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Application of a developed tool to visualize newly synthesized AMPA receptor components in situ
(2018)
The information flow between neurons happens at contact points, the synapses. One underlying mechanism of learning and memory is the change in the strength of information flow in selected synapses. In order to match the huge demand in membranes and proteins to build and maintain the neurites' complex architecture, neurons use decentralized protein synthesis. Many candidate proteins for local synthesis are known, and the need of de novo synthesis for memory formation is well established. The underlying mechanisms of how somatic versus dendritic synthesis is regulated are yet to be elucidated. Which proteins are newly synthesized in order to allow learning?
In this thesis protein synthesis is studied in hippocampal neurons. The fractional distribution of somatic and dendritic synthesis for candidate proteins and their subsequent transport to their destination are investigated using a newly developed technique. In the first part of this study we describe the development of this technique and use it in the second part to answer biological questions.
We focus here on AMPA receptor subunits, the key players in fast excitatory transmission. AMPA receptors contain multiple subunits with diverse functions. It remains to be understood, when and where in a neuron these subunits come together to form a protein complex and how the choice of subunits is regulated.
The investigation of the subunits' site of synthesis and redistribution kinetics in this study will help us to understand how neurons are able to change their synaptic strength in an input specific manner which eventually allows learning and memory.
Key questions which are addressed in this study:
How can specific newly synthesized endogenous proteins be visualized in situ? What are the neuron's abilities to locally synthesize and fully assemble AMPA receptor complexes?
How fast do different AMPA receptor subunits redistribute within neurons after synthesis?
ß1-integrins are essential for angiogenesis but the mechanisms regulating integrin function in endothelial cells (EC) and their contribution to angiogenesis remain elusive. BRAG2 is a guanine nucleotide exchange factor for the small Arf-GTPases Arf5 and Arf6. The role of BRAG2 in EC and angiogenesis and the underlying molecular mechanisms remains unclear. siRNA-mediated BRAG2-silencing reduced EC angiogenic sprouting and migration. BRAG2-siRNA-transfection differentially affected a5ß1- and aVß3-integrin function: specifically, BRAG2-silencing increased focal/fibrillar adhesions and EC adhesion on ß1-integrin-ligands (fibronectin and collagen), while reducing the adhesion on the aVß3-integrin-ligand, vitronectin. Consistent with these results, BRAG2-silencing enhanced surface expression of a5ß1-integrin, while reducing surface expression of aVß3-integrin. Mechanistically, BRAG2 mediated recycling of aVß3-integrins and endocytosis of ß1-integrins and specifically of the active/matrix bound a5ß1-integrin present in fibrillar/focal adhesions (FA), suggesting that BRAG2 contributes to the disassembly of FA via ß1-integrin-endocytosis. Arf5 and Arf6 are promoting downstream of BRAG2 angiogenic sprouting, ß1-integrin-endocytosis and the regulation of FA. In vivo silencing of the BRAG2-orthologues in zebrafish embryos using morpholinos perturbed vascular development. Furthermore, in vivo intravitral injection of plasmids containing BRAG2-shRNA reduced pathological ischemia-induced retinal and choroidal neovascularization. These data reveals that BRAG2 is essential for developmental and pathological angiogenesis by promoting EC sprouting through regulation of adhesion by mediating ß1-integrin internalization and associates for the first time the process of ß1-integrin endocytosis with angiogenesis.
Cardiac trabeculation is one of the essential processes required for the formation of a competent ventricular wall, whereby clusters of ventricular cardiomyocytes (CMs) from a single layer delaminate and expand into the cardiac jelly to form sheet-like projections in the developing heart (Samsa et al., 2013). Several congenital heart diseases are associated with defects in the formation of these trabeculae and lead to embryonic lethality (Jenni et al., 1999; Zhang et al., 2013, Jenni et al., 2001; Towbin 2010). It has been experimentally shown that lack of Nrg1/ErbB2/ErbB4, Angipoetin1/Tie2, EphrinB2/B4, BMP10, or any component of the Notch signaling pathway can cause defective trabeculation. Moreover, changes in blood flow and/or contractility can also affect trabeculation (Samsa et al., 2013). Together, these observations demonstrate that cardiac trabeculation is a highly dynamic and regulated process.
Trabeculation is a morphogenetic process that requires control over cell shape changes and rearrangements, similar to those observed during EMT. Epithelial cells within an epithelium are polarized and establish cell-cell junctions with the neighboring cells (Ikenouchi et al., 2003; Ferrer-vaquer et al., 2010), thus epithelial cell polarity is an important feature to maintain cell shape and tissue structure. During developmental processes such as cell migration and cell division or in disease states epithelial polarity might be disrupted. As a consequence of this alteration, cells lose their tight cell-cell adhesions, undergo cytoskeletal rearrangements, change their shape and gain migratory properties becoming mesenchymal cells (Micalizzi et al., 2010). In epithelial cells, apicobasal polarity is regulated by a conserved set of core complexes, including the PAR, Scribble and Crumbs complexes (Kemphues et al., 1988; Bilder and Perrimon, 2000; Teppas et al., 1984). The polarity proteins composing these complexes interact in a well organized and coordinated-manner creating molecular asymmetry along the apicobasal axis of the cell. In turn, this crosstalk regulates the maturation and stabilization of the junctions between cells and cytoskeleton in order to strengthen cell polarization (Roignot et al., 2013). Amongst the different polarity complex, Crumbs has been shown to be a key regulator of apicobasal polarity during development in both vertebrates and invertebrates (Tepass et al., 1990; Fan et al., 2004).
Here, taking advantage of zebrafish as a model organism, I study in vivo at single cell resolution changes in CM apicobasal polarity during cardiac trabeculation. Moreover, I show which factors regulate CM apicobasal polarity during this process. In addition, I dissect the role of the polarity complex Crumbs in regulating CM junctional rearrangements and the formation of the trabecular network.
Connectomic analysis of apical dendrite innervation in pyramidal neurons of mouse cerebral cortex
(2020)
The central goal of this study was to generate synapse-resolution maps of local and long-range innervation on apical dendrites (AD) in mouse cerebral cortex. We used three-dimensional electron microscopy (3D-EM) to first measure the cell-type specific balance in the excitatory and inhibitory input on ADs. Further, we found two inhibitory axon populations with preference for apical dendrites originating from layer 2 and 3/5. Additionally, we used a combination of large-scale volumetric light and electron microscopy to investigate the innervation preference of long-range cortical projections onto ADs. To generate such large-scale 3D-EM datasets, we also developed a software package to automate aberration adjustment.
The balance of excitation and inhibition defines the computational properties of neurons. We, therefore, generated 6 datasets and annotated 26,548 excitatory and inhibitory synapses to map the relative inhibitory strength on the AD of pyramidal neurons in layers 1 and 2 (L1 and 2) of the cortex. We found consistent and cell-type specific patterns of inhibitory strength along the apical dendrite of L2-5 pyramidal neurons in primary somatosensory (S1), secondary visual (V2), posterior parietal (PPC) and anterior cingulate (ACC) cortices. L2 and L5 pyramidal neurons had inhibitory hot-zones at their main bifurcation and distal apical dendrite tuft, respectively. In contrast, L3 neurons had a baseline (~10%) level of inhibition along their apical dendrite. As controls, we quantified the effect of synapse strength (size), dendrite diameter, AD classification and synapse identification methods on the cell-type specific synapse densities. To classify L5 pyramidal subtypes, we performed hierarchical clustering using morphological properties that were described to differentiate slender- and thick-tufted L5 neurons.
We also investigated the distance to soma as a predictor of fractional inhibition around the main bifurcation of apical dendrites. Interestingly, we found a strong exponential relationship that was absent in density of either synapse type. This suggests a distance dependent control mechanism designed specifically for the balance (in synapse numbers) of excitation and inhibition.
Next, we focused on the inhibitory innervation preference for apical dendrite of pyramidal neuron. We, therefore, annotated 5,448 output synapses of AD-targeting inhibitory axons and found two populations specific for either L2 or L3/5 apical dendrites. Together with previous findings on preferential innervation of sub-cellular structures by inhibitory axons, this suggests two distinct inhibitory circuits for control of AD activity in L2 vs. deep-layer pyramidal neurons. This innervation preference was surprisingly consistent across S1, V2, PPC and ACC cortices.
3D-EM data acquisition is a laborious process that is made easier and more popular everyday by technical progress in the laboratory and industrial settings. To make data acquisition robust using our custom-built 3D-EM microscopes, an automatic aberration software was implemented to adjust the objective lens and the stigmators of the electron microscope. This method was used in multiple month-long experiments across 2 microscopes and 10 datasets. The aberration adjustment used the reduction in image details (high-frequency elements) to estimate the level of deviation from optimal focus and stigmator parameters. However, large objects in EM micrographs such as blood vessel and nuclei cross-sections generated anomalous results. We, therefore, added image processing routines based on edge detection combined with morphological operations to exclude such large objects.
Finally, we performed a correlative three-dimensional (3D) light (LM) and electron (EM) microscopy experiment to map the long-range primary visual (V1) and secondary motor (M2) cortical input to ADs in layer 1 of PPC using the “FluoEM” approach. This method allows for identification of the long-range source of projection axons in EM volumes without the need for EM-dense label conversion or heat-induced markings. The long-range source of an axon in EM is identified based on the fluorescent protein that is expressed in its LM counterpart. In comparison to M2 input, Long-range axons from V1 had a higher tendency to target L3 pyramidal neurons in PPC according to our preliminary analysis. In combination with the difference observed in the synapse composition of L2 and L3 apical dendrites, this suggests the need for separate functional and structural analysis of L2 and 3 pyramidal neurons.
Die Analyse früher Entwicklungsstadien von Säugetierembryonen und daraus gewonnener Stammzelllinien kann entscheidende Erkenntnisse im Bereich der Reproduktionsbiologie und der regenerativen Medizin hervorbringen. Dabei spielt die Maus, als geeignetes Modellsystem für die Übertragbarkeit auf den Menschen eine wichtige Rolle, in erster Linie weil die Blastozysten der Maus verglichen mit menschliche Blastozysten eine morphologische Ähnlichkeit aufweisen. Humane embryonale Stammzelllinien haben großes Potential für die Anwendung in der regenerativen Medizin und vergleichend dazu wurde Gen-Targeting in embryonalen Stammzellen verwendet, um tausende neuer Mausstämme zu generieren. Die Gewinnung embryonaler Stammzellen erfolgt im Blastozystenstadium, diese können dann nach Injektion in eine andere Blastozyste zur Entwicklung aller Gewebearten, einschließlich der Keimbahngewebe, beitragen (Martin, 1981; Evans and Kaufman 1981).
Ursache einer Fehlgeburt können vor allem Defekte in der Entwicklung des Trophoblasten und des primitive Entoderms (PrE) sein, dabei sind ca. 5 % der Paare betroffen die versuchen ein Kind zu bekommen (Stephenson and Kutteh, 2007). Eine Untersuchung dieser Zelllinien im Mausmodell könnte weitere Erkenntnisse für die Gründe einer Fehlentwicklung liefern. Trophoblasten Stammzelllinien können aus den Blastozysten der Maus und dem extraembryonalen Ektoderm von bereits implantieren Embryonen gewonnen werden (Tanaka et al., 1998). Diese Zelllinien geben Aufschluss über die Entwicklung des Trophoblasten, fördern die Entwicklung der Plazenta und sind gleichzeitig ein gutes Modellsystem um die Implantation des Embryos im Uterus näher zu untersuchen. Zellen des primitive Entoderms (PrE) beeinflussen das im Dottersack vorhandene extraembryonale Entoderm, welches dort als “frühe Plazenta” fungiert und für die Versorgung des Embryos mit Nährstoffen zuständig ist (Cross et al., 1994). Des Weiteren besitzt das Entoderm einen induktiven Einfluss auf die Bildung von anterioren Strukturen und die Bildung von Endothelzellen sowie Blutinseln (Byrd et al., 2002).
Extraembryonale Endodermstammzellen (XEN Zellen) können aus Blastozysten gewonnen und in embryonale Stammzellen (ES-Zellen) umgewandelt werden (Fujikura et al., 2002; Kunath et al., 2005). Es war jedoch nicht bekannt, ob XEN-Zellen auch aus Postimplantations-Embryonen gewonnen werden können. XEN-Zellen tragen in vivo zur Entwicklung des Darmendoderms bei (Kwon et al., 2008; Viotti et al., 2014) und könnten als alternative, selbsterneuernde Quelle für extraembryonale Endoderm-abgeleitete Zellen dienen, die zur Herstellung von Geweben für die regenerative Medizin verwendet werden könnten (Niakan et al., 2013).
In der Embryogenese der Maus zeigt sich an Tag E3.0 eine kompakte Morula die sich allmählich in das Trophektoderm (TE) differenziert, welches wiederum den Embryonalknoten (“innere Zellmasse”) umschließt (Johnson and Ziomek, 1981). Ein wichtiger Schritt im Rahmen der Entwicklung findet an Tag E3.5 statt, in diesem Zeitraum gehen aus dem Embryonalknoten der pluripotente Epiblast und das primitive Entoderm hervor. Im späten Blastozystenstadium an Tag E4.5 liegt das PrE als Zellschicht entlang der Oberfläche der Blastocoel-Höhle. Aus dem Epiblast entwickeln sich im weiteren Verlauf der Embryo, das Amnion und das extraembryonale Mesoderm des Dottersacks. Die Zellen des Trophektoderm führen zur Entwicklung der Plazenta. Das PrE differenziert sich im Zuge der Weiterentwicklung in das viszerale Entoderm (VE) und das parietale Entoderm (PE) des Dottersacks (Chazaud et al., 2006; Gardner and Rossant, 1979; Plusa et al., 2008). VE umgibt den Epiblast und extraembryonisches Ektoderm (ExE). PE-Zellen wandern entlang der inneren Oberfläche von TE und sezernieren zusammen mit Trophoblasten-Riesenzellen Basalmembranproteine, um die Reichert-Membran zu bilden (Hogan et al., 1980). Die Reichert-Membran besteht aus Basalmembranproteinen, einschließlich Kollagenen und Lamininen, die zwischen den parietalen Endoderm- und Trophoblastzellen liegen. Diese Membran wirkt als ein Filter, der dem Embryo den Zugang zu Nährstoffen ermöglicht, während er eine Barriere zu den Zellen der Mutter bildet (Gardner, 1983).
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Even one century after Santiago Ramón y Cajal’s groundbreaking contribu- tions to neuroscience, one of the most fundamental questions in the field is still largely open, namely understanding how the shape of a dendrite is adapted to its specific biological function. A systematic investigation of this problem is challenging both technically and conceptually because neurons have diverse genetic, molecular, morphological, connectional and functional properties.
In the light of the preceding, dendritic arborisation (da) neurons of the Drosophila melanogaster larva PNS have proven to be an excellent model system for the study of such growth and patterning processes. Structure and function in these cell classes are intimately intertwined, as class type-specific dendritic arbour differentiation processes are required to satisfy a given phys- iological need. Also, there is a remarkable genetic toolkit that enables one to selectively and reproducibly label, image and manipulate each one of these sensory neuron classes. In this thesis, I address the aforementioned open problem by linking single-cell patterning, information processing and wiring optimisation in sensory da neurons to behaviour in Drosophila larva.
In particular, I study Class I ventral peripherical dendritic arborisation (c1vpda) neurons. These are a class of proprioceptive neurons that relay information on the position of the larva’s body back to the CNS during crawling behaviour to assure proper locomotion. Their stereotypical comb- like shaped dendritic branches spread along the body-wall, and they get noticeably deformed during crawling behaviour. The bending of the den- dritic branches is hypothesised to be a possible mechanism to transduce the mechanosensory inputs arising from cuticle folding. Interestingly, c1vpda neurons do not necessarily satisfy optimal wiring constraints since they are required to pattern into a specific shape to fulfil their function. Therefore, I considered the da system to study how the specific functional requirements may be combined with optimal wiring constraints during development.
Although the molecular machinery of dendrite patterning in c1vpda neurons is well studied, the precise elaboration of the comb-like shaped dendrites of these cells remains elusive. Moreover, even though a lot of work has been put into the description and quantification of growth processes of the nervous system, there are still few solid and standardised models of arbour staging and patterning. Importantly, the defining parameters that determine the dendrite elaboration program that in turn is responsible for creating the final arbour morphology are still unknown. As a result, unraveling possible universal stages of dendrite elaboration shared between different model systems and cell types is challenging.
Thus, in order to understand the development of the fine regulation of branch outgrowth that leads to the observed terminal arbour morphology in the mature cell, I collected in vivo, long-term, non-invasive high temporal res- olution time-lapse recordings of dendritic trees during the differentiation process in the embryo and its maturation phase in the larva. For further analysis, I developed new algorithms that quantified the structural changes in dendrite morphology in the time-lapse videos. My approach provides a framework to analyse such developmental data, or any dataset comprising continuous morphological dynamical processes in an unbiased way. Using these newly developed methods, I examined the development of a sample of c1vpda cells and identified five stages of differentiation in these data: initial stem polarization, extension, pruning, stabilization, and isometric stretching during larval stages.
The beginning of the growth process is marked by the polarisation of the main stem. Subsequently, during the extension phase, branches emerge interstitially from the existing main stem. Later, higher-order branches sprout from pre-existing lateral branches, increasing arbour complexity. This is followed by a pruning stage where developmental intermediate dendritic branches are removed. This step leads to a spatial rearrangement of the dendritic tree. The end of the pruning step is followed by a stabilisation period where arbour morphology remains virtually unaltered in the embryo. After hatching, c1vpda dendrites experience an isometric scaling, with their branching complexity and pattern being invariant across all larval stages.
After dissecting the c1vpda dendrites spatiotemporal differentiation process, I established a link between dendritic shape and behaviour. I measured intra- cellular Ca++ activity in the dendrite branches of l1 larvae during forward locomotion, while simultaneously recording branch deformation using a dual genetic line. I reported that post-embryonic c1vpda dendrites Ca++ responses increased in freely crawling larvae. Furthermore, I showed strong correlations between Ca++ signal and deformation of the comb-like dendritic ranches during body-wall contractions.
Then, using a geometrical model, I provided evidence that the pruning stage could reorganise the dendrite morphology to maximise mechanosensory re- sponses during body wall contraction. I showed that the angle orientation of each side branch correlates with the bending curvature and thus with the me- chanical displacement of the cell membrane during locomotion. During the pruning phase, I observed a preferential reduction of less efficient branches with low bending curvature, influencing the mechanisms of dendritic sig- nal integration of c1vpda sensory neurons. I proceeded to quantify branch dynamics at single tip resolution during pruning, providing evidence that a simple random pruning mechanism is sufficient to remodel the tree structure compatible with the observed way.
I used these time-lapse data to constrain a new computational noisy growth model with random pruning based on optimal wiring principles. This model is able to generate highly realistic synthetic c1vpda morphologies. The model furthermore requires few parameters to generate highly accurate temporal development trajectories and morphologies at single-cell level. Utilising this data and model enabled me to investigate upon the hypothesis that a noisy dendrite growth and random pruning mechanism synergise to achieve den- dritic trees efficient in terms of both wiring and function. My findings show how single neurons can create functionally specialised dendrites while min- imising wiring costs, elucidating how general principles of self-organisation may be involved in the generation of these structures.
Cerebellar ataxias are a group of neurodegenerative disorders primarily affecting the cerebellum. Although causative mutations in several genes have been identified there is currently no cure for ataxias.
The first part of this dissertation is focused on Spinocerebellar ataxia type 2 (SCA2). SCA2 is a dominant ataxia caused by repeat expansion mutations in the ATXN2 gene, which encodes the protein Ataxin2 (ATXN2). A polyglutamine (polyQ) tract consisting of CAG repeats interrupted by CAA was identified at exon 1 of ATXN2. Healthy individuals have between 22 and 23 glutamines, while expansions longer than 33 CAG repeats cause SCA2. The most noticeable symptom that SCA2 patients show is ataxic gait; however, they also show cerebellar dysarthria, dysdiadochokinesia, and ocular dysmetria caused by the progressive cerebellar degeneration.
To model the SCA2 disease, we generated a new mouse model where 100 CAG repeats were introduced in the mouse Atxn2 gene via homologous recombination. The characterization of this mouse model, Atxn2-CAG100-KIN, demonstrated that it reproduces the symptomatology observed in SCA2 patients. These animals showed significant loss of weight over time, brain atrophy, and motor deficits.
In addition, ATXN2 intermediate expansions have been linked to the pathology of Amyotrophic lateral sclerosis (ALS) as a risk factor. ALS is a fatal neurodegenerative disease where the motor neurons in the brain and spinal cord degenerate. A hallmark of ALS is the presence of TDP43-positive inclusions in neurons and glia. Further studies of post mortem spinal cord samples from SCA2 patients showed severe and widespread neurodegeneration of the central somatosensory system. Therefore, it was of interest to further investigate the pathology affection of this tissue in the Atxn2-CAG100-KIN line and the relationship between ATXN2 and TDP43. The characterization of the spinal cord pathology via protein quantification, transcript quantification, and immunohistochemistry showed a preferential affection of RNA binding proteins (RBP) in the spinal cord rather than the cerebellum. The ALS-linked factors TDP43 and TIA1 showed time-dependent co-aggregation with ATXN2 in spinal cord sections together with an increase of CASP3 levels. Therefore, this mouse model can help develop new therapies and evaluate their effect in differently affected areas.
A transcriptome data set from Atxn2-CAG100-KIN spinal cord samples at the final disease stage of this mouse model showed a strong up-regulation of RNA toxicity-, immune- and lysosome-implicated factors. These data pointed to a pathological reactivation of the synaptic pruning and phagocytosis in microglia. ATXN2-positive aggregates were found in microglia from spinal cord sections of 14-month-old Atxn2-CAG100-KIN via immunohistochemistry. The characterization of microglial response and the potentially deleterious effects of the expanded ATXN2 in this cell type could lead to therapies to improve patients’ living standards or delay the symptoms’ onset.
The second part of this thesis was focused on an autosomal recessive form of cerebellar ataxia, Ataxia Telangiectasia (A-T), with childhood onset. A-T patients show severe cerebellar atrophy manifesting as ataxia when the child starts to walk. The genetic cause of A-T is loss-of-function-mutations in the Ataxia Telangiectasia Mutated gene (ATM). ATM is a kinase involved in DNA damage response, oxidative stress, insulin resistance, autophagy via mTOR signaling, and synaptic function.
Working with proteome data from cerebrospinal fluid of 12 A-T patients and 12 healthy controls, we aimed to define novel biomarkers that would allow following the neurodegeneration in extracellular fluid. Additional validation efforts with ~2-month-old Atm-knock-out (Atm-/-) cerebellar samples helped us to define a scenario were the deficit of vesicle-associated ATM alters the secretion of ApoB, reelin, and glutamate. As extracellular factors, apolipoproteins and their cargo such as vitamin E may be useful for neuroprotective interventions.
Cardiovascular diseases are still regarded as the main cause of death in the modern world. However, the generic term "cardiovascular diseases" is not uniformly defined. It essentially describes diseases of the cardiovascular system and includes diseases such as hypertension, arteriosclerosis, myocardial infarctions, heart failure, coronary heart diseases, rheumatic heart diseases and heart valve defects. In addition to the well-known risk factors such as obesity, smoking, hypercholesterolemia and lack of exercise, age is a further risk factor that plays an important role in the development of cardiovascular diseases. As the modern societies age; this becomes an increasing problem.
But why does the prevalence of cardiovascular diseases increase with age? In gen-eral, age-dependent changes at the cellular level are assumed to be responsible for the pathological changes in the cardiac and vascular tissues. Important mechanisms such as autophagy, oxidative stress, mitochondrial dysfunctions, genomic instability, cellular senescence and disturbances in signaling pathways of growth factors play a decisive role. In old age, myocardial hypertrophy occurs, which results in cardiac wall thickening and an altered geometry of the ventricle. Chronic inflammations, paracrine and age-dependent cell-intrinsic factors further lead to activation of cardiac fibro-blasts with increase cell proliferation, collagen secretion and matrix cross-linking. The consequences are interstitial and perivascular fibrosis, which stiffen the heart and blood vessels. Oxidative stress and inflammations additionally attack the blood ves-sels and impair endothelial function, which is further aggravated by possible pre-existing conditions such as diabetes mellitus and hypertension.
In the past decades, the main focus has therefore been on researching these age-dependent changes in the hope of better understanding cardiovascular ageing and developing possible regenerative interventions. By studying the repair mechanisms of other organs such as the lungs and the bone marrow, the endothelium in particular showed a high regenerative capacity, which influences the proliferation and cell func-tion of the surrounding cells.
For a long time, the general opinion was that the endothelium is only the internal lin-ing of blood and lymphatic vessels, as well as the heart chambers, which as a single-layer barrier guarantees the integrity of the blood vessels. However, endothelial cells are very heterogeneous, depending on the type of blood vessel and the type of tis-sue they serve. In addition to their barrier function, endothelial cells also regulate the exchange of substances between blood and tissue, stimulate the formation of new blood vessels and re-model existing vascular networks. They are also able to re-structure the extracellular matrix that surrounds them. They release not only matrix proteins, but also cytokines and growth factors into the extracellular space. On de-mand, these factors are then released and stimulate angiogenesis or cell prolifera-tion. In addition, the secretion of various matrix proteins not only stabilizes the cellu-lar neighborhood, but also regulates various cell functions.
By modelling the endothelial environment - the so-called vascular niche - endothelial cells are able to communicate with the surrounding cells. As a result, a regenerative effect of the vascular niche has already been described in various organs. In the liv-er, for example, it has been shown that increased concentrations of endothelial Ang2 and decreased endothelial activin A after partial hepatectomy stimulate the prolifera-tion of hepatocytes and thus liver regeneration. In the bone marrow, endothelial cells mobilize stem cells via nitric oxide and in the lungs, endothelial MMP14 releases growth factors from the extracellular matrix, which stimulate epithelial cell prolifera-tion after partial pneumectomy. Whether such a regenerative effect of the vascular niche also plays a role in the heart is largely unknown.
Since both the regenerative capacity of the heart and endothelial function decrease with age, the aim of this dissertation was to investigate the role of the vascular niche and endothelial cell communication in the aged heart. Human cell lines as well as mouse and artificial rat models were used for these investigations. Since this thesis is a cumulative dissertation with partially published papers, it is divided into three parts.
In the first part of this thesis, the transcriptional signature of secretory genes in the aged cardiac endothelium was studied. Perfused endothelial cells from hearts of young (12-week-old animals) and old mice (20-month-old animals) were isolated and used for bulk RNA sequencing. The two matrix proteins laminin β1 and β2 were among the top-regulated genes. While laminin β2 was particularly expressed in the young cardiac endothelium, laminin β1 was predominantly found in the old endotheli-um. This change in laminin expression was confirmed histologically at protein level and its autocrine function was investigated in vitro. To mimic the in vivo situation in vitro, cell culture dishes were coated with human recombinant laminin 421 or laminin 411 and sutured with human endothelial cells from the umbilical vein (HUVEC). Di-verse functional investigations showed that endothelial cells migrated and adhered poorly in the presence of laminin 411, while in Matrigel tube formation assays HU-VEC formed reduced endothelial networks when cultured on LM 411.
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Der Neocortex der Säugetiere weist charakteristische Schichtungen auf, und jede dieser Schichten enthält verschiedene Typen von Neuronen, die in stereotypen Mustern angeordnet sind. Die Ausbildung dieser geschichteten Struktur ist nur dann möglich, wenn korrekte Migration von Neuronen von proliferativen Zonen zu deren Endpositionen stattfindet. Die exakte Migration und Schichtung wird von Mutationen beeinflusst, die entweder die migratorische Fähigkeit der Neuronen beeinträchtigen, oder deren Fähigkeit, die Position zu erkennen, an der sie die Wanderung beenden sollten (Gupta et al., 2002, Rice et al., 2001, Walsh et al., 2000). In den letzten Jahren wurde das extrazelluläre Protein Reelin als wichtiger Faktor bekannt, der sich auf mehrere Schritte der neuronalen Migration und Schichtung in der Großhirnrinde auswirkt (zusammengefasst in (Tissir et al., 2003). Das sekretierte Glykoprotein Reelin kontrolliert die Migration der Neuronen durch die Bindung an zwei Lipoproteinrezeptoren, den Very-low-density lipoprotein Rezeptor (VLDLR) und den Apolipoprotein E Rezeptor 2 (ApoER2) (D'Arcangelo et al., 1999). Die Bindung von Reelin an ApoER2 und VLDLR ruft die Phosphorylierung von Disabled-1 (Dab1) (D'Arcangelo et al., 1999, Howell et al., 1997), einem Adapterprotein, das an die intrazelluläre Domäne der Rezeptoren bindet, hervor, indem sie Kinasen der Src-Familie (SFKs) aktiviert (Arnaud et al., 2003, Bock et al., 2003a). Außer der Bedeutung des Reelin-Signalwegs für die korrekte Entwicklung des Nervensystems und dem Wissen, dass die Unterbrechung dieses Signalwegs zu verschiedenen neurologischen Krankheiten wie Epilepsie, Schizophrenie und der Alzheimerkrankheit führt (Costa et al., 2002, Botella-Lopez et al., 2006, Herz et al., 2006), ist die molekulare Grundlage der Aktivierung dieses Signalwegs an der Zellmembran noch kaum charakterisiert. Da VLDLR und ApoER2 keine intrinsische Kinaseaktivität besitzen, wurde die Existenz eines Korezeptors für mindestens eine Dekade vermutet, und die genaue Natur dieses Korezeptors ist unbekannt. EphrinBs, Transmembranliganden für Eph-Rezeptoren, besitzen die Fähigkeit zur Signalgebung, die für synaptische Plastizität und Angiogenese durch Sprossung erforderlich ist, indem sie die Aktivität anderer Transmembranrezeptoren wie AMPAR beziehungsweise VEGFR2 beeinflussen (Sawamiphak et al., 2010b, Segura et al., 2007, Essmann et al., 2008). Darüber hinaus führt die Stimulation von cortikalen Neuronen in Kultur mit löslichen EphB-Rezeptoren zur Rekrutierung und Aktivierung von SFKs in Membranpatches, in denen sich ephrinB-Liganden befinden (Palmer et al., 2002). Deshalb nehmen wir an, dass ephrinB in vivo funktionell mit dem Reelin-Signalweg verbunden sein könnte. Der Fokus dieser Arbeit liegt darin, zu zeigen, dass das neuronale Wegweisermolekül ephrinB einen entscheidenden Korezeptor für die Reelin-Signalgebung während der Entwicklung geschichteter Strukturen im Gehirn darstellt. Um zu erforschen, ob ephrinB und die Reelin-Signalgebung in vivo genetisch interagieren, wurden zuerst Mäuse mit Compound-Mutationen hergestellt, die eine Nullmutation im Gen für ephrinB3 tragen und heterozygot für Reelin sind (rl/+; b3-/-). Reeler ist eine autosomal rezessive Mutation der Maus, die, wenn sie heterozygot auftritt, keinen offenkundigen Phänotyp aufweist (Caviness et al., 1972, Caviness et al., 1978). Wir zeigen, dass ephrinBs genetisch mit Reelin interagieren, da Mäuse mit Compound-Mutationen (rl/+; b3 -/-) und ephrinB1-, B2- und B3-Dreifach-Knockouts die verschiedenen Defekte in der Entwicklung phänokopieren, die im Neocortex, Hippocampus und Cerebellum der reeler-Mäuse beobachtet wurden. Eines der Kennzeichen des reeler-Phänotyps ist die gestörte Schichtung der Großhirnrinde mit einer Marginalzone (MZ), die eine äußerst große Zahl an Zellen enthält (Caviness, 1982). Sowohl die Compound-Mäuse als auch die Triple-ephrinB1B2B3-knockouts zeigten eine Zunahme der Zellzahl in der MZ. Um die cortikalen Defekte detailliert zu charakterisieren, wurde die Verteilung von postmitotischen migrierenden Neuronen im Cortex von rl/+; b3-/- Compound-Mäusen mit Hilfe von unterschiedlichen schichtenspezifischen Markern für früh (Tbr1) (Hevner et al., 2001) und spät entstandene (SatB2 and Brn1) (Britanova et al., 2008, McEvilly et al., 2002) Neuronen, analysiert . Unsere Untersuchungen ließen die veränderte cortikale Schichtung in den rl/+; b3-/- Compound-Mäusen erkennen. So befanden sich früh entstandene Neuronen in den oberen cortikalen Schichten und spät entstandene in den unteren cortikalen Schichten, was für eine outside-in-Schichtung spricht, wie man sie von reeler kennt. Interessanterweise ist eine der frühesten strukturellen Abnormalitäten, die man im reeler-Cortex erkennen kann, die Unfähigkeit, die Preplate, die reich an extrazellulärer Matrix ist, in die Marginalzone und die Subplate aufzuspalten (Sheppard et al., 1997). Zum Zeitpunkt E17.5 zeigten rl/+; b3-/- Compound-Mäuse eine beachtliche Anhäufung von Chondroitin-Sulfat-Proteoglykan (CSPG), einer Komponente der extrazellulären Matrix, im gesamten Neocortex mit einer ungeteilten Schicht an der Oberfläche, welche übermäßig viel CSPG enthielt und somit die abnorme Teilung der Preplate der reeler-Maus nachahmte. Um zu bestätigen, dass die beobachteten Effekte auf die Schichtung des Cortex der rl/+; b3-/- Compound-Mäuse als Folge der Beeinträchtigung der neuronalen Migration auftritt, wurden zusätzlich BrdU-Puls-Experimente durchgeführt. BrdU wird in sich teilende Vorläuferzellen eingebaut und spiegelt deshalb das migratorische Verhalten von neu entstandenen Neuronen zum Zeitpunkt der Injektion wieder. Schwangeren Weibchen wurde BrdU zu den Zeitpunkten E12.5, E15.5 und E17.5 injiziert und die Gehirne wurden am postnatalen Tag 20 ausgewertet. Die Verteilung der mit BrdU gekennzeichneten Neuronen zu verschiedenen Zeitpunkten der Entwicklung in der Großhirnrinde bestätigte unsere Untersuchungen, die mit Hilfe der schichtspezifischen Marker durchgeführt worden waren. Deshalb deuten unsere Ergebnisse an, dass die beobachteten Defekte in der Schichtung des Cortex tatsächlich eine Folge von beeinträchtigter neuronaler Migration sind. Es wurde beobachtet, dass auch geschichtete Strukturen im Hippocampus in den rl/+; b3-/- Compound-Mäusen verändert sind, was für einen Crosstalk zwischen ephrinB3 und Reelin auch während der Entwicklung des Hippocampus spricht. Die CA1-Region des Hippocampus zeigte eine lockere Verbindung der pyramidalen Zellschichten, welche zu einer signifikanten Erhöhung der Dicke dieser Region und zu einer Einwanderung von Pyramidalzellen in das Stratum oriens führte. Darüber hinaus haben die Anomalien in den dendritischen Verzweigungen von Pyramidalneuronen der CA1-Region, die in Richtung der Reelin-produzierenden Cajal-Retzius-Zellen im stratum locunosum moleculare projizieren, in den rl/+; b3-/- Compound-Mäusen eine auffallende Ähnlichkeit mit denen, die in reeler-Mutanten beobachtet wurden. Reelin fungiert auch als Differenzierungsfaktor und Positionierungssignal für radiale Gliazellen, die positiv für glial fibrillary acidic protein (GFAP) sind und ein Gerüst für die korrekte Migration von neu entstandenen Granularzellen, die auf das Netzwerk der Granularzellen im Gyrus dentatus zuwandern (Forster et al., 2002) bilden. In rl/+; b3-/- Compound-Mäusen ist dieses Gerüst aus radialen Gliazellen schwerwiegend beeinträchtigt, was ebenfalls zu einer lockeren Organisation der Granularzellen im Gyrus dentatus führt. Die Ataxie in reeler-Mäusen ist das Ergebnis einer schwerwiegenden Fehlorganisation im Cerebellum dieser Mutanten (Tissir et al., 2003). Interessanterweise wurden nur milde Defekte in den Granularzellen, die sich in der internen Granularschicht des Cerebellums von rl/+; b3-/- Compound-Mäusen angesammelt haben, und keine Defekte in der Migration und der Verzweigung der Purkinjezellschicht, festgestellt. Stattdessen ist ephrinB2 in den Purkinjezellen des Cerebellums stark exprimiert (Liebl et al., 2003) und obwohl keine bedeutenden Defekte der Migration dieser Zellen festgestellt wurden, zeigte die Untersuchung der Verzweigung der Purkinjezellen in b2-/- Mäusen eindeutige Defekte, die bereits in einfachen ephrinB2-Mutanten auftraten. Bedeutend ist, dass die Defekte in der Verzweigung bei rl/+; b2-/- Compound-Mäusen signifikant verstärkt waren, was darauf hindeutet, dass der Reelin-Signalweg im Cerebellum spezifisch ephrinB2 benötigt. Um Einblicke in den Mechanismus zu erhalten, wie ephrinB-Liganden den Crosstalk mit Reelin durchführen, um die korrekte Positionierung von Neuronen in den geschichteten Strukturen des Gehirns zu kontrollieren, wurde als nächstes die biochemische Interaktion dieser beiden Signalwege untersucht. In einer gerichteten proteomischen Untersuchung mit Hilfe der Tandem affinity purification-mass spectometry-Methode (Angrand et al., 2006) von Proteinen aus eine Neuroblastom-Zelllinie, die ephrinB binden, wurde Reelin als ein Protein, das mutmaßlich mit ephrinB interagiert, identifiziert. Zunächst bestätigten wir die Fähigkeit von Reelin, mit ephrinBs zu assoziieren mit Ko-Immunpräzipitation beider endogener Proteine aus Gehirnlysaten. Das extrazelluläre Protein Reelin zeigte eine starke Bindung an die extrazelluläre Domäne von ephrinB3 und auch von ephrinB2, was andeutet, dass beide ephrin-Liganden die Funktionen von Reelin in vivo beeinflussen könnten. Die Stimulierung von cortikalen Neuronen mit Reelin führt zu einer effektiven Tyrosin-Phosphorylierung des Adapters Dab1. Da die Stimulation von cortikalen Neuronen mit einer löslichen, vorgeclusterten Form von EphB-Rezeptoren zur Rekrutierung und Aktivierung von Src-Kinasen in ephrinB-Clustern führt (Palmer et al., 2002), nehmen wir an, dass ephrinBs Src-Kinasen in VLDLR- und ApoER2-Rezeptor-Clustern rekrutieren und aktivieren könnten. Aktivierte Src-Kinasen phosphorylieren dann wiederum das Adapterprotein Dab1, das an VLDLR und ApoER2 gebunden ist und initiieren die weitere Signalgebung. In Übereinstimmung damit ko-immunpräzipitiert phosphoryliertes Dab1 zum Zeitpunkt E16.5 mit ephrinBs, während die neuronale Migration und die Schichtung des Cortex stattfindet. Darüber hinaus konnten wir beobachten, dass ephrinB3, das durch EphB3-Fc aktiviert wurde, sowohl Reelin, als auch ApoER2 und VLDLR in ephrinB3-Membranpatches in cortikalen Neuronen anhäuft. Die Aktivierung von ephrinB-Liganden durch Stimulation von cortikalen Neuronen mit EphB3-Fc führt zur Rekrutierung und Phosphorylierung von Dab1 in ephrinB-Clustern. Als nächstes befassten wir uns mit der Notwendigkeit von der durch ephrinB vermittelten Rekrutierung und Aktivierung von Src-Kinasen für den Reelin-Signalweg, indem wir Loss-of-function-Studien sowohl in cortikalen Neuronen in Kultur als auch in vivo in Mäusen durchführten. Cortikale Neuronen, die aus ephrinB3- und ephrinB2-Knockouts isoliert wurden, zeigten eine signifikante Beeinträchtigung der durch Reelin vermittelten Phosphorylierung von Dab1 und die Phosphorylierungslevels von Dab1 in ephrinB3 Mausmutanten waren stark verringert, was andeutet, dass ephrinBs Korezeptoren, die notwendig für einwandfreie Signalgebung durch Reelin sind, darstellen. Um die Bedeutung von ephrinBs für die Kontrolle der Funktion von Reelin zu untersuchen, arrangierten wir eine Reihe von Rescue-Experimenten sowohl in Neuronenkulturen als auch während der neuronalen Migration im Cortex in vivo. Aus reeler-Mäusen isolierte cortikale Neuronen zeigten die erwartet verringerte Phosphorylierung von Dab1, die rückgängig gemacht werden konnte, indem die Neuronen mit exogenem Reelin stimuliert wurden. Noch bedeutender ist die Tatsache, dass die Phosphorylierung von Dab1 durch die alleinige Aktivierung von ephrinBs mit EphB wiederhergestellt werden konnte, was die Bedeutung der ephrinBs als Korezeptoren für die Aktivierung des Signalwegs über die Rezeptoren für Reelin, VLDLR und ApoER2, wiederspiegelt. Um die Rolle von ephrinBs als Korezeptoren für den Reelin-Signalweg während der neuronalen Migration in der Großhirnrinde zu unterstreichen, setzten wir ähnliche Rescue-Experimente in organotypischen Schnittkulturen an. In den Schnitten von reeler-Mäusen und Wildtyp-Wurfgeschwistern wurde die Migration von Neuronen, die durch Fc als Kontrolle und EphB3-Fc stimuliert wurde, nach drei Tagen in Kultur untersucht. Die reeler-Schnitte zeigten den typischen reeler-Phänotyp in der Großhirnrinde. In Übereinstimmung mit der Annahme einer wirksamen Regulation des Reelin-Signalwegs war die Aktivierung von eprhinB mit EphB-Rezeptoren in der Lage, die migratorischen Defekte in reeler-Schnitten aufzuheben. Zusammengefasst identifizieren unsere Ergebnisse ephrinBs als Korezeptoren für den Reelin-Signalweg, die für die Funktion von Reelin in der neuronalen Migration während der Entwicklung der geschichteten Strukturen der Großhirnrinde, dem Hippocampus und dem Cerebellum notwendig sind. Unsere genetischen Analysen von ephrinB-Mutanten zeigen gemeinsam mit starken biochemischen Untersuchungen, dass ephrinBs in vivo für zahlreiche Aktivitäten von Reelin erforderlich sind.
Exploring the in vivo subthreshold membrane activity of phasic firing in midbrain dopamine neurons
(2021)
Dopamine is a key neurotransmitter that serves several essential functions in daily behaviors such as locomotion, motivation, stimulus coding, and learning. Disrupted dopamine circuits can result in altered functions of these behaviors which can lead to motor and psychiatric symptoms and diseases. In the central nervous system, dopamine is primarily released by dopamine neurons located in the substantia nigra pars compacta (SNc) and ventral tegmental area (VTA) within the midbrain, where they signal behaviorally-relevant information to downstream structures by altering their firing patterns. Their “pacemaker” firing maintains baseline dopamine levels at projection sites, whereas phasic “burst” firing transiently elevates dopamine concentrations. Firing activity of dopamine neurons projecting to different brain regions controls the activation of distinct dopamine pathways and circuits. Therefore, characterization of how distinct firing patterns are generated in dopamine neuron populations will be necessary to further advance our understanding of dopamine circuits that encode environmental information and facilitate a behavior.
However, there is currently a large gap in the knowledge of biophysical mechanisms of phasic firing in dopamine neurons, as spontaneous burst firing is only observed in the intact brain, where access to intrinsic neuronal activity remains a challenge. So far, a series of highly-influential studies published in the 1980s by Grace and Bunney is the only available source of information on the intrinsic activity of midbrain dopamine neurons in vivo, in which sharp electrodes were used to penetrate dopamine neurons to record their intracellular activity. A novel approach is thus needed to fill in the gap. In vivo whole-cell patch-clamp method is a tool that enables access to a neuron’s intrinsic activity and subthreshold membrane potential dynamics in the intact brain. It has been used to record from neurons in superficial brain regions such as the cortex and hippocampus, and more recently in deeper regions such as the amygdala and brainstem, but has not yet been performed on midbrain dopamine neurons. Thus, the deep brain in vivo patch-clamp recording method was established in the lab in an attempt to investigate the subthreshold membrane potential dynamics of tonic and phasic firing in dopamine neurons in vivo.
The use of this method allowed the first in-depth examination of burst firing and its subthreshold membrane potential activity of in vivo midbrain dopamine neurons, which illuminated that firing activity and subthreshold membrane activity of dopamine neurons are very closely related. Furthermore, systematic characterization of subthreshold membrane patterns revealed that tonic and phasic firing patterns of in vivo dopamine neurons can be classified based on three distinct subthreshold membrane signatures: 1) tonic firing, characterized by stable, non-fluctuating subthreshold membrane potentials; 2) rebound bursting, characterized by prominent hyperpolarizations that initiate bursting; and 3) plateau bursting, characterized by transient, depolarized plateaus on which bursting terminates. The results thus demonstrated that different types of phasic firing are driven by distinct patterns of subthreshold membrane activity, which may potentially signal distinct types of information. Taken together, the deep brain in vivo patch-clamp technique can be used for the investigation of firing mechanisms of dopamine neurons in the intact brain and will help address open questions in the dopamine field, particularly regarding the biophysical mechanisms of burst firing in dopamine neurons that control behavior.