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Chronic pain conditions are a major reason for the utilization of the health care system. Inflammatory pain states can persist facilitated by peripheral sensitization of nociceptors. The voltage-gated sodium channel 1.9 (NaV1.9) is an important regulator of neuronal excitability and is involved in inflammation-induced pain hypersensitivity. Recently, oxidized 1-palmitoyl-2-arachidonoyl-sn-glycerol-3-phosphatidylcholine (OxPAPC) was identified as a mediator of acute inflammatory pain and persistent hyperalgesia, suggesting an involvement in proalgesic cascades and peripheral sensitization. Peripheral sensitization implies an increase in neuronal excitability. This thesis aims to characterize spontaneous calcium activity in neuronal compartments as a proxy to investigate neuronal excitability, making use of the computational tool Neural Activity Cubic (NA3). NA3 allows automated calcium activity event detection of signal-close-to-noise calcium activity and evaluation of neuronal activity states. Additionally, the influence of OxPAPC and NaV1.9 on the excitability of murine dorsal root ganglion (DRG) neurons and the effect of OxPAPC on the response of DRG neurons towards other inflammatory mediators (prostaglandin E2, histamine, and bradykinin) is investigated. Using calcium imaging, the presence of spontaneous calcium activity in murine DRG neurons was established. NA3 was used to quantify this spontaneous calcium activity, which revealed decreased activity counts in axons and somata of NaV1.9 knockout (KO) neurons compared to wildtype (WT). Incubation of WT DRG neurons with OxPAPC before calcium imaging did not show altered activity counts compared to controls. OxPAPC incubation also did not modify the response of DRG neurons treated with inflammatory mediators. However, the variance ratio computed by NA3 conclusively allowed to determine neuronal activity states. In conclusion, my findings indicate an important function of NaV1.9 in determining the neuronal excitability of DRG neurons in resting states. OxPAPC exposition does not influence neuronal excitability nor sensitizes neurons for other inflammatory mediators. This evidence reduces the primary mechanism of OxPAPC-induced hyperalgesia to acute effects. Importantly, it was possible to establish an approach for unbiased excitability quantification of DRG neurons by calcium activity event detection and calcium trace variance analysis by NA3. It was possible to show that signal-close-to-noise calcium activity reflects neuronal excitability states.
Der zur Familie der pentameren ligandengesteuerten Ionenkanäle zugehörige Glycinrezeptor (GlyR) ist ein wichtiger Vermittler synaptischer Inhibition im Zentralnervensystem von Säugetieren. GlyR-Mutationen führen zur neurologischen Bewegungsstörung Hyperekplexie. Aufgrund fehlender struktureller Daten ist die intrazelluläre Loop-Struktur zwischen den Transmembransegmenten 3 und 4 (TM3-4 Loop) eine weitgehend unerforschte Domäne des GlyR. Innerhalb dieser Domäne wurden Rezeptortrunkierungen sowie Punktmutationen identifiziert. Rezeptortrunkierung geht mit Funktionslosigkeit einher, welche jedoch durch Koexpression des fehlenden Sequenzabschnitts zum Teil wiederhergestellt werden kann. Innerhalb dieser Arbeit wurde die Interaktion zwischen trunkierten, funktionslosen GlyR und sukzessiv verkürzten Komplementationskonstrukten untersucht. Dabei wurden als Minimaldomänen für die Interaktion das C-terminalen basische Motive des TM3-4 Loops, die TM4 sowie der extrazelluläre C-Terminus identifiziert. Die Rückkreuzung transgener Mäuse, die das Komplementationskonstrukt iD-TM4 unter Kontrolle des GlyR-Promotors exprimierten, mit der oscillator-Maus spdot, die einen trunkierten GlyR exprimiert und 3 Wochen nach der Geburt verstirbt, hatte aufgrund fehlender Proteinexpression keinen Effekt auf die Letalität der Mutation. Des Weiteren wurde die Bedeutsamkeit der Integrität beider basischer Motive 316RFRRKRR322 und 385KKIDKISR392 im TM3-4 Loop in Kombination mit der Loop-Länge für die Funktionalität und das Desensitisierungsverhalten des humanen GlyRα1 anhand von chimären Rezeptoren identifiziert. Eine bisher unbekannte Patientenmutation P366L innerhalb des TM3-4 Loops wurde mit molekularbiologischen, biochemischen und elektrophysiologischen Methoden charakterisiert. Es wurde gezeigt, dass die mutierten Rezeptorkomplexe in vitro deutlich reduzierte Glycin-induzierte Maximalströme sowie eine beschleunigte Schließkinetik aufweisen. P366L hat im Gegensatz zu bereits charakterisierten Hyperekplexiemutationen innerhalb des TM3-4 Loops keinen Einfluss auf die Biogenese des Rezeptors. P366 ist Teil einer möglichen Poly-Prolin-Helix, die eine Erkennungssequenz für SH3-Domänen darstellt. Ein potenzieller Interaktionspartner des TM3-4 Loops des GlyRα1 ist Collybistin, welches eine wichtige Rolle bei der synaptischen Rezeptorintegration spielt und die Verbindung zum Zytoskelett vermittelt. An der inhibitorischen Synapse verursacht P366L durch die Reduzierung postsynaptischer Chloridströme, das beschleunigte Desensitisierungsverhalten des GlyRα1 sowie ein verändertes Interaktionsmotiv Störungen der glycinergen Transmission, die zur Ausprägung phänotypischer Symptome der Hyperekplexie führen.
Die proximale spinale Muskelatrophie (SMA) ist eine autosomal rezessive Erb-krankheit, welche durch fortschreitende Muskelatrophie mit Betonung der pro-ximalen Extremitäten, sowie zunehmende motorische Lähmungen charakterisiert wird. Bedingt wird diese neurodegenerative Erkrankung durch Mutation bzw. Deletion des SMN1-Gens auf Chromosom 5q13. Dies führt zu reduzierten Mengen des ubiquitär exprimierten SMN-Proteins, da der Verlust des SMN1-Gens nicht durch das noch verbleibende SMN2-Gen kompensiert werden kann. Die SMN-Promotor-Region enthält ein CRE II bindendes Element, welches Effekte von zyklischem Adenosinmonophosphat (cAMP) vermittelt und so die SMN-Transkription in untersuchten Zellen stimuliert. Ausgehend von diesem Befund stellte sich die Frage, ob cAMP dem Mangel an volllängen SMN bei der SMA entgegen wirkt. Daher wurden für diese Dissertation neurosphärenbildende kortikale Vorläuferzellen und primär kultivierte Motoneuronen von Smn+/+; SMN2- und Smn–/–;SMN2-Mausembryonen untersucht, um zu klären, ob die cAMP-Behandlung der Zellen zu einer Hochregulierung des SMN2-Transkripts führt, und durch die resultierende Erhöhung des SMN-Proteingehalts morphologische und funktionelle Defekte kompensiert werden. Die Untersuchung zeigte eine signifikante Zunahme des SMN2-Transkriptgehalts in Anwesenheit von cAMP. Dadurch kam es zu einem Anstieg der SMN-Proteinmenge im Soma, Axon und Wachstumskegel von Smn–/–;SMN2-Motoneuronen. Die Verteilungs-störung des SMN-Interaktionspartners hnRNP R mit fehlender kontrolltypischer Anreicherung im distalen Axon und Wachstumskegel von Smn–/–;SMN2-Motoneuronen wurde ebenfalls durch cAMP kompensiert. Smn-defiziente Mo-toneurone zeigten im Vergleich zu Kontrollzellen kleinere Wachstumskegel sowie ein Defizit an β-Aktin im distalen Axon. Zudem fehlte in Smn–/–;SMN2-Motoneuronen die bei Kontrollen ausgeprägte Zusammenlagerung von N-Typ spezifischen Ca2+-Kanälen in der Präsynapse, die nach Kontakt mit der β2-Kette des endplattenspezifischen Laminin-221 spontan öffnen und so einen in-trazellulären Kalziumanstieg bewirken, wodurch es zu Erregbarkeitsstörungen und Axonelongationsdefekten bei Smn-defizienten Motoneuronen kommt. Die Behandlung der Smn-defizienten Motoneuronen mit cAMP führte zur Vergrößerung der Wachstumskegelfläche und zu einer im Verlauf des Axons zunehmenden Anfärbung mit β-Aktin. Außerdem kam es zu einer Erhöhung der Menge an Cav2.2-Kanalprotein in den Wachstumskegeln Smn-defizienter Motoneurone, was mit einer erhöhten Erregbarkeit korrelierte und zu einer Normalisierung der Axonlänge von Smn–/–;SMN2-Motoneuronen auf Laminin-221 führte. Die Ergebnisse dieser Arbeit lassen die Vermutung zu, dass Smn-defiziente Motoneurone in vivo Defekte im präsynaptischen Bereich der Motorendplatte aufweisen. In Zukunft können mit dem beschriebenen in vitro Assay weitere Substanzen, welche die SMN2-Traskription stimulieren, auf ihr kompensatorisches Potential getestet werden.
Most RNAs within polarized cells such as neurons are sorted subcellularly in a coordinated manner. Despite advances in the development of methods for profiling polyadenylated RNAs from small amounts of input RNA, techniques for profiling coding and non-coding RNAs simultaneously are not well established. Here, we optimized a transcriptome profiling method based on double-random priming and applied it to serially diluted total RNA down to 10 pg. Read counts of expressed genes were robustly correlated between replicates, indicating that the method is both reproducible and scalable. Our transcriptome profiling method detected both coding and long non-coding RNAs sized >300 bases. Compared to total RNAseq using a conventional approach our protocol detected 70% more genes due to reduced capture of ribosomal RNAs. We used our method to analyze the RNA composition of compartmentalized motoneurons. The somatodendritic compartment was enriched for transcripts with post-synaptic functions as well as for certain nuclear non-coding RNAs such as 7SK. In axons, transcripts related to translation were enriched including the cytoplasmic non-coding RNA 7SL. Our profiling method can be applied to a wide range of investigations including perturbations of subcellular transcriptomes in neurodegenerative diseases and investigations of microdissected tissue samples such as anatomically defined fiber tracts.
Spinal muscular atrophy and amyotrophic lateral sclerosis are the two most common devastating motoneuron diseases. The mechanisms leading to motoneuron degeneration are not resolved so far, although different hypotheses have been built on existing data. One possible mechanism is disturbed axonal transport of RNAs in the affected motoneurons. The underlying question of this study was therefore to characterize changes in transcript levels of distinct RNAs in cell culture models of spinal muscular atrophy and amyotrophic lateral sclerosis, especially in the axonal compartment of primary motoneurons.
To investigate this in detail we first established compartmentalized cultures of Primary mouse motoneurons. Subsequently, total RNA of both compartments was extracted
separately and either linearly amplified and subjected to microarray profiling or whole transcriptome amplification followed by RNA-Sequencing was performed. To make
the whole transcriptome amplification method suitable for compartmentalized cultures, we adapted a double-random priming strategy. First, we applied this method
for initial optimization onto serial dilutions of spinal cord RNA and later on to the compartmentalized motoneurons.
Analysis of the data obtained from wildtype cultures already revealed interesting results. First, the RNA composition of axons turned out to be highly similar to the somatodendritic compartment. Second, axons seem to be particularly enriched for transcripts related to protein synthesis and energy production. In a next step we
repeated the experiments by using knockdown cultures. The proteins depleted hereby are Smn, Tdp-43 and hnRNP R. Another experiment was performed by knocking down the non-coding RNA 7SK, the main interacting RNA of hnRNP R.
Depletion of Smn led to a vast number of deregulated transcripts in the axonal and somatodendritic compartment. Transcripts downregulated in the axons upon Smn depletion were especially enriched for GOterms related to RNA processing and encode proteins located in neuron projections including axons and growth cones.
Strinkingly, among the upregulated transcripts in the somatodendritic compartment we mainly found MHC class I transcripts suggesting a potential neuroprotective role.
In contrast, although knockdown of Tdp-43 also revealed a large number of downregulated transcripts in the axonal compartment, these transcripts were mainly
associated with functions in transcriptional regulation and RNA splicing. For the hnRNP R knockdown our results were again different. Here, we observed
downregulated transcripts in the axonal compartment mainly associated with regulation of synaptic transmission and nerve impulses. Interestingly, a comparison between deregulated transcripts in the axonal compartment of both hnRNP R and 7SK knockdown presented a significant overlap of several transcripts suggesting
some common mechanism for both knockdowns.
Thus, our data indicate that a loss of disease-associated proteins involved in axonal RNA transport causes distinct transcriptome alterations in motor axons.
Die proximale spinale Muskelatrophie (SMA) stellt eine der häufigsten erblichen Ursachen für den Tod im Kindesalter dar. Die Patienten leiden unter symmetrischer, langsam progredienter Muskelschwäche und in schweren Fällen auch an sensiblen Ausfällen. Die neurodegenerative Erkrankung wird autosomal-rezessiv durch Deletion bzw. Mutationen des SMN1-Gens (survival motor neuron 1-Gens) auf Chromosom 5q13 vererbt. Das SMN-Protein wird ubiquitär exprimiert und findet sich in allen untersuchten Geweben in einem Multiproteinkomplex, dem sogenannten SMN-Komplex, der die Zusammenlagerung von spleißosomalen Komplexen koordiniert. Die Funktion solcher Komplexe ist für alle Zelltypen essentiell. Deshalb stellt sich die Frage, welcher Pathomechanismus für die Erkrankung SMA verantwortlich ist. Die vorliegende Arbeit zeigt, dass die Überlebensraten der Smn–/–;SMN2-Motoneurone 14 Tage alter Mausembryonen gegenüber Smn+/+;SMN2-Motoneuronen (Kontrollen) nicht reduziert waren. Bei der morphologischen Untersuchung der Zellen zum gleichen Entwicklungszeitpunkt zeigten sich jedoch deutliche Unterschiede. Die Axonlängen der Smn-defizienten Motoneurone waren gegenüber Kontrollen signifikant verringert. Das Dendritenwachstum war nicht beeinträchtigt. Die Untersuchung der Wachstumskegel ergab bei den Smn–/–;SMN2 Motoneuronen eine signifikante Verminderung der Fläche gegenüber Kontrollen. Weiterhin zeigten sich Defekte im Zytoskelett. In den Motoneuronen von Kontrolltieren fand sich eine Anreicherung von beta-Aktin in perinukleären Kompartimenten sowie besonders stark in den Wachstumskegeln. Die beta-Aktin-Anreicherung nahm im Verlauf des Axons zu. In Smn–/–;SMN2-Motoneuronen war keine Anreicherung im distalen Axon oder in den Wachstumskegeln detektierbar. Eine gleichartige Verteilungsstörung fand sich für das SMN-Interaktionsprotein hnRNP R (heterogenous nuclear ribonucleoprotein R) und, wie andere Arbeiten zeigen konnten, auch für die beta-Aktin-mRNA, die spezifisch an hnRNP R bindet. In gleicher Weise wurden auch Veränderungen in den sensorischen Neuronen aus den Hinterwurzelganglien 14 Tage alter Mausembryonen untersucht. Bei Smn–/–;SMN2-Mäusen war die Neuritenlänge sensorischer Neurone im Vergleich zur Kontrolle gering, jedoch signifikant verkürzt und die Fläche der Wachstumskegel hochsignifikant verringert. Im Smn–/–;SMN2 Mausmodell für eine schwere Form der SMA fanden sich in den sensorischen Nervenzellen im Vergleich zu den Motoneuronen geringer ausgeprägte, jedoch gleichartige Veränderungen, was auf einen ähnlichen Pathomechanismus in beiden Zelltypen hinweist.
Spinale Muskelatrophie (SMA), die häufigste autosomal rezessive neuromuskuläre Erkrankung bei Kindern und jungen Erwachsenen, wird durch Mutationen in der telomeren Kopie des survival motor neuron (SMN1) Gens auf dem humanen Chromosom 5 verursacht. Anders als bei Mäusen, welche nur ein Smn Gen haben, gibt es beim Menschen eine zweite Kopie (SMN2). Das Genprodukt dieser zweiten Kopie wird am C-Terminus bevorzugt alternativ gespleißt. Es bringt nur eine kleine Menge des vollständigen SMN Proteins hervor. Der Grund, warum eine reduzierte Menge des ubiquitär exprimierten SMN Proteins speziell zu einer Motorneuronendegeneration führt, ohne andere Zelltypen gleichermaßen zu betreffen ist noch immer nicht bekannt. Mit Hilfe der Yeast-Two-Hybrid Technik wurden die beiden heterogenen nukleären Ribonukleoproteine hnRNP-R und hnRNP-Q als neue SMN-bindende Proteine identifiziert. Diese beiden hochhomologen Proteine waren bereits bekannt und stehen in Verbindung mit dem RNA Metabolismus, im Speziellen: Editing, Transport und Spleißing. hnRNP-R und -Q interagieren mit Wildtyp Smn, aber nicht mit trunkierten oder mutierten Smn Formen, welche in SMA-Patienten gefunden wurden. Beide Proteine werden in den meisten Geweben exprimiert. Im Rückenmark von Mäusen ist die stärkste Expression am neunzehnten embryonalen Tag zu beobachten. Interessanterweise ist hnRNP-R hauptsächlich in den Axonen von Motoneuronen zu finden und kolokalisiert dort mit Smn. Im Mausmodell für die SMA konnte gezeigt werden, dass sich die Motoneurone von erkrankten Mäusen hinsichtlich der Morphologie ihrer Neuriten von solchen aus Wildtyp Mäusen unterscheiden. Werden hnRNP-R oder hnRNP-Q in kultivierten Nervenzellen exprimiert, so fördern sie das Wachstum von Neuriten. Bei SMA-Patienten ohne Mutation im SMN Gen konnte allerdings weder Mutation noch Deletion in hnRNP-R oder hnRNP-Q nachgewiesen werden. Die Ergebnisse dieser Arbeit können entscheidend zu einem besseren Verständnis der motoneuronen spezifischen Funktion von Smn bei der SMA beitragen.
Der Glycin-Rezeptor ist Teil der inhibitorischen liganden-gesteuerten Ionenkanäle im ZNS und wird am stärksten im adulten Rückenmark sowie im Hirnstamm exprimiert. In der Nerv-Muskel-Synapse sind GlyR für die rekurrente Hemmung der Motoneuronen wichtig und steuern das Gleichgewicht zwischen Erregung und Hemmung der Muskelzellen. Für die glycinerge Neurotransmission sind neben den präsynaptischen GlyR 𝛼1 insbesondere postsynaptische GlyR 𝛼1/𝛽 verantwortlich. Durch Mutationen des GlyR entsteht das Erkrankungsbild der Hyperekplexie mit übersteigerter Schreckhaftigkeit, Muskelsteifheit und Apnoe. Hauptursächlich dafür sind Mutationen im GLRA1-Gen. Die shaky Maus stellt ein gutes Modell zur Erforschung dieser seltenen Erkrankung dar.
Die shaky Missense-Mutation Q177K in der extrazellulären 𝛽8-𝛽9 Schleife der Glycin- Rezeptor-𝛼1-Untereinheit zeigte strukturell ein gestörtes Wasserstoffbrückennetzwerk. Funktionell konnten eingeschränkt leitfähige Ionenkanäle identifiziert werden. Der letale Phänotyp äußert sich beim homozygoten shaky Tier durch Schrecksymptome mit einem einhergehenden zunehmenden Gewichtsverlust. Die Quantifizierung der Oberflächenexpression deutete auf einen Verlust synaptischer GlyR 𝛼1/𝛽 hin. Aussagen bezüglich der GlyR-𝛽-Untereinheit, die Teil des synaptischen GlyR Komplexes ist, waren aufgrund fehlender stabiler Antikörper bisher nicht möglich. Das neuartige KI- Mausmodell Glrb eos exprimiert endogen fluoreszierende 𝛽 -Untereinheiten und ermöglicht damit erstmalig eine Betrachtung der GlyR- 𝛽-Expression in Tiermodellen der Startle Erkrankung.
Ziel dieser Arbeit war es, die Auswirkungen der shaky Mutation auf die Interaktion mit der 𝛽 -Untereinheit und Gephyrin zu erforschen. Dafür wurden Markerproteine der glycinergen Synapse in Rückenmarksneuronen der Kreuzung Glrb eos x Glra1 sh gefärbt und quantifiziert. Die durchgeführte Gewichtsbestimmung der Nachkommen im zeitlichen Verlauf zeigte keinen Einfluss der eingefügten mEos4b-Sequenz auf das Körpergewicht der Tiere und schließt damit funktionelle Einschränkungen bedingt durch die mEos4b-Sequenz aus. Zur Verstärkung des 𝛽 eos-Signals wurde ein Antikörper verwendet. Die Quantifizierung der GlyR- 𝛽- Untereinheit an Rückenmarksneuronen zeigte für homozygote shaky Tiere im Vergleich zum Wildtyp signifikant reduzierte 𝛽eos Oberflächenexpressionen in Gephyrin Clustern sowie signifikant erniedrigte Kolokalisationen von Gephyrin/𝛼1, 𝛽eos/𝛼1 und 𝛽eos/Gephyrin. Die mutierte GlyR-𝛼1- Untereinheit wurde hingegen vermehrt an der Oberfläche in shaky Tieren exprimiert. Die Ergebnisse der Rückenmarksschnitte unterstützen diese Befunde aus den Primärneuronen. Die Untersuchung der Präsynapse erbrachte für Glrb eos/eos x Glra1 sh/sh eine signifikant verminderte Synapsin und Synapsin/𝛼1 Expression.
Die Ergebnisse dieser Arbeit erweitern die Daten früherer Arbeiten zur shaky Maus und zeigen einen starken Verlust synaptischer GlyR 𝛼 1/ 𝛽 an der Oberfläche von Motoneuronen. Ein möglicher kompensatorischer Versuch durch erhöhte 𝛼1 Expression bleibt infolge der Funktionsbeeinträchtigung dieser mutierten GlyR- 𝛼 1 Rezeptoren erfolglos mit letalem Ausgang. In vorherigen Arbeiten wurde vermutet, dass die Mutation in der extrazellulären Bindungsstelle in der Lage ist, Konformationsänderungen in die TM3-TM4-Schleifenstruktur zu übertragen und dadurch die Gephyrin Bindung und synaptische Verankerung zu stören. Die Daten dieser Arbeit stützen diese Annahme und weisen darüber hinaus auf eine gestörte Rezeptorkomplexbindung hin. Die vorliegende Arbeit trägt somit zum besseren Verständnis der Startle Erkrankung auf synaptischer Ebene bei.
Motoneurons played an essential role in establishing the concept of target-mediated support of innervating neurons. However, it took several decades until molecules were identined which trophically support motoneurons in vitro and in vivo. The most potent molecule identined so far is ciliary neurotrophic factor (CNTF). It is expressed as a cytosolic molecule in myelinating Schwann cells rather than in skeletal muscle in the postnatal period and therefore does not qualify as a target-derived neurotrophic factor regulating motoneuron survival during embryonic development. However, the inactivation of CNTF by gene targeting experiments results in progressive atrophy and degeneration of motoneurons, demonstrating that CNTF plays an essential role as a maintenance factor for motoneurons postnatally. Secretory molecules which are expressed in skeletal muscle during embryonic development and which support motoneurons in culture and partially also in vivo include members of the NGF gene family (BDNF, NT-3, NT-4/S) , FGF-S, IGF-I, and UF. The evaluation of the physiological importance of these molecules is under investigation.
The transmission of proliferative and developmental signals from activated cell-surface receptors to initiation of cellular responses in the nucleus is synergically controlled by the coordinated action of a diverse set of intracellular signalling proteins. The Ras/Raf/MEK/MAPK signalling pathway has been shown to control the expression of genes which are crucial for the physiological regulation of cell proliferation, differentiation and apoptosis. Within this signalling cascade, the Raf protein family of serine/threonine kinases serves as a central intermediate which connects to many of other signal transduction pathways. To elucidate the signalling functions of the different Raf kinases in motoneurons during development, the expression, distribution and subcellular localization of Rafs in the spinal cord and the facial nucleus in brainstem of mice at various embryonic and postnatal stages were investigated. Moreover, we have investigated the intracellular redistribution of Raf molecules in isolated motoneurons from 13 or 14 day old mouse embryos, after addition or withdrawal of neurotrophic factors to induce Raf kinases activation in vitro. Furthermore, in order to investigate the potential anti-apoptotic function of Raf kinases on motoneurons, we isolated motoneurons from B-raf-/- and c-raf-1-/- mouse embryos and analysed the survival and differentiation effects of neurotrophic factors in motoneurons lacking B-Raf and c-Raf-1. We provide evidence here that all three Raf kinases are expressed in mouse spinal motoneurons. Their expression increases during the period of naturally occurring cell death of motoneurons. In sections of embryonic and postnatal spinal cord, motoneurons express exclusively B-Raf and c-Raf-1, but not A-Raf, and subcellularly Raf kinases are obviously colocalized with mitochondria. In isolated motoneurons, most of the B-Raf or c-Raf-1 immunoreactivity is located in the perinuclear space but also in the nucleus, especially after activation by addition of CNTF and BDNF in vitro. We found that c-Raf-1 translocation from the cytosol into the nucleus of motoneurons after its activation by neurotrophic factors is a distinct event. As a central finding of our study, we observed that the viability of isolated motoneurons from B-raf but not c-raf-1 knockout mice is lost even in the presence of CNTF and other neurotrophic factors. This indicates that B-Raf but not c-Raf-1, which is still present in B-raf deficient motoneurons, plays a crucial role in mediating the survival effect of neurotrophic factors during development. In order to prove that B-Raf is an essential player in this scenario, we have re-expressed B-Raf in mutant sensory and motor neurons by transfection. The motoneurons and the sensory neurons from B-raf knockout mouse which were transfected with exogenous B-raf gene revealed the same viability in the presence of neurotrophic factors as primary neurons from wild-type mice. Our results suggest that Raf kinases have important signalling functions in motoneurons in mouse CNS. In vitro, activation causes redistribution of Raf protein kinases, particularly for c-Raf-1, from motoneuronal cytoplasm into the nucleus. This redistribution of c-Raf-1, however, is not necessary for the survival effect of neurotrophic factors, given that B-raf-/- motor and sensory neurons can not survive despite the presence of c-Raf-1. We hypothesize that c-Raf-1 nuclear translocation may play a direct role in transcriptional regulation as a consequence of neurotrophic factor induced phosphorylation and activation of c-Raf-1 in motoneurons. Moreover, the identification of target genes for nuclear translocated c-Raf-1 and of specific cellular functions initiated by this mechanism awaits its characterization.
In mammals, a major fraction of the genome is transcribed as non-coding RNAs. An increasing amount of evidence has accumulated showing that non-coding RNAs play important roles both for normal cell function and in disease processes such as cancer or neurodegeneration. Interpreting the functions of non-coding RNAs and the molecular mechanisms through which they act is one of the most important challenges facing RNA biology today.
In my Ph.D. thesis, I have been investigating the role of 7SK, one of the most abundant non-coding RNAs, in the development and function of motoneurons. 7SK is a highly structured 331 nt RNA transcribed by RNA polymerase III. It forms four stem-loop (SL) structures that serve as binding sites for different proteins. Larp7 binds to SL4 and protects the 3' end from exonucleolytic degradation. SL1 serves as a binding site for HEXIM1, which recruits the pTEFb complex composed of CDK9 and cyclin T1. pTEFb has a stimulatory role for transcription and is regulated through sequestration by 7SK. More recently, a number of heterogeneous nuclear ribonucleoproteins (hnRNPs) have been identified as 7SK interactors. One of these is hnRNP R, which has been shown to have a role in motoneuron development by regulating axon growth. Taken together, 7SK’s function involves interactions with RNA binding proteins, and different RNA binding proteins interact with different regions of 7SK, such that 7SK can be considered as a hub for recruitment and release of different proteins. The questions I have addressed during my Ph.D. are as follows: 1) which region of 7SK interacts with hnRNP R, a main interactor of 7SK? 2) What effects occur in motoneurons after the protein binding sites of 7SK are abolished? 3) Are there additional 7SK binding proteins that regulate the functions of the 7SK RNP?
Using in vitro and in vivo experiments, I found that hnRNP R binds both the SL1 and SL3 region of 7SK, and also that pTEFb cannot be recruited after deleting the SL1 region but is able to bind to a 7SK mutant with deletion of SL3. In order to answer the question of how the 7SK mutations affect axon outgrowth and elongation in mouse primary motoneurons, we proceeded to conduct rescue experiments in motoneurons by using lentiviral vectors. The constructs were designed to express 7SK deletion mutants under the mouse U6 promoter and at the same time to drive expression of a 7SK shRNA from an H1 promoter for the depletion of endogenous 7SK. Using this system we found that 7SK mutants harboring deletions of either SL1 or SL3 could not rescue the axon growth defect of 7SK-depleted motoneurons suggesting that 7SK/hnRNP R complexes are integral for this process.
In order to identify novel 7SK binding proteins and investigate their functions, I proceeded to conduct pull-down experiments by using a biotinylated RNA antisense oligonucleotide that targets the U17-C33 region of 7SK thereby purifying endogenous 7SK complexes. Following mass spectrometry of purified 7SK complexes, we identified a number of novel 7SK interactors. Among these is the Smn complex. Deficiency of the Smn complex causes the motoneuron disease spinal muscular atrophy (SMA) characterized by loss of lower motoneurons in the spinal cord. Smn has previously been shown to interact with hnRNP R. Accordingly, we found Smn as part of 7SK/hnRNP R complexes. These proteomics data suggest that 7SK potentially plays important roles in different signaling pathways in addition to transcription.
The P429L loss of function mutation of the human glycine transporter 2 associated with hyperekplexia
(2019)
Glycine transporter 2 (GlyT2) mutations across the entire sequence have been shown to represent the presynaptic component of the neurological disease hyperekplexia. Dominant, recessive and compound heterozygous mutations have been identified, most of them leading to impaired glycine uptake. Here, we identified a novel loss of function mutation of the GlyT2 resulting from an amino acid exchange of proline 429 to leucine in a family with both parents being heterozygous carriers. A homozygous child suffered from severe neuromotor deficits. We characterised the GlyT2P429L variant at the molecular, cellular and protein level. Functionality was determined by glycine uptake assays. Homology modelling revealed that the mutation localises to α‐helix 5, presumably disrupting the integrity of this α‐helix. GlyT2P429L shows protein trafficking through various intracellular compartments to the cellular surface. However, the protein expression at the whole cell level was significantly reduced. Although present at the cellular surface, GlyT2P429L demonstrated a loss of protein function. Coexpression of the mutant with the wild‐type protein, reflecting the situation in the parents, did not affect transporter function, thus explaining their non‐symptomatic phenotype. Nevertheless, when the mutant was expressed in excess compared with the wild‐type protein, glycine uptake was significantly reduced. Thus, these data demonstrate that the proline residue at position 429 is structurally important for the correct formation of α‐helix 5. The failure in functionality of the mutated GlyT2 is most probably due to structural changes localised in close proximity to the sodium‐binding site of the transporter.
The family of Cys-loop receptors (CLRs) shares a high degree of homology and sequence identity. The overall structural elements are highly conserved with a large extracellular domain (ECD) harboring an α-helix and 10 β-sheets. Following the ECD, four transmembrane domains (TMD) are connected by intracellular and extracellular loop structures. Except the TM3–4 loop, their length comprises 7–14 residues. The TM3–4 loop forms the largest part of the intracellular domain (ICD) and exhibits the most variable region between all CLRs. The ICD is defined by the TM3–4 loop together with the TM1–2 loop preceding the ion channel pore. During the last decade, crystallization approaches were successful for some members of the CLR family. To allow crystallization, the intracellular loop was in most structures replaced by a short linker present in prokaryotic CLRs. Therefore, no structural information about the large TM3–4 loop of CLRs including the glycine receptors (GlyRs) is available except for some basic stretches close to TM3 and TM4. The intracellular loop has been intensively studied with regard to functional aspects including desensitization, modulation of channel physiology by pharmacological substances, posttranslational modifications, and motifs important for trafficking. Furthermore, the ICD interacts with scaffold proteins enabling inhibitory synapse formation. This review focuses on attempts to define structural and functional elements within the ICD of GlyRs discussed with the background of protein-protein interactions and functional channel formation in the absence of the TM3–4 loop.
The cDNA for ciliary neurotrophic factor (CNTF), a polypeptide involved in the survival of motoneurons in mammals, has recently been cloned (Stöckli et al., Nature, 342, 920 - 923, 1989; Lin et al. Science, 246, 1023 - 1025, 1989). We have now localized the corresponding gene Cntf to chromosome 19 in the mouse, using an interspecific cross between Mus spretus and Mus musculus domesticus. The latter was carrying the gene wobbler (wr) for spinal muscular atrophy. DNA was prepared from backcross individuals and typed for the segregation of species-specific Cntf restriction fragments in relation to DNA markers of known chromosomal location. The M.spretus allele of Cntf cosegregated with chromosome 19 markers and mapped closely to Ly-1, to a region of mouse chromosome 19 with conserved synteny to human chromosome 11q. Cntf is not linked to wr, and the expression of CNTF mRNA and protein appears close to normal in facial and sciatic nerves, of affected (wr/wr) mice, suggesting that motoneuron degeneration of wobbler mice has its origin in defects other than reduced CNTF expression.
Ciliary neurotrophic factor (CNTF) is expressed in high quantities in Schwann cells of peripheral nerves during postnatal development of the rat. The absence of a hydrophobic leader sequence and the immunohistochemical localization of CNTF within the cytoplasm of these cells indicate that the factor might not be available to responsive neurons under physiological conditions. However, CNTF supports the survival of a variety of embryonic neurons, including spinal motoneurons in culture. Moreover we have recently demonstrated that the exogenous application of CNTF protein to the lesioned facial nerve of the newborn rat rescued these motoneurons from cell death. These results indicate that CNTF might indeed play a major role in assisting the survival of lesioned neurons in the adult peripheral nervous system. Here we demonstrate that the CNTF mRNA and protein levels and the manner in which they are regulated are compatible with such a function in lesioned peripheral neurons. In particular, immunohistochemical analysis showed significant quantities of CNTF at extracellular sites after sciatic nerve lesion. Western blots and determination of CNTF biological activity of the same nerve segments indicate that extracellular CNTF seems to be biologically active. After nerve lesion CNTF mRNA levels were reduced to <5 % in distal regions of the sciatic nerve whereas CNTF bioactivity decreased to only one third of the original before-lesion levels. A gradual reincrease in Schwann cells occurred concomitant with regeneration.
Synaptopathies: synaptic dysfunction in neurological disorders - a review from students to students
(2016)
Synapses are essential components of neurons and allow information to travel coordinately throughout the nervous system to adjust behavior to environmental stimuli and to control body functions, memories, and emotions. Thus, optimal synaptic communication is required for proper brain physiology, and slight perturbations of synapse function can lead to brain disorders. In fact, increasing evidence has demonstrated the relevance of synapse dysfunction as a major determinant of many neurological diseases. This notion has led to the concept of synaptopathies as brain diseases with synapse defects as shared pathogenic features. In this review, which was initiated at the 13th International Society for Neurochemistry Advanced School, we discuss basic concepts of synapse structure and function, and provide a critical view of how aberrant synapse physiology may contribute to neurodevelopmental disorders (autism, Down syndrome, startle disease, and epilepsy) as well as neurodegenerative disorders (Alzheimer and Parkinson disease). We finally discuss the appropriateness and potential implications of gathering synapse diseases under a single term. Understanding common causes and intrinsic differences in disease-associated synaptic dysfunction could offer novel clues toward synapse-based therapeutic intervention for neurological and neuropsychiatric disorders. In this Review, which was initiated at the 13th International Society for Neurochemistry (ISN) Advanced School, we discuss basic concepts of synapse structure and function, and provide a critical view of how aberrant synapse physiology may contribute to neurodevelopmental (autism, Down syndrome, startle disease, and epilepsy) as well as neurodegenerative disorders (Alzheimer's and Parkinson's diseases), gathered together under the term of synaptopathies. Read the Editorial Highlight for this article on page .
Learning and memory is considered to require synaptic plasticity at presynaptic specializations of neurons. Kenyon cells are the intrinsic neurons of the primary olfactory learning center in the brain of arthropods – the mushroom body neuropils. An olfactory mushroom body memory trace is supposed to be located at the presynapses of Kenyon cells. In the calyx, a sub-compartment of the mushroom bodies, Kenyon cell dendrites receive olfactory input provided via projection neurons. Their output synapses, however, were thought to reside exclusively along their axonal projections outside the calyx, in the mushroom body lobes. By means of high-resolution imaging and with novel transgenic tools, we showed that the calyx of the fruit fly Drosophila melanogaster also comprised Kenyon cell presynapses. At these presynapses, synaptic vesicles were present, which were capable of neurotransmitter release upon stimulation. In addition, the newly identified Kenyon cell presynapses shared similarities with most other presynapses: their active zones, the sites of vesicle fusion, contained the proteins Bruchpilot and Syd-1. These proteins are part of the cytomatrix at the active zone, a scaffold controlling synaptic vesicle endo- and exocytosis. Kenyon cell presynapses were present in γ- and α/β-type KCs but not in α/β-type Kenyon cells.
The newly identified Kenyon cell derived presynapses in the calyx are candidate sites for an olfactory associative memory trace. We hypothesize that, as in mammals, recurrent neuronal activity might operate for memory retrieval in the fly olfactory system.
Moreover, we present evidence for structural synaptic plasticity in the mushroom body calyx. This is the first demonstration of synaptic plasticity in the central nervous system of Drosophila melanogaster. The volume of the mushroom body calyx can change according to changes in the environment. Also size and numbers of microglomeruli - sub-structures of the calyx, at which projection neurons contact Kenyon cells – can change. We investigated the synapses within the microglomeruli in detail by using new transgenic tools for visualizing presynaptic active zones and postsynaptic densities. Here, we could show, by disruption of the projection neuron - Kenyon cell circuit, that synapses of microglomeruli were subject to activity-dependent synaptic plasticity. Projection neurons that could not generate action potentials compensated their functional limitation by increasing the number of active zones per microglomerulus. Moreover, they built more and enlarged microglomeruli. Our data provide clear evidence for an activity-induced, structural synaptic plasticity as well as for the activity-induced reorganization of the olfactory circuitry in the mushroom body calyx.
Synapsin is an evolutionarily conserved presynaptic phosphoprotein. It is encoded by only one gene in the Drosophila genome and is expressed throughout the nervous system. It regulates the balance between reserve and releasable vesicles, is required to maintain transmission upon heavy demand, and is essential for proper memory function at the behavioral level. Task-relevant sensorimotor functions, however, remain intact in the absence of Synapsin. Using an odor-sugar reward associative learning paradigm in larval Drosophila, we show that memory scores in mutants lacking Synapsin (syn\(^{97}\)) are lower than in wild-type animals only when more salient, higher concentrations of odor or of the sugar reward are used. Furthermore, we show that Synapsin is selectively required for larval short-term memory. Thus, without Synapsin Drosophila larvae can learn and remember, but Synapsin is required to form memories that match in strength to event salience-in particular to a high saliency of odors, of rewards, or the salient recency of an event. We further show that the residual memory scores upon a lack of Synapsin are not further decreased by an additional lack of the Sap47 protein. In combination with mass spectrometry data showing an up-regulated phosphorylation of Synapsin in the larval nervous system upon a lack of Sap47, this is suggestive of a functional interdependence of Synapsin and Sap47.
Structural and functional modifications of synaptic connections (“synaptic plasticity”) are believed to mediate learning and memory processes. Thus, molecular mechanisms of how synapses assemble in both structural and functional terms are relevant for our understanding of neuronal development as well as the processes of learning and memory. Synapses form by an asymmetric association of highly specialized membrane domains: at the presynaptic active zone transmitter filled vesicles fuse, while transmitter receptors at the opposite postsynaptic density sense this signal. By genetic analysis, matrix proteins of active zones from various families have been shown to be important for fast vesicle fusion, and were suggested to contribute to synapse stability and assembly. The Sigrist lab in collaboration with the Buchner lab previously had shown that the large scaffold protein Bruchpilot (Brp) is essential for both the structural and functional integrity of active zones and for synaptic plasticity in Drosophila melanogaster. The work described in this thesis investigated several candidate proteins which appear to be involved in preand postsynaptic function, as summarized in the following: (1) DREP-2 (DEF45 related protein-2) had been found by co-immunoprecipitations with anti-Brp antibodies by Dr. Manuela Schmidt (unpublished data). Mutants and antibodies for the further study of DREP- 2 were generated in this thesis. Yeast two hybrid results suggest that DREP-2 might interact with dynein light chain 2, while in vivo imaging indicates that DREP-2 might be involved in bidirectional axonal transport. (2) Coimmunoprecipitation and pull down experiments suggested that the ARFGAP [ADP-ribosylation factor (ARF)-directed GTPase activating protein (GAP)] protein GIT (G-protein coupled receptor kinase interacting protein) could interact with the endocytosis associated molecule Stoned B (StnB). Mutants in the dgit gene showed an accumulation of large size vesicles, membrane intermediates and decreased vesicle density at the 3rd instar larval neuromuscular junction (NMJ) by electron microscopy (EM). The phenotypes accumulation of large size vesicles and membrane intermediates could be rescued partially by expression of Drosophila GIT (DGIT) or human GIT in dgit mutant background. Furthermore, by immunofluorescence the dgit mutant shows specifically decreased levels of StnB, which could be restored partially by the expression of DGIT. These results strongly support the suggestion that DGIT interacts with StnB, which is involved in the regulation of vesicle size, endocytosis or recycling of synaptic vesicles (SVs). Furthermore, the dgit mutants also showed signs of a mislocalization of the presynaptic protein Brp relative to the postsynaptic protein GluRIID, which could be rescued by expression of DGIT or human GIT in the dgit mutant background, but not by StnB. These results suggest that GIT on one hand executes roles in the regulation of synaptic vesicle endocytosis, but potentially also has structural roles for synapse assembly (3) Djm-1 is a candidate locus to mediate mental retardation in human patients when it is mutated. As a first step towards an understanding of the mechanistic role of DJM-1, Drosophila genetics were used to address DJM-1 function. So far, however, the djm-1 mutant generated in this thesis did not show a nervous system phenotype.
3D cell cultures allow a better mimicry of the biological and mechanical environment of cells in vivo compared to 2D cultures. However, 3D cell cultures have been challenging for ultrasoft tissues such as the brain. The present study uses a microfiber reinforcement approach combining mouse primary spinal cord neurons in Matrigel with melt electrowritten (MEW) frames. Within these 3D constructs, neuronal network development is followed for 21 days in vitro. To evaluate neuronal development in 3D constructs, the maturation of inhibitory glycinergic synapses is analyzed using protein expression, the complex mechanical properties by assessing nonlinearity, conditioning, and stress relaxation, and calcium imaging as readouts. Following adaptation to the 3D matrix-frame, mature inhibitory synapse formation is faster than in 2D demonstrated by a steep increase in glycine receptor expression between days 3 and 10. The 3D expression pattern of marker proteins at the inhibitory synapse and the mechanical properties resemble the situation in native spinal cord tissue. Moreover, 3D spinal cord neuronal networks exhibit intensive neuronal activity after 14 days in culture. The spinal cord cell culture model using ultrasoft matrix reinforced by MEW fibers provides a promising tool to study and understand biomechanical mechanisms in health and disease.
Survival motor neuron (SMN) is an essential and ubiquitously expressed protein that participates in several aspects of RNA metabolism. SMN deficiency causes a devastating motor neuron disease called spinal muscular atrophy (SMA). SMN forms the core of a protein complex localized at the cytoplasm and nuclear gems and that catalyzes spliceosomal snRNP particle synthesis. In cultured motor neurons, SMN is also present in dendrites and axons, and forms part of the ribonucleoprotein transport granules implicated in mRNA trafficking and local translation. Nevertheless, the distribution, regulation, and role of SMN at the axons and presynaptic motor terminals in vivo are still unclear. By using conventional confocal microscopy and STED super-resolution nanoscopy, we found that SMN appears in the form of granules distributed along motor axons at nerve terminals. Our fluorescence in situ hybridization and electron microscopy studies also confirmed the presence of β-actin mRNA, ribosomes, and polysomes in the presynaptic motor terminal, key elements of the protein synthesis machinery involved in local translation in this compartment. SMN granules co-localize with the microtubule-associated protein 1B (MAP1B) and neurofilaments, suggesting that the cytoskeleton participates in transporting and positioning the granules. We also found that, while SMN granules are physiologically downregulated at the presynaptic element during the period of postnatal maturation in wild-type (non-transgenic) mice, they accumulate in areas of neurofilament aggregation in SMA mice, suggesting that the high expression of SMN at the NMJ, together with the cytoskeletal defects, contribute to impairing the bi-directional traffic of proteins and organelles between the axon and the presynaptic terminal.
Neuste Studien haben ergeben, dass Asc-1 Knock-out Mäuse aufgrund einer verminderten intrazellulären Glycinkonzentration in synaptischen Boutons im Gehirn, einen Hyperekplexie-ähnlichen Phänotyp entwickeln. Aufgrund nicht vollständig geklärter Ursachen für die Entstehung des Krankheitsbildes der Hyperekplexie beim Menschen, wurde eine Kohorte von 51 Patienten zusammengetragen, um vor dem Hintergrund der Forschungsergebnisse zu Asc-1 im Tiermodell, das kodierende Gen beim Menschen SLC7A10 als mögliches Kandidatengen auf Sequenzalterationen zu untersuchen. Hierfür wurde aus Vollblut der an Hyperekplexie erkrankten Patienten genomische DNA isoliert, um mittels PCR und anschließendem Screening der Sequenzen, Mutationen innerhalb funktionell wichtiger Bereiche des Gens zu eruieren. Neben weiteren Sequenzunterschieden, die meist in Introns gefunden wurden, wurde die codierende Mutation G307R innerhalb von Exon 7 identifiziert, die letztendlich der Grund für eine Versuchsreihe war, um zu hinterfragen, ob dieser Aminosäureaustausch in der Proteinsequenz funktionelle Konsequenzen zur Folge hat. HEK293-Zellen wurden mit dem zuvor hergestellten Klon G307R transfiziert, um über Biotinylierung, immuncytochemische Färbungen und funktionelle Untersuchungen die Aktivität des Transporters zu beurteilen. Hier zeigte sich ein Funktionsverlust von über 95 %, bei uneingeschränkter Oberflächenexpression. ASC-1 bestätigt sich damit als neue Ursache in der Ausprägung von Hyperekplexie. Ferner können Zusammenhänge mit geistiger Retardierung und eingeschränkter neuronaler Plastizität bestehen.
Naturally occurring compounds such as sesquiterpenes and sesquiterpenoids (SQTs) have been shown to modulate GABA\(_{A}\) receptors (GABA\(_{A}\)Rs). In this study, the modulatory potential of 11 SQTs at GABA\(_{A}\)Rs was analyzed to characterize their potential neurotropic activity. Transfected HEK293 cells and primary hippocampal neurons were functionally investigated using electrophysiological whole-cell recordings. Significantly different effects of β-caryophyllene and α-humulene, as well as their respective derivatives β-caryolanol and humulol, were observed in the HEK293 cell system. In neurons, the concomitant presence of phasic and tonic GABA\(_{A}\)R configurations accounts for differences in receptor modulation by SQTs. The in vivo presence of the γ\(_{2}\) and δ subunits is important for SQT modulation. While phasic GABA\(_{A}\) receptors in hippocampal neurons exhibited significantly altered GABA-evoked current amplitudes in the presence of humulol and guaiol, negative allosteric potential at recombinantly expressed α\(_{1}\)β\(_{2}\)γ\(_{2}\) receptors was only verified for humolol. Modeling and docking studies provided support for the binding of SQTs to the neurosteroid-binding site of the GABA\(_{A}\)R localized between transmembrane segments 1 and 3 at the (\(^{+}\)α)-(\(^{-}\)α) interface. In sum, differences in the modulation of GABA\(_{A}\)R isoforms between SQTs were identified. Another finding is that our results provide an indication that nutritional digestion affects the neurotropic potential of natural compounds.
Diabetic polyneuropathy (DPN) is the most common complication in diabetes and can be painful in up to 26% of all diabetic patients. Peripheral nerves are shielded by the blood-nerve barrier (BNB) consisting of the perineurium and endoneurial vessels. So far, there are conflicting results regarding the role and function of the BNB in the pathophysiology of DPN. In this study, we analyzed the spatiotemporal tight junction protein profile, barrier permeability, and vessel-associated macrophages in Wistar rats with streptozotocin-induced DPN. In these rats, mechanical hypersensitivity developed after 2 weeks and loss of motor function after 8 weeks, while the BNB and the blood-DRG barrier were leakier for small, but not for large molecules after 8 weeks only. The blood-spinal cord barrier remained sealed throughout the observation period. No gross changes in tight junction protein or cytokine expression were observed in all barriers to blood. However, expression of Cldn1 mRNA in perineurium was specifically downregulated in conjunction with weaker vessel-associated macrophage shielding of the BNB. Our results underline the role of specific tight junction proteins and BNB breakdown in DPN maintenance and differentiate DPN from traumatic nerve injury. Targeting claudins and sealing the BNB could stabilize pain and prevent further nerve damage.
Neurotrophic factor signaling modulates differentiation, axon growth and maintenance, synaptic plasticity and regeneration of neurons after injury. Ciliary neurotrophic factor (CNTF), a Schwann cell derived neurotrophic factor, has an exclusive role in axon maintenance, sprouting and synaptic preservation. CNTF, but not GDNF, has been shown to alleviate motoneuron degeneration in pmn mutant mice carrying a missense mutation in Tbce gene, a model for Amyotrophic Lateral Sclerosis (ALS). This current study elucidates the distinct signaling mechanism by which CNTF rescues the axonal degeneration in pmn mutant mice. ...
Dopaminergic neurons in the brain of the Drosophila larva play a key role in mediating reward information to the mushroom bodies during appetitive olfactory learning and memory. Using optogenetic activation of Kenyon cells we provide evidence that recurrent signaling exists between Kenyon cells and dopaminergic neurons of the primary protocerebral anterior (pPAM) cluster. Optogenetic activation of Kenyon cells paired with odor stimulation is sufficient to induce appetitive memory. Simultaneous impairment of the dopaminergic pPAM neurons abolishes appetitive memory expression. Thus, we argue that dopaminergic pPAM neurons mediate reward information to the Kenyon cells, and in turn receive feedback from Kenyon cells. We further show that this feedback signaling is dependent on short neuropeptide F, but not on acetylcholine known to be important for odor-shock memories in adult flies. Our data suggest that recurrent signaling routes within the larval mushroom body circuitry may represent a mechanism subserving memory stabilization.
Animal models point towards a key role of brain-derived neurotrophic factor (BDNF), insulin-like growth factor-I (IGF-I) and vascular endothelial growth factor (VEGF) in mediating exercise-induced structural and functional changes in the hippocampus. Recently, also platelet derived growth factor-C (PDGF-C) has been shown to promote blood vessel growth and neuronal survival. Moreover, reductions of these neurotrophic and angiogenic factors in old age have been related to hippocampal atrophy, decreased vascularization and cognitive decline. In a 3-month aerobic exercise study, forty healthy older humans (60 to 77 years) were pseudo-randomly assigned to either an aerobic exercise group (indoor treadmill, n = 21) or to a control group (indoor progressive-muscle relaxation/stretching, n = 19). As reported recently, we found evidence for fitness-related perfusion changes of the aged human hippocampus that were closely linked to changes in episodic memory function. Here, we test whether peripheral levels of BDNF, IGF-I, VEGF or PDGF-C are related to changes in hippocampal blood flow, volume and memory performance. Growth factor levels were not significantly affected by exercise, and their changes were not related to changes in fitness or perfusion. However, changes in IGF-I levels were positively correlated with hippocampal volume changes (derived by manual volumetry and voxel-based morphometry) and late verbal recall performance, a relationship that seemed to be independent of fitness, perfusion or their changes over time. These preliminary findings link IGF-I levels to hippocampal volume changes and putatively hippocampus-dependent memory changes that seem to occur over time independently of exercise. We discuss methodological shortcomings of our study and potential differences in the temporal dynamics of how IGF-1, VEGF and BDNF may be affected by exercise and to what extent these differences may have led to the negative findings reported here.
3D neuronal cultures attempt to better replicate the in vivo environment to study neurological/neurodegenerative diseases compared to 2D models. A challenge to establish 3D neuron culture models is the low elastic modulus (30–500 Pa) of the native brain. Here, an ultra-soft matrix based on thiolated hyaluronic acid (HA-SH) reinforced with a microfiber frame is formulated and used. Hyaluronic acid represents an essential component of the brain extracellular matrix (ECM). Box-shaped frames with a microfiber spacing of 200 µm composed of 10-layers of poly(ɛ-caprolactone) (PCL) microfibers (9.7 ± 0.2 µm) made via melt electrowriting (MEW) are used to reinforce the HA-SH matrix which has an elastic modulus of 95 Pa. The neuronal viability is low in pure HA-SH matrix, however, when astrocytes are pre-seeded below this reinforced construct, they significantly support neuronal survival, network formation quantified by neurite length, and neuronal firing shown by Ca\(^{2+}\) imaging. The astrocyte-seeded HA-SH matrix is able to match the neuronal viability to the level of Matrigel, a gold standard matrix for neuronal culture for over two decades. Thus, this 3D MEW frame reinforced HA-SH composite with neurons and astrocytes constitutes a reliable and reproducible system to further study brain diseases.
Neurotrophin signaling via receptor tyrosine kinases is essential for the development and function of the nervous system in vertebrates. TrkB activation and signaling show substantial differences to other receptor tyrosine kinases of the Trk family that mediate the responses to nerve growth factor and neurotrophin-3. Growing evidence suggests that TrkB cell surface expression is highly regulated and determines the sensitivity of neurons to brain-derived neurotrophic factor (BDNF). This translocation of TrkB depends on co-factors and modulators of cAMP levels, N-glycosylation, and receptor transactivation. This process can occur in very short time periods and the resulting rapid modulation of target cell sensitivity to BDNF could represent a mechanism for fine-tuning of synaptic plasticity and communication in complex neuronal networks. This review focuses on those modulatory mechanisms in neurons that regulate responsiveness to BDNF via control of TrkB surface expression.
Ciliary neurotrophic factor (CNTF) is a potent survival molecule for a variety of embryonic neurons in culture. The developmental expression of CNTF occurs clearly after the time period of the physiological cell death of CNTF-responsive neurons. This, together with the sites of expression, excludes CNTF as a target-derived neuronal survival factor, at least in rodents. However, CNTF also participates in the induction of type 2 astrocyte differentiation in vitro. Here we demonstrate that the time course of the expression of CNTF-mRNA and protein in the rat optic nerve (as evaluated by quantitative Northern blot analysis and biological activity, respectively) is compatible with such a glial differentiation function of CNTF in vivo. We also show that the type 2 astrocyte-inducing- activity previously demonstrated in optic nerve extract can be precipitated by an antiserum against CNTF. Immunohistochemical analysis of astrocytes in vitro and in vivo demonstrates that the expression of CNTF is confined to a subpopulation of type 1 astrocytes. The olfactory bulb of adult rats has comparably high levels of CNTF to the optic nerve, and here again, CNTF-immunoreactivity is localized in a subpopulation of astrocytes. However, the postnatal expression of CNTF in the olfactory bulb occurs later than in the optic nerve. In other brain regions both CNTF-mRNA and protein levels are much lower.
The nervous system is shielded by special barriers. Nerve injury results in blood–nerve barrier breakdown with downregulation of certain tight junction proteins accompanying the painful neuropathic phenotype. The dorsal root ganglion (DRG) consists of a neuron-rich region (NRR, somata of somatosensory and nociceptive neurons) and a fibre-rich region (FRR), and their putative epi-/perineurium (EPN). Here, we analysed blood–DRG barrier (BDB) properties in these physiologically distinct regions in Wistar rats after chronic constriction injury (CCI). Cldn5, Cldn12, and Tjp1 (rats) mRNA were downregulated 1 week after traumatic nerve injury. Claudin-1 immunoreactivity (IR) found in the EPN, claudin-19-IR in the FRR, and ZO-1-IR in FRR-EPN were unaltered after CCI. However, laser-assisted, vessel specific qPCR, and IR studies confirmed a significant loss of claudin-5 in the NRR. The NRR was three-times more permeable compared to the FRR for high and low molecular weight markers. NRR permeability was not further increased 1-week after CCI, but significantly more CD68\(^+\) macrophages had migrated into the NRR. In summary, NRR and FRR are different in naïve rats. Short-term traumatic nerve injury leaves the already highly permeable BDB in the NRR unaltered for small and large molecules. Claudin-5 is downregulated in the NRR. This could facilitate macrophage invasion, and thereby neuronal sensitisation and hyperalgesia. Targeting the stabilisation of claudin-5 in microvessels and the BDB barrier could be a future approach for neuropathic pain therapy.
The structure of the rat ciliary neurotrophic factor (CNTF) gene and the regulation ofCNTF mRNA levels in cultured glial cells were investigated. The rat mRNA is encoded by a simple two-exon transcription unit. Sequence analysis of the region upstream of the transcription start-site did not reveal a typical TATA-box consensus sequence. Low levels of CNTF mRNA were detected in cultured Schwann cells, and CNTF mRNA was not increased by a variety of treatments. Three-week-old astrocyteenriched cell cultures from new-born rat brain contained easily detectable CNTF mRNA. In astrocyte-enriched cultures, upregulation of CNTF mRNA levels was observed after treatment with IFN-gamma. CNTF mRNA levels were down-regulated in these cells by treatments that elevate intracellular cyclic AMP and by members of the fibroblast growth factor (FGF) family. The implications of these results for potential in vivo functions of CNTF are discussed.
Although evidence obtained with the PC12 cell line has suggested a role for the ras oncogene proteins in the signal transduction of nerve growth factor-mediated fiber outgrowth, little is known about the signal transduction mechanisms involved in the neuronal response to neurotrophic factors in nontransformed cells. We report here that the oncogene protein T24-ras, when introduced into the cytoplasm of freshly dissociated chick embryonic neurons, promotes the in vitro survival and neurite outgrowth of nerve growth factor-responsive dorsal rootganglion neurons, brain-derived neurotrophic factor-responsive nodose ganglion neurons, and ciliary neuronotrophic factor-responsive ciliary ganglion neurons. The proto-oncogene product c-Ha-ras also promotes neuronal survival, albeit less strongly. No effect could be observed with truncated counterparts of T24-ras and c-Ha-ras lacking the 23 C-terminal amino acids including the membrane-an-choring, palmityl-accepting cysteine. These results sug-gest a generalized involvement of ras or ras-like proteins in the intracellular signal transduction pathway for neurotrophic factors.
At early developmental stages (embryonic day 7, E7), chick paravertebral sympathetic ganglia contain a cell population that divides in culture while expressing various neuronal properties. In an attempt to identify factors that control neuronal proliferation, we found that ciliary neurotrophic factor (CNTF) specifically inhibits the proliferation of those cells expressing neuronal markers. In addition, CNTF affects the differentiation of sympathetic ganglion cells by inducing the expression of vasoactive intestinal peptide immunoreactivity (VIP-IR). After 1 day in culture, tyrosine hydroxylase immunoreactivity (TH-I R) was expressed by about 86% of the cells whereas VIP-IR was virtually absent. In the presence of CNTF, 50%-60% of the cells expressed VIP-IR after 4 days in culture; however, none of the cells expressed VIP-IR in the absence of CNTF. These results, and the demonstration of cells that express both VIP and TH-IR, indicate that VIP is induced in cells that initially express tyrosine hydroxylase. The findings suggest a potential role for CNTF as a factor affecting the proliferation and differentiation of developing sympathetic neurons.
Spinal muscular atrophy (SMA) is caused by deficiency of the ubiquitously expressed survival motoneuron (SMN) protein. SMN is crucial component of a complex for the assembly of spliceosomal small nuclear ribonucleoprotein (snRNP) particles. Other cellular functions of SMN are less characterized so far. SMA predominantly affects lower motoneurons, but the cellular basis for this relative specificity is still unknown. In contrast to nonneuronal cells where the protein is mainly localized in perinuclear regions and the nucleus, Smn is also present in dendrites, axons and axonal growth cones of isolated motoneurons in vitro. However, this distribution has not been shown in vivo and it is not clear whether Smn and hnRNP R are also present in presynaptic axon terminals of motoneurons in postnatal mice. Smn also associates with components not included in the classical SMN complex like RNA-binding proteins FUS, TDP43, HuD and hnRNP R which are involved in RNA processing, subcellular localization and translation. We show here that Smn and hnRNP R are present in presynaptic compartments at neuromuscular endplates of embryonic and postnatal mice. Smn and hnRNP R are localized in close proximity to each other in axons and axon terminals both in vitro and in vivo. We also provide new evidence for a direct interaction of Smn and hnRNP R in vitro and in vivo, particularly in the cytosol of motoneurons. These data point to functions of SMN beyond snRNP assembly which could be crucial for recruitment and transport of RNA particles into axons and axon terminals, a mechanism which may contribute to SMA pathogenesis.
Autophagy-mediated degradation of synaptic components maintains synaptic homeostasis but also constitutes a mechanism of neurodegeneration. It is unclear how autophagy of synaptic vesicles and components of presynaptic active zones is regulated. Here, we show that Pleckstrin homology containing family member 5 (Plekhg5) modulates autophagy of synaptic vesicles in axon terminals of motoneurons via its function as a guanine exchange factor for Rab26, a small GTPase that specifically directs synaptic vesicles to preautophagosomal structures. Plekhg5 gene inactivation in mice results in a late-onset motoneuron disease, characterized by degeneration of axon terminals. Plekhg5-depleted cultured motoneurons show defective axon growth and impaired autophagy of synaptic vesicles, which can be rescued by constitutively active Rab26. These findings define a mechanism for regulating autophagy in neurons that specifically targets synaptic vesicles. Disruption of this mechanism may contribute to the pathophysiology of several forms of motoneuron disease.
The progressive motor neuropathy (PMN) mouse is a model of an inherited motor neuropathy disease with progressive neurodegeneration. Axon degeneration associates with homozygous mutations of the TBCE gene encoding the tubulin chaperone E protein. TBCE is responsible for the correct dimerization of alpha and beta-tubulin. Strikingly, the PMN mouse also develops a progressive hearing loss after normal hearing onset, characterized by degeneration of the auditory nerve and outer hair cell (OHC) loss. However, the development of this neuronal and cochlear pathology is not fully understood yet. Previous studies with pegylated insulin-like growth factor 1 (peg-IGF-1) treatment in this mouse model have been shown to expand lifespan, weight, muscle strength, and motor coordination. Accordingly, peg-IGF-1 was evaluated for an otoprotective effect. We investigated the effect of peg-IGF-1 on the auditory system by treatment starting at postnatal day 15 (p15). Histological analysis revealed positive effects on OHC synapses of medial olivocochlear (MOC) neuronal fibers and a short-term attenuation of OHC loss. Peg-IGF-1 was able to conditionally restore the disorganization of OHC synapses and maintain the provision of cholinergic acetyltransferase in presynapses. To assess auditory function, frequency-specific auditory brainstem responses and distortion product otoacoustic emissions were recorded in animals on p21 and p28. However, despite the positive effect on MOC fibers and OHC, no restoration of hearing could be achieved. The present work demonstrates that the synaptic pathology of efferent MOC fibers in PMN mice represents a particular form of “efferent auditory neuropathy.” Peg-IGF-1 showed an otoprotective effect by preventing the degeneration of OHCs and efferent synapses. However, enhanced efforts are needed to optimize the treatment to obtain detectable improvements in hearing performances.
Aktuell herrscht in der Wissenschaft Unklarheit über die pathologischen Prozesse, die durch Caspr2-aAK ausgelöst werden. Dissens herrscht, ob es durch die aAK im Serum oder im Liquor zu einer Internalisierung von an der Zellmembran exprimierten Caspr2 kommt. Ebenso ist nicht abschließend geklärt, inwieweit die Struktur des VGKC durch die aAK-Bindung verändert wird.
Mit der vorliegenden Arbeit wurden Untersuchungen zum Pathomechanismus von Caspr2-aAK vorgenommen, indem die Oberflächenexpression von Caspr2 in DRGs im Langzeitversuch näher untersucht wurde. Dafür wurden zunächst die Caspr2-aAK in den Patientenseren mithilfe immunzytochemischer Färbungen in vitro sowohl in transfizierten HEK293, als auch in adulten DRGs nachgewiesen. Zusätzlich wurde mit der Membranpräparation von Caspr2 transfizierten HEK293-Zellen die Caspr2 Bindung mittels proteinbiochemischen Nachweises verifiziert.
Es wurde zudem eine Subklassenbestimmung an den 9 vorliegenden Patientenseren und einer Probe mit aufgereinigtem IgG durchgeführt. Die dominante Subklasse war IgG4 was mit dem wissenschaftlichen Forschungsstand kongruiert, dass IgG4 bei Caspr2-aAK der dominierende Subtyp ist.
Im Langzeitversuch zur Untersuchung einer möglichen Internalisierung von Caspr2 durch die Inkubation in Caspr2-aAK positiven Seren wurden in vitro kultivierte DRGs adulter Mäuse für 24h, 48h, bzw. 96 h mit den Seren konfrontiert. Zusätzlich wurde überprüft wie sich ein Rescue der Zellen – nach 48 h wurde das Caspr2-aAK positive Serum gegen ein Caspr2-negatives Serum für weitere 48 h ausgetauscht – auf die Oberflächenexpression auswirkt. Zur Überprüfung der Dichte des an der Zellmembran exprimierten Caspr2 Proteins wurde diese abschließend quantifiziert und statistisch ausgewertet. Zusammenfassend ließ sich bei keinem der untersuchten Seren eine signifikante Veränderung der Caspr2 Oberflächenexpression erkennen.
Mit diesen Ergebnissen konnte gezeigt werden, dass eine vorübergehende Erniedrigung/Erhöhung der Caspr2 Expression nach Inkubation mit aAK durch primäre DRG Neurone kompensiert wird und eine erhöhte Internalisierung nicht als ursächlich für den Pathomechanismus der Caspr2-aAK in Frage kommt.
Within the lipidome oxidized phospholipids (OxPL) form a class of chemically highly reactive metabolites. OxPL are acutely produced in inflamed tissue and act as endogenous, proalgesic (pain-inducing) metabolites. They excite sensory, nociceptive neurons by activating transient receptor potential ion channels, specifically TRPA1 and TRPV1. Under inflammatory conditions, OxPL-mediated receptor potentials even potentiate the action potential firing rate of nociceptors. Targeting OxPL with D-4F, an apolipoprotein A-I mimetic peptide or antibodies like E06, specifically binding oxidized headgroups of phospholipids, can be used to control acute, inflammatory pain syndromes, at least in rodents. With a focus on proalgesic specificities of OxPL, this article discusses, how targeting defined substances of the epilipidome can contribute to mechanism-based therapies against primary and secondary chronic inflammatory or possibly also neuropathic pain.
Non-steroidal antiinflammatory drugs are most commonly used for inflammatory and postoperative pain. But they lack effectiveness and specificity, leading to severe side effects, like gastric ulcers, asthma and severe bleeding. Oxidized 1-palmitoyl-2-arachinidonoyl-sn-glycero-3-phosphocholine (OxPAPC) plays an important role in inflammatory pain. PAPC is a common phosphatidylcholine of membranes, which can be oxidized by reactive oxygen species. In preliminary experiments, our group found that local injection of OxPAPC in rat paws induces hyperalgesia.
In this study we examined the effect of OxPAPC on transient receptor potential A1 (TRPA1), an ion channel expressed in C-fiber neurons. Furthermore, we investigated if intracellular cysteine residues of TRPA1 were necessary for agonist-channel-interactions and if a subsequent TRPA1 activation could be prevented by OxPAPC scavengers.
To answer these questions, we performed calcium imaging using HEK-293 cells stably expressing hTRPA1, or transiently expressing the triple mutant channel hTRPA1-3C and naïve DRG neurons. Cells were incubated with the ratiometric, fluorescent dye Fura-2/AM and stimulated with OxPAPC. The change of light emission after excitation with 340 and 380 nm wavelengths allowed conclusions regarding changes of intracellular calcium concentrations after TRPA1 activation.
In our investigation we proved evidence that OxPAPC activates TRPA1, which caused a flow of calcium ions into the cytoplasm. The TRPA1-specific channel blocker HC-030031 eliminated this agonist-induced response. TRPA1-3C was not completely sensitive to OxPAPC. The peptide D-4F and the monoclonal antibody E06 neutralized OxPAPC-induced TRPA1 activation.
In this work, the importance of OxPAPC as a key mediator of inflammatory pain and as a promising target for drug design is highlighted. Our results indicate that TRPA1 activation by OxPAPC involves cysteine-dependent mechanisms, but there are other, cysteine-independent activation mechanisms as well. Potential pharmaceuticals for the treatment of inflammatory pain are D-4F and E06, whose efficiency has recently been confirmed in the animal model by our research group.
The amyotrophic lateral sclerosis (ALS) neurodegenerative disorder has been associated with multiple genetic lesions, including mutations in the gene for fused in sarcoma (FUS), a nuclear-localized RNA/DNA-binding protein. Neuronal expression of the pathological form of FUS proteins in Caenorhabditis elegans results in mislocalization and aggregation of FUS in the cytoplasm, and leads to impairment of motility. However, the mechanisms by which the mutant FUS disrupts neuronal health and function remain unclear. Here we investigated the impact of ALS-associated FUS on motor neuron health using correlative light and electron microscopy, electron tomography, and electrophysiology. We show that ectopic expression of wild-type or ALS-associated human FUS impairs synaptic vesicle docking at neuromuscular junctions. ALS-associated FUS led to the emergence of a population of large, electron-dense, and filament-filled endosomes. Electrophysiological recording revealed reduced transmission from motor neurons to muscles. Together, these results suggest a pathological effect of ALS-causing FUS at synaptic structure and function organization.
Startle disease is a rare disorder associated with mutations in GLRA1 and GLRB, encoding glycine receptor (GlyR) α1 and β subunits, which enable fast synaptic inhibitory transmission in the spinal cord and brainstem. The GlyR β subunit is important for synaptic localization via interactions with gephyrin and contributes to agonist binding and ion channel conductance. Here, we have studied three GLRB missense mutations, Y252S, S321F, and A455P, identified in startle disease patients. For Y252S in M1 a disrupted stacking interaction with surrounding aromatic residues in M3 and M4 is suggested which is accompanied by an increased EC\(_{50}\) value. By contrast, S321F in M3 might stabilize stacking interactions with aromatic residues in M1 and M4. No significant differences in glycine potency or efficacy were observed for S321F. The A455P variant was not predicted to impact on subunit folding but surprisingly displayed increased maximal currents which were not accompanied by enhanced surface expression, suggesting that A455P is a gain-of-function mutation. All three GlyR β variants are trafficked effectively with the α1 subunit through intracellular compartments and inserted into the cellular membrane. In vivo, the GlyR β subunit is transported together with α1 and the scaffolding protein gephyrin to synaptic sites. The interaction of these proteins was studied using eGFP-gephyrin, forming cytosolic aggregates in non-neuronal cells. eGFP-gephyrin and β subunit co-expression resulted in the recruitment of both wild-type and mutant GlyR β subunits to gephyrin aggregates. However, a significantly lower number of GlyR β aggregates was observed for Y252S, while for mutants S321F and A455P, the area and the perimeter of GlyR β subunit aggregates was increased in comparison to wild-type β. Transfection of hippocampal neurons confirmed differences in GlyR-gephyrin clustering with Y252S and A455P, leading to a significant reduction in GlyR β-positive synapses. Although none of the mutations studied is directly located within the gephyrin-binding motif in the GlyR β M3-M4 loop, we suggest that structural changes within the GlyR β subunit result in differences in GlyR β-gephyrin interactions. Hence, we conclude that loss- or gain-of-function, or alterations in synaptic GlyR clustering may underlie disease pathology in startle disease patients carrying GLRB mutations.
Introduction
The neuronal ceroid lipofuscinoses constitute a group of fatal inherited lysosomal storage diseases that manifest in profound neurodegeneration in the CNS. Visual impairment usually is an early symptom and selective degeneration of retinal neurons has been described in patients suffering from distinct disease subtypes. We have previously demonstrated that palmitoyl protein thioesterase 1 deficient (Ppt1-/-) mice, a model of the infantile disease subtype, exhibit progressive axonal degeneration in the optic nerve and loss of retinal ganglion cells, faithfully reflecting disease severity in the CNS. Here we performed spectral domain optical coherence tomography (OCT) in Ppt1-/- and ceroid lipofuscinosis neuronal 3 deficient (Cln3-/-) mice, which are models of infantile and juvenile neuronal ceroid lipofuscinosis, respectively, in order to establish a non-invasive method to assess retinal alterations and monitor disease severity in vivo.
Results
Blue laser autofluorescence imaging revealed increased accumulation of autofluorescent storage material in the inner retinae of 7-month-old Ppt1-/- and of 16-month-old Cln3-/- mice in comparison with age-matched control littermates. Additionally, optical coherence tomography demonstrated reduced thickness of retinae in knockout mice in comparison with age-matched control littermates. High resolution scans and manual measurements allowed for separation of different retinal composite layers and revealed a thinning of layers in the inner retinae of both mouse models at distinct ages. OCT measurements correlated well with subsequent histological analysis of the same retinae.
Conclusions
These results demonstrate the feasibility of OCT to assess neurodegenerative disease severity in mouse models of neuronal ceroid lipofuscinosis and might have important implications for diagnostic evaluation of disease progression and therapeutic efficacy in patients. Moreover, the non-invasive method allows for longitudinal studies in experimental models, reducing the number of animals used for research.
In spinal muscular atrophy (SMA), mutations in or loss of the Survival Motor Neuron 1 (SMN1) gene reduce full-length SMN protein levels, which leads to the degeneration of a percentage of motor neurons. In mouse models of SMA, the development and maintenance of spinal motor neurons and the neuromuscular junction (NMJ) function are altered. Since nifedipine is known to be neuroprotective and increases neurotransmission in nerve terminals, we investigated its effects on cultured spinal cord motor neurons and motor nerve terminals of control and SMA mice. We found that application of nifedipine increased the frequency of spontaneous Ca\(^{2+}\) transients, growth cone size, cluster-like formations of Cav2.2 channels, and it normalized axon extension in SMA neurons in culture. At the NMJ, nifedipine significantly increased evoked and spontaneous release at low-frequency stimulation in both genotypes. High-strength stimulation revealed that nifedipine increased the size of the readily releasable pool (RRP) of vesicles in control but not SMA mice. These findings provide experimental evidence about the ability of nifedipine to prevent the appearance of developmental defects in SMA embryonic motor neurons in culture and reveal to which extent nifedipine could still increase neurotransmission at the NMJ in SMA mice under different functional demands.
Motoneuron diseases represent a m&jor challenge to modern neurology, yet their clinical manifestations ware first described more than hundred years ago, and despite many studies the etiology of these diseases ramd,ns obscure with no effective treatments having been reported. Although progress has been made in establishing genetic linkage in the rare inherited for.ms of these diseases such as familial amyotrophic lateral scleriosisl , spinal mDscular atrophy and X-linked bulbo-spinal-mDscular atrophy, this new information has not yet affected therapeutic techniques. During the last few years several important steps have been taken concerning the physiological mechanisms involved in motoneuron survival during development, after lesion and in animal models of degenerative diseases, the molecular clOning of several new neurotrophic factors (brain-derived neurotrophic factor (BDNP), neurotrophin-3 and-4 (NT-3 and NT-4) and ciliary neurotrophic factor (CNTP)); the identification of a gene family of receptor molecules for same of these factors, progress in the understanding of the effects of polypeptide growth factors on muscle cell differentiation, neuronal sprouting (insulin-like growth factor-I and -11 (IGF-I and IGF-II), and in vitro motoneuronal survival (CNTF, IGF-I and -II and basic FGF). These findings have raised new hopes in that they could lead to a better understanding of the pathophysiological processes underlying these diseases, and that the pharmacological use of same of these newly characterized neurotrophic factors could present new possibilities for the treatment of these diseases.