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In the adult mammalian brain stem cells within defined neurogenic niches retain the capacity for lifelong de novo generation of neurons. The subventricular zone (SVZ) of the lateral ventricles and the subgranular layer (SGL) of the hippocampal dentate gyrus (DG) have been identified as the two major sites of adult neurogenesis. Moreover, the third ventricle in the hypothalamus is emerging as a new neurogenic niche in the adult brain. Extracellular purine and pyrimidine nucleotides are involved in the control of both embryonic and adult neuro-genesis. These nucleotides act via ionotropic P2X or metabotropic P2Y receptors and studies of the adult SVZ and the DG provide strong evidence that ATP promotes progenitor cell proliferation in this stem cell rich regions. Previous studies have shown that the extracellular nucleotide-hydrolyzing enzyme NTPDase2 is highly expressed by adult neural stem and progenitor cells of the SVZ and the rostral migratory stream (RMS), the hippocampal SGL, and the third ventricle. NTPDase2 preferentially hydrolyzes extracellular nucleoside triphosphates (NTPs) and, to a lower extent, diphosphates, thus modulating their effect on nearby nucleotide receptors. Deletion of the enzyme increases extracellular NTP concentrations, and might indicate roles of purinergic signaling in adult neurogenesis. As shown by enzyme histochemistry, genetic deletion of NTPDase2 essentially eliminates ATPase activity in neurogenic niches but does not affect protein expression levels and activity of other ectonucleotidases. Lack of NTPDase2 leads to expansion of the hippocampal stem cell pool as well as of the inter-mediate progenitor type-2 cells. Cell expansion is lost at around type-3 stage, paralleled by increased labeling for caspase-3, indicating increased apoptosis, and decreased levels in CREB phosphorylation in doublecortin-expressing cells, diminishing survival in this cell population. In line with increased cell death, P2Y12 receptor-expressing microglia is enriched at the hilus orientated side of the granule cell layer. These data strongly suggest that NTPDase2 functions as central homeostatic regulator of nucleotide-mediated neural progenitor cell proliferation and expansion in the adult brain by balancing extracellular nucleotide concentrations and activation of purinergic receptors.
In order to further characterize the role of purinergic signaling in adult neurogenesis, the ADP-sensitive P2Y13 receptor was identified as a potential candidate whose activation might inhibit neurogenesis in the hippocampal dentate gyrus and the newly identified neurogenic niche at the third ventricle. Deletion of P2ry13 increased progenitor cell proliferation and long-term progenitor survival as well as new neuron formation in the hippocampal neurogenic niche. This was further paralleled by increased thickening of the granule cell layer, CREB phosphorylation, and expression of the neuronal activity marker c-Fos. Increased progenitor cell proliferation and progenitor survival persist in aged P2ry13 knockout animals. However, in the ventral dentate gyrus proliferation and expansion levels of progenitor cells did not differ significantly from the wild type. This study strongly supports the notion that extracellular nucleotides significantly contribute to the control of adult neurogenesis in the dentate gyrus in situ. Data in this work suggest that activation of the P2Y13 receptor dampens progenitor cell proliferation, new neuron formation, and neuronal activity. In contrast to several in vitro studies and studies in the SVZ in situ, a contribution of the ATP/ADP-sensitive P2Y1 receptor could not be confirmed in the dentate gyrus in vivo.
To unravel implications of purinergic signaling and P2Y13 receptor action in the control of adult hypothalamic neurogenesis a pilot study was performed. Mice null for P2ry13 revealed increased progenitor cell proliferation at the third ventricle as well as long-term progeny survival and new neuron formation in the hypothalamus. In contrast to results obtained in the dentate gyrus expression of the neuronal activity marker c-Fos was significantly decreased in hypothalamic nuclei, indicating increased inhibition of appetite-regulating neuronal circuits by surplus neurons in knockout animals. These data provide first evidence that extracellular nucleotide signaling contributes to the control of adult hypothalamic neurogenesis in situ. Activation of the P2Y13 receptor inhibits progenitor cell proliferation, long-term survival and neuron formation and therefore controls inhibition of appetite-regulating circuits in the adult rodent hypothalamus.
Fuer die schlechte Prognose von Glioblastompatienten mit einer ueberlebenszeit von 9-15 Monaten (Norden and Wen, 2006) ist vor allem die hohe Invasivitaet dieser Tumore verantwortlich. Nach operativer Entfernung des Haupttumors entstehen aus den verbleibenden invadierten Zellen sekundaere Tumore, die sich mitunter ueber weite Bereiche des Hirns verteilen. Des Weitern sind die hochinvasiven Tumorzellen oft resistent gegen Chemo- und Strahlentherapie (Drappatz et al., 2009; Lefranc et al., 2005). In Maustumormodellen und Pateinten konnte zudem gezeigt werden, dass die neuartige antiangiogenetische Therapie zwar das Tumorwachstum verringert, jedoch die Invasivitaet stark erhoeht. (Norden et al., 2008; Ebos et al., 2009; Paez-Ribes et al., 2009). Ueber die Mechanismen die diese hohen Invasivitaet induzieren, ist bislang nur sehr wenig bekannt. Die durch Reduktion von Blutgefaessen steigende Hypoxie des Tumors foerdert die Expression von Matrix-Metalloproteinasen (MMPs). Dies fuehrt zum Abbau der extrazelluaeren Matrix des umgebenden gesunden Gewebes und beguenstigt dadurch die Tumorzellinvasion (Indelicato et al., 2010; Miyazaki et al., 2008; Shyu et al., 2007). Die Umformung des Aktinzytoskeletts und damit die Mobilitaet von Zellen wird vorwiegend durch ein akkurates Zusammenspeil der Rho GTPasen Rac, Rho und Cdc42, kontrolliert (Ridley et al., 2003). Fuer die Organisation von Axonen im Nervensystem und fuer die Blut- und Lymphgefaessbildung wurde gezeigt, dass die Interaktion der Eph-Rezeptortyrosinkinasen und Ihrer Ephrin-Liganden Signalwege induziert, die in die Regulation dieses Zusammenspiels involviert sind (Egea and Klein, 2007; Makinen et al., 2005; Palmer et al., 2002; Sawamiphak et al., 2010). Des Weiteren zeigt die Analyse der Genloci von Eph-Rezeptoren und Ephrinen in verschieden Hirntumoren eine gehaeufte Deletionen des Ephrin-B2-Gens. Die Quantifizierung von Ephrin-B2 mRNA in diesen Tumoren hat ausserdem ergeben, dass mit zunehmender Malignitaet die Expression von Ephrin-B2 sinkt. Aus diesen Gruenden wurden die Untersuchungen in dieser Arbeit auf die Rolle von Ephrin-B2 anhaengigen Signalwegen in der Glioblastomzellinvasion konzentriert. In einem modifiziertem Boyden-Chamber-Assay konnte gezeigt werden, dass das Ephrin-B2 induzierte EphB4 forward signaling und EphB4 induzierte Ephrin-B2 reverse signaling die Invasivitaet der human Glioblastomzelllinien LN-229, G55 und SNB-19 reduziert. In einem Maustumormodel konnte weiterhin gezeigt werden, dass Ephrin-B2 Knock-Out (KO) Astrozytomzellen, im Vergleich zu Wild-Typ (WT) Zellen, Tumore mit einem groesseren Volumen und einer erhoehten Invasivitaet bilden. Da die Expressionslevel fuer die Ephrin-B2 bindenden Rezeptoren EphA4, EphB1 EphB3 und EphB6 auch im adulten Hirn hoch sind (Hafner et al., 2004), weisen diese in vitro und in vivo Ergebnisse auf eine Tumorsupressorfunktion von Ephrin-B2 hin, die durch repulsive Effekte des Ephrin-B2 reverse signaling vermittelte werden koennten. Dies geht mit Erkenntnissen ueber kolorektale Tumore einher (Batlle et al., 2005). Die in einem Sphaeroid-Invasionsassay mit einer EphB-Rezeptoren freien Umgebung beobachtete verminderte Invasion von Ephrin-B2 WT deutet auf eine zusaetzliche invasionsblockierende Rolle der Ephrin-B2-Eph-Rezeptor Interaktion zwischen benachbarten Tumorzellen hin, wie sie auch in Brusttumoren gefunden wurde (Noren et al., 2006). Es scheint als sei Tumorprogression und Invasion erst moeglich, nachdem die Expression von Ephrin-B2 vermindert wurde. Es konnte weiterhin gezeigt werden, dass in hypoxischen Glioblastomzellen die Ephrin-B2 Expression durch die direkte Bindung des den Transkriptionsfaktors ZEB2 an den Ephrin-B2 Promoter reprimiert wird. In einem Weiteren Maustumormodel konnte gezeigt werden, dass die Blockierung der ZEB2 Expression mittels shRNA und die damit einhergehenden Inhibition der hypoxie induzierten Ephrin-B2 Repression das Wachstum und die Invasivitaet von Glioblastomen verringert. Zusaetzlich wurde gezeigt, dass der Verlust von ZEB2 ausreicht, die durch antiangiogenetische Therapie induzierte stark erhoehte Invasivitaet zu vermeiden. Die in dieser Arbeit gewonnen Erkenntnisse fuehren zu folgendem Modelmechanismus. In kleinen normoxischen Tumoren koennen repulsive Effekte des Ephrin-B2 reverse signalings und EphB forward signalings zwischen Tumorzellen und Zellen des umgebenden Gewebes die Ausbreitung und Invasion des Tumors unterdruecken. Zusaetzlich koennte das Ephrin-B2 induzierte EphB forward signaling zwischen benachbarten Tumorzellen die Mobilitaet der Tumorzellen wie in Brusttumoren inhibieren. Beim Erreichen einer bestimmten Tumorgroesse tritt Hypoxie auf, wodurch HIF-1alpha stabilisiert wird. Dies fuehrt dann zur ZEB2 Expression und leitet die Repression von Ephrin-B2 ein, was wiederum zur erhoehten Tumorzellemobilitaet und im Zusammenspiel mit MMPs zu Invasion fuehren kann. Gleichzeitig werden durch den HIF-induzierten VEGF-Gradienten neue Blutgefaesse rekrutiert. Damit wird der hypoxie-induzierten Invasivitaet entgegengewirkt. Wird mittels antiangiogenetischer Behandlung versucht Tumorprogression entgegenzuwirken, resultiert daraus eine erneut gesteigerte Hypoxie, die dann durch die ZEB2 vermittelte Repression von Ephrin-B2 wieder eine erhoehte Invasivitaet induzieren kann. Das Blockieren der ZEB2 Expression kann dieser durch antiangiogenetischen Behandlung induzierten Invasivitaet entgegenwirken.
Synaptic plasticity is the basis for information storage, learning and memory and is achieved by modulation of the synaptic transmission. The amount of active AMPA (α-amino-3-hydroxy-5-methyl-4-isoxazol-propionic acid) receptors at the synapse determines the transmission properties, therefore the regulation of AMPA receptor trafficking affects the synaptic strength. The protein GRIP (glutamate receptor interacting protein) binds to AMPA receptors and is one of the important regulators of AMPA receptor stability at the synapse (Dong et al., 1997; Osten et al., 2000). Previous studies have shown that the ablation of ephrinB2 or ephrinB3 in the nervous system leads to severe defects in hippocampal LTP (long term potentiation) and LTD (long term depression) (Grunwald et al., 2004). We found that ephrinB2 ligands play an important role in the stabilization of AMPA receptors at the cellular membrane (Essmann et al., 2008). Treating cultured hippocampal neurons with AMPA resulted in a robust AMPA receptor internalization, which could be inhibited by simultaneous ephrinB2 activation with soluble EphB4-Fc fusion proteins. Conditional hippocampal ephrinB2 knock-out (KO) neurons showed enhanced constitutive internalization of AMPA receptors. Interaction and interference experiments revealed that ephrinB ligands and AMPA receptors are bridged by GRIP. This interaction is regulated by phosphorylation of a single serine residue in close proximity to the C-terminal PDZ protein target site in ephrinB ligands (Essmann et al., 2008). To investigate the in vivo relevance of this previously undescribed feature of ephrinB reverse signaling, we generated ephrinB2 S-9>A knock-in mice, where the serine at position -9 was replaced by an alanine to prevent phosphorylation. The mutated ephrinB2 of this mouse line was expressed and able to form clusters following stimulation with the preclustered receptor EphB4-Fc. Surface ephrinB2 cluster size and cluster number was slightly smaller in comparison to wild type (WT) mice. Analyzing AMPA receptor internalization, we oserved an increased basal GluR2 endocytosis in cultured hippocampal neurons of ephrinB2 S-9>A mice. Dendrite and spine morphology was similar in pyramidal CA1 neurons of brain slices from adult ephrinB2 S-9>A and WT mice, suggesting a redundancy between the different ephrinB familily members.
Apart from regulating AMPA receptor stability at the synapse, GRIP1 also has an important role in the secretory pathway to deliver cargo proteins along microtubules to dendrites and synapses (Setou et al., 2002). Proteins involved in synaptic transmission and plasticity, as well as lipids required for the outgrowth and remodeling of dendrites and axons have to be transported. We showed in our laboratory with a directed proteomic analysis using the tandem affinity purification-mass spectrometry methodology (Angrand et al., 2006) and with immunoprecipitation assays with brain lysates that the small regulatory protein 14-3-3 interacts with GRIP1. Further immunoprecipitation assays with lysates from HeLa cells transfected with various parts and sequence mutants of GRIP1 revealed that threonine 956 in the linker region L2 between PDZ6 and PDZ7 of GRIP1 is necessary for the interaction with 14-3-3. GRIP1 has been postulated to influence dendritic arborization and maintenance in hippocampal neurons in culture due to defective kinesin-dependent transport along microtubules (Hoogenraad et al 2005). In order to address the role of the association of GRIP1 and 14-3-3 in dendritogenesis, we transfected rat hippocampal neurons with GRIP1-WT and GRIP1 mutants and performed Sholl analysis to evaluate dendritic arborization defects. We could observe striking increased formation and growth of dendrites in developing neurons as well as in mature neurons overexpressing GRIP1-WT. However, overexpression of GRIP1-T956A, where the threonine 956 was replaced by an alanine to prevent phosphorylation, did not show enhanced dendritogenesis, indicating a role for threonine 956 phosphorylation in dendrite branching. To investigate the importance of the interaction between GRIP1 and 14-3-3 in vivo, we generated transgenic mouse lines with a GRIP1-T956A transgene or a GRIP1-WT transgene as control. These mice were crossed with heterozygous GRIP1 mice and by further breedings we obtained some surviver mice carrying either the wild type or the mutated GRIP1 transgene in the usually embryonic lethal GRIP1-KO background (Bladt et al., 2002; Takamiya et al., 2004). In embryonic day (E) 14.5 cultured hippocampal GRIP1-KO neurons we could observe reduced dendritic growth. We also showed reduced GluR2 staining on the dendritic surface in cultured hippocampal neurons from GRIP1-KO and GRIP1-KO neurons containing the GRIP1-T956A transgene. GRIP1-KO neurons containing the GRIP1-WT transgene showed a similar surface GluR2 signal intensity as WT neurons. Reduced surface GluR2 staining in GRIP1-KO neurons and GRIP1-KO neurons with the GRIP1-T956A transgene might be a consequence of defective kinesin-dependent transport of GluR2 to dendrites, indicating an important role of threonine 956 phosphorylation of GRIP1 for GluR2 trafficking.
Nervous system development requires a sequence of processes such as neuronal migration, the development of dendrites and dendritic spines and the formation of synapses. The extracellular matrix protein Reelin plays an important role in these processes, Reelin regulates for example the migration of neurons from proliferative zones to their target positions in the brain. As a consequence, layered structures are formed in the neocortex, the hippocampus and cerebellum (Lambert de Rouvroit et al., 1999). Reelin exerts its functions by binding to two transmembrane receptors, apolipoprotein E receptor 2 (ApoER2) and very-low-density lipoprotein receptor (VLDLR). This binding causes phosphorylation of the intracellular adapter protein Disabled-1 (Dab1) (D’Arcangelo et al., 1999) via activation of Src-family kinases (SFKs) (Bock and Herz, 2003), leading to cytoskeletal reorganization which enables cell migration and morphological changes (Lambert de Rouvroit and Goffinet, 2001). Since ApoER2 and VLDLR do not possess intrinsic kinase activity to activate SFKs, the existence of a co-receptor was suggested. EphrinBs are transmembrane ligands for Eph receptors and have signaling capabilities required for axon guidance (Cowan et al., 2004), dendritic spine maturation (Segura et al., 2007) and synaptic plasticity (Essmann et al., 2008; Grunwald et al., 2004). As stimulation of cultured cortical neurons with soluble EphB receptors causes recruitment of SFKs to ephrinB-containing membrane patches and SFK activation (Palmer et al., 2002), we investigated whether ephrinB ligands would be the missing co-receptors in the Reelin signaling pathway functioning during neuronal migration, dendritic spine maturation and synaptic plasticity. We found that the extracellular part of ephrinBs directly binds to Reelin and that ephrinBs interact with Dab1, phospho-Dab1, ApoER2 and VLDLR. EphrinB3 is localized in the same neurons as ApoER2 and Dab1 in the cortex and hippocampus, and in the cerebellum ephrinB2 is detected in neurons that express Dab1. To investigate the requirement of ephrinBs for neuronal migration, triple knockout mice lacking all ephrinB ligands were analyzed. The cortical layering of ephrinB1, B2, B3 knockout brains is inverted, showing the outside-in pattern typical for the reeler cortex. The hippocampus and cerebellum of triple knockout mice also exhibit reeler-like malformations, although less penetrant than the cortical defects. Dab1 phosphorylation is impaired in mice lacking ephrinB3 and this effect is strongly enhanced in neurons lacking all ephrin ligands. Moreover, activation of ephrinB3 reverse signaling induces Dab1phosphorylation in reeler primary neurons. In agreement with an important regulatory function of ephrinBs in Reelin signaling, activation of ephrinB3 reverse signaling is even able to rescue reeler defects in cortical layering in organotypic slice cultures. In summary, all these results identify ephrinBs as co-receptors for Reelin signaling, playing essential roles in neuronal migration during the development of cortex, hippocampus and cerebellum (Sentürk et al., 2011).
Angiogenesis, the formation of new blood vessels from existing ones, is a fundamental biological process required for embryonic development; it also plays an important role during postnatal organ development and various physiological and pathological remodeling processes in the adult organism. Vascular endothelial growth factor (VEGF) and its main receptor, VEGF receptor-2 (VEGFR-2), play a central role in angiogenesis. VEGFR-2 expression is strongly upregulated in angiogenic vessels, but the mechanisms regulating VEGFR-2 expression are not well understood. We found in this study that the G-protein α subunit Gα13 plays an important role in the regulation of VEGFR-2 expression. In vitro, we found that knockdown of Gα13 reduced VEGFR-2 expression in human umbilical vein endothelial cells and impaired responsiveness to VEGF-A. This phenotype was rescued by adenoviral normalization of VEGFR-2 expression. Gα13-dependent VEGFR-2 expression involved activation of the small GTPase RhoA and transcription factor NF-κB; it was abrogated by deletion of the NF-κB binding site at position -84 of the VEGFR-2 promoter. In vivo, endothelial cell-specific loss of Gα13 resulted in reduced VEGFR-2 expression, impaired responsiveness towards VEGF-A in Matrigel assays, and reduced retinal angiogenesis. Importantly, also tumor vascularization was diminished in the absence of endothelial Gα13, resulting in reduced tumor growth. Taken together, we identified Gα13-dependent NF-κB activation as a new pathway underlying the transcriptional regulation of VEGFR-2 during retinal and tumor angiogenesis.
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.