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Taubheit stellt eine starke Beeinträchtigung im Leben Betroffener dar und geht einher mit funktionellen und morphologischen Veränderungen der Hörbahn. Im Tierversuch mit der mongolischen Wüstenrennmaus wurden in der vorliegenden Studie die Auswirkungen von frühzeitiger bilateraler Ertaubung auf den lateralen oberen Olivenkern (LSO) untersucht.
Die LSO spielt als erste binaurale Schaltstelle der zentralen Hörbahn eine tragende Rolle im Richtungshören, indem sie die Intensitätsunterschiede beidseits eintreffender Schallsignale auf der Basis des Gleichgewichts von exzitatorischem und inhibitorischem Input ermittelt. In dieser Studie wurde die LSO von 10 normalhörenden und 12 frühzeitig ertaubten mongolischen Wüstenrennmäusen in der Nissl-Färbung und den immunhistologischen Färbungen mit GABA und Glycin lichtmikroskopisch untersucht. Die Querschnittsfläche des Kerngebiets und die Zellzahlen in allen drei Färbungen sowie die Zellgrößen und Zelldichte in der Nissl-Färbung wurden analysiert. Zudem erfolgte die Überprüfung des Kerngebiets auf einen tonotopen Gradienten sowie auf Hemisphärenunterschiede.
Es zeigte sich die ertaubungsbedinge Schrumpfung des Kerngebiets der LSO sowie die Abnahme der Zellgrößen. Die Zellschrumpfung war unabhängig vom tonotopen Gradienten nachzuweisen. Zellzahlen und Zelldichte wiesen weitgehend keine Veränderungen auf. Eine deutliche Tendenz hemisphärenspezifischer Unterschiede konnte nicht dargestellt werden.
Diese ertaubungsbedingten strukturellen Veränderungen der LSO zeigen sich auch im Vergleich zu altersbedingten morphologischen Auswirkungen stärker ausgeprägt und könnten die Funktionsfähigkeit der Neurone und damit das Richtungshören beeinträchtigen. Diese Studie leistet einen Beitrag zur genaueren Beleuchtung der morphologischen Veränderungen der zentralen Hörbahn bei frühzeitiger bilateraler Ertaubung und gibt Anreiz für weitere elektrophysiologische Studien.
Vorherige Studien beschreiben bei der Aufmerksamkeitslenkung präfrontale Aktivierungen im rechten DLPFC und DMPFC. Diese Studie wollte untersuchen, ob die Aufmerksamkeitslenkung durch Richten des Fokus auf nicht -emotionale Bildinhalte innerhalb eines Stimulus zu präfrontalen Effekten führt. Dazu wurde eine kombinierte Messung aus EEG, fNIRS und emotionalem Arousal erhoben. Die Bedingungen beinhalteten entweder das passive Bildbetrachten oder die Aufmerksamkeitslenkung. Das EEG wurde als Kontrollbedingung erhoben, um zu replizieren, dass die Aufmerksamkeitslenkung auf nicht –emotionale Bildinhalte zu einer Reduktion des LPP und des emotionalen Arousals führt. In dieser Studie konnte sowohl ein reduziertes LPP als ein geringeres emotionales Arousal bei der Aufmerksamkeitslenkung beschrieben werden. In der fNIRS zeigten sich jedoch weder ein signifikanter Emotions- noch ein signifikanter Regulationseffekt, sodass keine Aktivierungen präfrontal bei der Aufmerksamkeitslenkung beschrieben werden konnte. Es sind somit weiterführende Studien zur Aufmerksamkeitslenkung notwendig, ob die Aufmerksamkeitslenkung zu präfrontalen Aktivierungen führt, und ob diese mit der fNIRS abgebildet werden können.
Abstract
Background: Attention-deficit/ hyperactivity disorder (ADHD) ranges among the most common neurodevelopmental disorders worldwide with a prevalence of 3-12% in childhood and 1-5% for adults. Over the last decade extensive genetic research has been conducted in order to determine its causative genetic factors. None of the so far identified susceptibility genes, however, could explain the estimated ADHD heritability of 76%. In this thesis one of the most promising candidates -Cadherin 13 (Cdh13) - was examined in terms of its influence on the central serotonergic (5-HT) system. In addition to that, the Cdh13 protein distribution pattern was analysed over time.
Methods: The developing serotonergic system was compared over three embryonic and postnatal stages (E13.5, E17.5 and P7) in different Cdh13 genotypes (WT, HZ and KO) using immunohistochemistry and various double staining protocols.
Results: The raphe nuclei of the 5-HT system develop in spite of Cdh13 absence and show a comparable mature constellation. The cells in the KO, however, are slightly more scattered than in the WT. Furthermore the dynamics of their formation is altered, with a transient delay in migration at E13.5. In early developmental stages the total amount of serotonergic cells is reduced in KO and HZ, though their proportional distribution to the raphe nuclei stays constant. Strikingly, at P7 the absolute numbers are comparable again.
Concerning the Cdh13 protein, it shows high concentrations on fibres running through hindbrain and midbrain areas at E13.5. This, however, changes over time, and it becomes more evenly spread until P7. Furthermore, its presence in serotonergic cells could be visualised using confocal microscopy. Since the described pattern is only in parts congruent to the localisation of serotonergic neurons, it is most likely that Cdh13 is present in other developing neurotransmitter systems, such as the dopaminergic one, as well.
Conclusion: It could be proven that Cdh13 is expressed in serotonergic cells and that its knockout does affect the developing serotonergic system to some degree. Its absence, however, only slightly and transiently affects the measured parameters of serotonergic system development, indicating a possible compensation of CDH13 function by other molecules in the case of Cdh13 deficiency. In addition further indicators could be found for an influence of Cdh13 on outgrowth and path finding of neuronal processes.
Recently, our research group identified in a study novel proalgesic targets in acute and chronic inflammatory pain: oxidized phospholipids (OxPL). OxPL, endogenous chemical irritants, are generated in inflamed tissue and mediate their pain-inducing function by activating the transient receptor potential channels TRPA1 and TRPV1. Both channels are sensors for chemical stimuli on primary afferent nociceptors and are involved in nociception. Here, with the help of calcium imaging and whole cell patch clamp recording techniques, it was found that OxPL metabolites acutely activate TRPA1 and TRPV1 ion channels to excite DRG neurons. OxPL species act predominantly via TRPA1 ion channels and mediate long- lasting non-selective inward currents. Notably, one pure OxPL compound, PGPC, activated a TRPA1 mutant lacking the binding site for electrophilic agonists, suggesting that OxPL activate TRP ion channels by an indirect mechanical mechanism. Next, it was investigated how OxPL influence the excitability of primary sensory neurons. Acute stimulation and fast calcium imaging revealed that OxPL elicit repetitive, spike-like calcium transients in small- diameter DRG neurons, which were fully blocked by antagonists against TRPA1/V1 and N- type voltage-gated calcium channels.
In search of a mechanism that drives repetitive spiking of DRG neurons, it was asked whether NaV1.9, a voltage-gated sodium channel involved in subthreshold excitability and nociception, is needed to trigger OxPL-induced calcium spikes and action potential firing. In electrophysiological recordings, both the combination of local application of OxPL and current injection were required to efficiently increase the action potential (AP) frequency of small-diameter sensory neurons. However, no difference was monitored in the resting membrane potential or OxPL-induced AP firing rate between wt and NaV1.9-deficient small diameter DRG neurons. To see whether NaV1.9 needs inflammatory conditions to be integrated in the OxPL-induced excitation cascade, sensory neurons were pretreated with a mixture of inflammatory mediators before OxPL application. Under inflammatory conditions both the AP and the calcium-spike frequency were drastically enhanced in response to an acute OxPL stimulus. Notably, this potentiation of OxPL stimuli was entirely lost in NaV1.9 deficient sensory neurons. Under inflammatory conditions, the resting membrane potential of NaV1.9-deficient neurons was more negative compared to wt neurons, suggesting that NaV1.9 shows resting activity only under inflammatory conditions.
In conclusion, OxPL are endogenous irritants that induce excitability in small-diameter DRG
neurons, a cellular model of nociceptors, via TRP activation. This effect is potentiated under inflammatory conditions. Under these conditions, NaV1.9 functions as essential mediator as it eases the initiation of excitability after OxPL stimulation.
As mutants in the human NaV1.9 mediate an enhanced or painless perception, this study provides new insight into the mechanism on how NaV1.9 amplifies stimuli of endogenous irritants under inflammatory conditions.
Fabry disease (FD) is an X-linked lysosomal storage disorder with intracellular accumulation of globotriaosylceramide (Gb3) due to α-galactosidase A deficiency. We studied α-galactosidase A knockout mice (GLA KO) as a model for sensory disturbance and pain in FD.
Pain associated behavior of young (3 months) and old (≥18 months) GLA KO mice and wildtype (WT) littermates in an inflammatory and a neuropathic pain model was investigated. Furthermore, affective and cognitive behavior was assessed in the naïve state and in an inflammatory pain model. Gene and protein expression of pain associated ion channels and Gb3 accumulation in dorsal root ganglion (DRG) neurons was determined. We also performed patch clamp analysis on cultivated DRG neurons and human embryonic kidney 293 (HEK) cells expressing voltage-gated-sodium channel 1.7 (Nav1.7) as an in vitro model of FD. Intracellular Gb3 deposits were modulated using shRNA silencing of α-galactosidase A.
After intraplantar injection of complete Freund`s adjuvant (CFA) and chronic constriction injury (CCI) of the right sciatic nerve, old GLA KO mice did not develop heat and mechanical hypersensitivity in contrast to young GLA KO and old WT mice. Additionally, we found no relevant differences between genotypes and age-groups in affective and cognitive behavior in the naïve state and after CFA injection. Gene and protein expression analysis provided no explanation for the observed sensory impairment. However, cultured DRG neurons of old GLA KO mice revealed a marked decrease of sodium and Ih-currents compared to young GLA KO and old WT mice. DRG neurons of old GLA KO mice displayed substantial intracellular accumulation of Gb3 compared to young GLA KO and old WT mice. Similar to cultured neurons, sodium currents were also decreased in HEK cells treated with shRNA and consecutively increased intracellular Gb3 deposits compared to the control condition, but could be rescued by treatment with agalsidase-alpha.
Our study unveils that, similar to patients with FD, GLA KO mice display age-dependent sensory deficits. However, contrary to patients, GLA KO mice are also protected from hypersensitivity induced by inflammation and nerve lesion due to Gb3-dependent and reversible reduction of neuronal sodium- and Ih-currents. Our data provide evidence for direct Gb3-dependent ion channel impairment in sensory DRG neurons as a potential contributor to sensory dysfunction and pain in FD.
Cadherin-13 (CDH13) is an atypical member of the cadherin superfamily, a group of membrane proteins mediating calcium-dependent cellular adhesion. Although CDH13 shows the classical extracellular cadherin structure, the typical transmembrane and cytoplasmic domains are absent. Instead, CDH13 is attached to the cell membrane via a glycosylphosphatidylinositol (GPI) anchor. These findings and many studies from different fields suggest that CDH13 also plays a role as a cellular receptor. Interestingly, many genome-wide association studies (GWAS) have found CDH13 as a risk gene for attention-deficit/hyperactivity disorder (ADHD) and other neurodevelopmental disorders. In previous work from our research group, strong expression of Cdh13 mRNA in interneurons of the hippocampal stratum oriens (SO) was detected. Therefore, double-immunofluorescence studies were used to evaluate the degree of co-expression of CDH13 with seven markers of GABAergic interneuron subtypes. For this purpose, murine brains were double stained against CDH13 and the respective marker and the degree of colocalization in the SO of the hippocampus was assessed. Based on the result of this immunofluorescence study, quantitative differences in interneuron subtypes of the SO between Cdh13 knockout (ko), heterozygote (het) and wildtype (wt) mice were investigated in this dissertation using stereological methods. In addition, genotype- dependent differences in the expression of genes involved in GABAergic and glutamatergic neurotransmission were analyzed by quantitative real-time PCR (qRT-PCR). Primers targeting different GABA receptor subunits, vesicular GABA and glutamate transporter, GABA synthesizing enzymes and their interaction partners were used for this purpose.
The results of the stereological quantification of the interneuron subtypes show no significant differences in cell number, cell density or volume of the SO between Cdh13 ko, het and wt mice. On the other hand, qRT-PCR results indicate significant differences in the expression of tropomyosin-related kinase B gene (TrkB), which encodes the receptor of brain-derived neurotrophic factor (BDNF), a regulator of GABAergic neurons. This finding supports a role for CDH13 in the regulation of BDNF signaling in the hippocampus.
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.