate the transcription of artificially expressed constructs and many downstream gene targets have been discussed. Here we further identified the metabolism and subcellular localization of the constructs used in this well documented gene reporter assay. We also co-examined the mechanistic lead up to the AICD accumulation and explored possible significances for its increased expression. We found that most of the AICD generated under pH neutralized conditions is likely that cleaved from C83. Furthermore, the AICD surplus is not transcriptionally active but rather remains membrane tethered and free in the cytosol where it interacts with Fe65. However, Fe65 is still essential in AICD mediated transcriptional transactivation although its exact role in this set of events is unclear.

Genetische und funktionelle Analyse von Vesikelmembranprotein-Mutanten in Maus und Caenorhabditis elegans

Tetraspan vesicle membrane proteins (TVPs) sind konservierte, ubiquitär vorkommende Membranproteine synaptischer Vesikel und zytoplasmatischer Transportvesikel. Bei Säugetieren lassen sie sich in die Physine, Gyrine und SCAMPs (secretory carrier-associated membrane proteins) unterteilen, die im Nematoden C. elegans jeweils nur durch ein einzelnes Polypeptid vertreten sind (Synaptophysin-1 [SPH-1], Synaptogyrin-1 [SNG-1] und SCAMP-1 [SCM-1]). Obwohl den TVPs eine Beteiligung bei der Regulation des Vesikelzyklus zugesprochen wurde, sind Synaptophysin-1-Knockout-Mäuse und vollständig TVP-defiziente Würmer gesund und weisen nur geringgradige Veränderungen auf. In dieser Arbeit sollten daher zum einen genomweite komparative Transkriptomanalysen durchgeführt werden, um mögliche Kompensationsmechanismen in der Maus und C. elegans zu finden, zum anderen sollten mit Hilfe pharmakologischer Stressassays und genetischer Verfahren Schwachstellen und Redundanzen identifiziert werden. Erstaunlicherweise konnten durch Affymetrix GeneChip-Analysen der RNA in der Retina von Synaptophysin-1-/--Mäusen keine differenziell exprimierten Gene gefunden werden. Bei der Untersuchung der C. elegans-TVP-Dreifachmutante wurden hingegen 17 Gene mit erhöhter und 3 mit erniedrigter Transkription identifiziert. Die Befunde für 12 hochregulierte Gene wurden durch quantitative Real-Time RT-PCR bestätigt. Das am stärksten hochregulierte Gen arf-1.1 kodiert für eine GTPase, die vermutlich an der Regulation der Vesikelbildung beteiligt ist. Von den ebenso identifizierten Genen cdr-2, cdr-4 und pgp-9 ist bekannt, dass sie in Stresssituationen, z. B. in Gegenwart von Cadmium, verstärkt transkribiert werden. ugt-62 und ugt-19 kodieren für Glucuronosyltransferasen. Für arf-1.1, cdr-2, ugt-62 sowie für das Gen T16G1.6, das für eine coiled-coil-Domäne kodiert, wurden im Folgenden fluoreszierende Promoterkonstrukte hergestellt, um Koexpressionsmuster mit TVPs zu bestimmen. Es stellte sich heraus, dass alle vier Promoterkonstrukte im Darm zusammen mit SPH-1 und SCM-1 im Darm transkribiert werden. Mit fluoreszierenden Translationschimären konnte weiterhin gezeigt werden, dass ARF-1.1 und CDR-2 mit den Darm-spezifischen TVPs im apikalen Bereich der Darmzellen kolokalisieren. Um mehr über die Funktion von TVPs im Vesikelzyklus zu erfahren, wurden pharmakologische und genetische Analysen von Würmern durchgeführt, in denen die Expression des Neuronen-spezifischen SNG-1 verändert ist. Deletion oder Überexpression führte zu einer Resistenz gegenüber dem Acetylcholinesterase-Inhibitor Aldicarb und zu erhöhter Empfindlichkeit gegenüber dem GABA-Rezeptor-Antagonisten Pentylentetrazol. Auf genetischer Ebene zeigte sich, dass sng-1 synthetisch mit den Genen für Synaptotagmin-1, Endophilin A sowie Synaptojanin wirkt. Die beobachteten Effekte weisen auf alternative Funktionen in der synaptischen Übertragung hin und unterstützen zugleich die Hypothese, dass SNG-1 im synaptischen Vesikelzyklus eine wichtige Funktion erfüllt, die möglicherweise einem noch unbekannten redundanten Kompartiment-spezifischen Signalweg der synaptischen Transmission zuzuordnen ist.

Endocytic trafficking and oligodendroglial exosome secretion in axon-glia communication and myelination

Oligodendrocytes form specialized plasma membrane extensions which spirally enwrap axons, thereby building up the myelin sheath. During myelination, oligodendrocytes produce large amounts of membrane components. Oligodendrocytes can be seen as a complex polarized cell type with two distinct membrane domains, the plasma membrane surrounding the cell body and the myelin membrane. SNARE proteins mediate the fusion of vesicular cargoes with their target membrane. We propose a model in which the major myelin protein PLP is transported by two different pathways. VAMP3 mediates the non-polarized transport of newly synthesized PLP via recycling endosomes to the plasma membrane, while transport of PLP from late endosomes/lysosomes to myelin is controlled by VAMP7. In the second part of the thesis, the role of exosome secretion in glia to axon signaling was studied. Further studies are required to clarify whether VAMP7 also controls exosome secretion. The thesis further focused on putative metabolic effects in the target neurons. Oligodendroglial exosomes showed no obvious influences on neuronal metabolic activity. Analysis of the phosphorylation levels of the neurofilament heavy subunit revealed a decrease in presence of oligodendrocytes, indicating effects of oligodendroglial exosomes on the neuronal cytoskeleton. Finally, candidates for kinases which are possibly activated upon influence of oligodendroglial exosomes and could influence neuronal survival were identified.

Uptake mechanism, intracellular trafficking and endo-lysosomal pH monitoring of polystyrene nanoparticles

What is the intracellular fate of nanoparticles (NPs) taken up by the cells? This question has been investigated for polystyrene NPs of different sizes with a set of molecular biological and biophysical techniques.rnTwo sets of fluorescent NPs, cationic and non-ionic, were synthesized with three different polymerization techniques. Non-ionic particles (132 – 846 nm) were synthesized with dispersion polymerization in an ethanol/water solution. Cationic NPs with 120 nm were synthesized by miniemulsion polymerization Particles with 208, 267 and 603 nm were produced by seeding the 120 nm particle obtained by miniemulsion polymerization with drop-wise added monomer and polymerization of such. The colloidal characterization of all particles showed a comparable amount of the surface groups. In addition, particles were characterized with regard to their size, morphology, solid content, amount of incorporated fluorescent dye and zeta potential. The fluorescent intensities of all particles were measured by fluorescence spectroscopy for calibration in further cellular experiments. rnThe uptake of the NPs to HeLa cells after 1 – 24 h revealed a much higher uptake of cationic NPs in comparison to non-ionic NPs. If the same amount of NPs with different sizes is introduced to the cell, a different amount of particles is present in the cell medium, which complicates a comparison of the uptake. The same conclusion is valid for the particles’ overall surface area. Therefore, HeLa cells were incubated with the same concentration, amount and surface area of NPs. It was found that with the same concentration always the same polymer amount is taking up by cells. However, the amount of particles taken up decreases for the biggest. A correlation to the surface area could not be found. We conclude that particles are endocytosed by an excavator-shovel like mechanism, which does not distinguish between different sizes, but is only dependent on the volume that is taken up. For the decreased amount of large particles, an overload of this mechanism was assumed, which leads to a decrease in the uptake. rnThe participation of specific endocytotic processes has been determined by the use of pharmacological inhibitors, immunocytological staining and immunofluorescence. The uptake of NPs into the endo-lysosomal machinery is dominated by a caveolin-mediated endocytosis. Other pathways, which include macropinocytosis and a dynamin-dependent mechanism but exclude clathrin mediated endocytosis, also occur as competing processes. All particles can be found to some extent in early endosomes, but only bigger particles were proven to localize in late endosomes. No particles were found in lysosomes; at least not in lysosomes that are labeled with Lamp1 and cathepsin D. However, based on the character of the performed experiment, a localization of particles in lysosomes cannot be excluded.rnDuring their ripening process, vesicles undergo a gradual acidification from early over late endosomes to lysosomes. It is hypothesized that NPs in endo-lysosomal compartments experience the same change in pH value. To probe the environmental pH of NPs after endocytosis, the pH-sensitive dye SNARF-4F was grafted onto amino functionalized polystyrene NPs. The pH value is a ratio function of the two emission wavelengths of the protonated and deprotonated form of the dye and is hence independent of concentration changes. The particles were synthesized by the aforementioned miniemulsion polymerization with the addition of the amino functionalized copolymer AEMH. The immobilization of SNARF-4F was performed by an EDC-coupling reaction. The amount of physically adsorbed dye in comparison to covalently bonded dye was 15% as determined by precipitation of the NPs in methanol, which is a very good solvent for SNARF-4F. To determine influences of cellular proteins on the fluorescence properties, a intracellular calibration fit was established with platereader measurements and cLSM imaging by the cell-penetrable SNARF-4F AM ester. Ionophores equilibrated the extracellular and intracellular pH.rnSNARF-4F NPs were taken up well by HeLa cells and showed no toxic effects. The pH environment of SNARF-4F NPs has been qualitatively imaged as a movie over a time period up to 1 h in pseudo-colors by a self-written automated batch program. Quantification revealed an acidification process until pH value of 4.5 over 24 h, which is much slower than the transport of nutrients to lysosomes. NPs are present in early endosomes after min. 1 h, in late endosomes at approx. 8 h and end up in vesicles with a pH value typical for lysosomes after > 24 h. We therefore assume that NPs bear a unique endocytotic mechanism, at least with regards to the kinetic involvedrn

Identification and characterisation of Stx5 a novel interactor of VLDL-R affecting its intracellular trafficking and processing

We identified syntaxin 5 (Stx5), a protein involved in intracellular vesicle trafficking, as a novel interaction partner of the very low density lipoprotein (VLDL)-receptor (VLDL-R), a member of the LDL-receptor family. In addition, we investigated the effect of Stx5 on VLDL-R maturation, trafficking and processing. Here, we demonstrated mutual association of both proteins using several in vitro approaches. Furthermore, we detected a special maturation phenotype of VLDL-R resulting from Stx5 overexpression. We found that Stx5 prevented Golgi-maturation of VLDL-R, but did not cause accumulation of the immature protein in ER to Golgi compartments, the main expression sites of Stx5. Rather more, abundantly present Stx5 was capable of translocating ER-/N-glycosylated VLDL-R to the plasma membrane, and thus was insensitive to BFA treatment and incubation at low temperature. Based on our findings, we postulate that Stx5 can directly bind to the C-terminal domain of VLDL-R, thereby influencing the receptor’s glycosylation, trafficking and processing characteristics. Resulting from that, we further suggest that Stx5, which is highly expressed in neurons along with VLDL-R, might play a role in modulating the receptor’s physiology by participating in a novel/undetermined alternative pathway bypassing the Golgi apparatus.

Oligodendroglial exosomes in glia to neuron signaling

In the CNS, myelinating oligodendrocytes and axons form a functional unit based on intimate cell-cell interactions. In addition to axonal insulation serving to increase the conduction velocity of electrical impulses, oligodendrocytes provide trophic support to neurons essential for the long-term functional integrity of axons. The glial signals maintaining axonal functions are just at the beginning to become uncovered. Yet, their determination is highly relevant for all types of demyelinating diseases, where lack of glial support significantly contributes to pathology. rnThe present PhD thesis uncovers exosomes as a novel signaling entity in the CNS by which cargo can be transferred from oligodendrocytes to neurons. Exosomes are small membranous vesicles of endocytic origin, which are released by almost every cell type and have been implicated in intercellular communication. Oligodendrocytes secrete exosomes containing a distinct set of proteins as well as mRNA and microRNA. Intriguingly, oligodendroglial exosome release is stimulated by the neurotransmitter glutamate indicating that neuronal electrical activity controls glial exosome release. In this study, the role of exosomes in neuron-glia communication and their implications on glial support was examined. Cortical neurons internalized and accumulated oligodendroglial exosomes in the neuronal cell soma in a time-dependent manner. Moreover, uptake occurred likewise at the somatodendritic and axonal compartment of the neurons via dynamin and clathrin dependent endocytosis. Intriguingly, neuronal internalization of exosomes resulted in functional retrieval of exosomal cargo in vitro and in vivo upon stereotactic injection of Cre recombinase bearing exosomes. Functional recovery of Cre recombinase from transferred exosomes was indicated by acquired reporter recombination in the target cell. Electrophysiological analysis showed an increased firing rate in neurons exposed to oligodendroglial exosomes. Moreover, microarray analysis revealed differentially expressed genes after exosome treatment, indicating functional implications on neuronal gene expression and activity. rnTaken together, the results of this PhD thesis represent a proof of principle for exosome transmission from oligodendrocytes to neurons suggesting a new route of horizontal transfer in the CNS.rn

Drug delivery, entry and intracellular trafficking of polymeric nanoparticles

Polymere Nanopartikel sind kleine Teilchen, die vielseitige Einsatzmöglichkeiten für den Transport von Wirkstoffen bieten. Da Nanomaterialien in diesen biomedizinischen Anwendungen oft mit biologischen Systemen in Berührung kommen, erfordert das eine genaue Untersuchung ihrer gegenseitigen Wechselwirkungen. In diesem speziellen Forschungsgebiet, welches sich auf die Interaktionen von Nanomaterialien mit biologischen Komponenten konzentriert, wurde bereits eine Vielzahl verschiedener Nanopartikel-Zell-Interaktionen (z. B. Nanotoxizität, Wirkstofftransport-mechanismen) analysiert. Bezüglich der Untersuchungen zu nanopartikulären Wirkstofftransport-mechanismen ist es im Allgemeinen akzeptiert, dass ein erfolgreicher zellulärer Transport hauptsächlich von der Aufnahme des Nanotransporters abhängt. Deshalb analysieren wir in dieser Arbeit (1) den Wirkstofftransportmechanismus für biologisch-abbaubare eisenhaltige Poly-L-Milchsäure Nanopartikel (PLLA-Fe-PMI) sowie (2) die Aufnahmemechanismen und die intrazellulären Transportwege von nicht-abbaubaren superparamagnetischen Polystyrolnanopartikeln (SPIOPSN). rnIn dieser Arbeit identifizieren wir einen bisher unbekannten und nicht-invasiven Wirkstoff-transportmechanismus. Dabei zeigt diese Studie, dass der subzelluläre Transport der nanopartikulärer Fracht nicht unbedingt von einer Aufnahme der Nanotransporter abhängt. Der identifizierte Arzneimitteltransportmechanismus basiert auf einem einfachen physikochemischen Kontakt des hydrophoben Poly-L-Milchsäure-Nanopartikels mit einer hydrophoben Oberfläche, wodurch die Freisetzung der nanopartikulären Fracht ausgelöst wird. In Zellexperimenten führt die membranvermittelte Freisetzung der nanopartikulären Fracht zu ihrem sofortigen Transport in TIP47+- und ADRP+- Lipidtröpfchen. Der Freisetzungsmechanismus („kiss-and-run") kann durch die kovalente Einbindung des Frachtmoleküls in das Polymer des Nanopartikels blockiert werden.rnWeiterhin wird in Langzeitversuchen gezeigt, dass die Aufnahme der untersuchten polymeren Nanopartikel von einem Makropinozytose-ähnlichen Mechanismus gesteuert wird. Im Laufe dieser Arbeit werden mehrere Faktoren identifiziert, die in diesem Aufnahmemechanismus eine Rolle spielen. Darunter fallen unter anderem die kleinen GTPasen Rac1 und ARF1, die die Aufnahme von SPIOPSN beeinflussen. Darauffolgend werden die intrazellulären Transportwege der Nanopartikel untersucht. Mit Hilfe eines neuartigen Massenspektrometrieansatzes wird der intrazelluläre Transport von nanopartikelhaltigen endozytotischen Vesikeln rekonstruiert. Intensive Untersuchungen identifizieren Marker von frühen Endosomen, späten Endosomen/ multivesikulären Körpern, Rab11+- Endosomen, Flotillin-Vesikeln, Lysosomen und COP-Vesikeln. Schließlich wird der Einfluss des lysosomalen Milieus auf die Proteinhülle der Nanopartikel untersucht. Hier wird gezeigt, dass die adsorbierte Proteinhülle auf den Nanopartikeln in die Zelle transportiert wird und anschließend im Lysosom abgebaut wird. rnInsgesamt verdeutlicht diese Arbeit, dass die klassische Strategie des nanopartikulären und invasiven Wirkstofftransportmechanismuses überdacht werden muss. Weiterhin lässt sich aus den Daten schlussfolgern, dass polymere Nanopartikel einem atypischen Makropinozytose-ähnlichen Aufnahmemechanismus unterliegen. Dies resultiert in einem intrazellulären Transport der Nanopartikel von Makropinosomen über multivesikuläre Körperchen zu Lysosomen.rn