Refine
Has Fulltext
- yes (34)
Is part of the Bibliography
- yes (34)
Year of publication
Document Type
- Journal article (29)
- Doctoral Thesis (5)
Language
- English (34) (remove)
Keywords
- ADHD (7)
- mice (5)
- prefrontal cortex (3)
- psychiatric disorders (3)
- serotonin (3)
- CDH13 (2)
- Cadherine (2)
- Genetics (2)
- Hypothalamus (2)
- Maus (2)
- SLC2A3 (2)
- Serotonin (2)
- T-cadherin (2)
- adulthood (2)
- anxiety (2)
- attention-deficit/hyperactivity disorder (ADHD) (2)
- chronic stress (2)
- hippocampus (2)
- neurodevelopment (2)
- neurodevelopmental disorders (2)
- pro-inflammatory cytokines (2)
- serotonergic system (2)
- 3-dimensional MRI (1)
- 5-HT receptors (1)
- 5-HTT (1)
- 5-HTTLPR polymorphism (1)
- ADGRL3 (1)
- ADHS (1)
- Adult (1)
- Aggression (1)
- Antisocial behavior (1)
- Association (1)
- C57BL/6 mice (1)
- CB1 receptor antagonists (1)
- COMT (1)
- CO\(_{2}\) exposure (1)
- Cadherin 13 (1)
- Cadherin-13 (1)
- Central nervous system (1)
- Conduct disorder (1)
- DNA (1)
- DRD4 (1)
- Deficit/hyperactivity disorder (1)
- Diagnostic approach (1)
- Dopamine (1)
- Epigenetik (1)
- Fgf-signalling (1)
- GABAerge Nervenzelle (1)
- GLUT3 (1)
- GWAS (1)
- Gene (1)
- Hippocampus (1)
- Human Transcriptome (1)
- Illumina Human Exome Bead Chip (1)
- Large multicenter ADHD (1)
- Molecular biology (1)
- Mouse Model (1)
- NMDA receptor subunits NR2A and NR2B (1)
- NPY (1)
- Neurodevelopment (1)
- Neuroscience (1)
- OXTR (1)
- Psychiatric disorders (1)
- Raphe Kerne (1)
- Rating scale (1)
- SARS-CoV-2 (1)
- SSRI (1)
- Serotonerge Nervenzelle (1)
- Susceptibility loci (1)
- TrkB (1)
- Tropomyosin receptor kinase B (1)
- Xenopus laevis oocytes (1)
- Zebrabärbling (1)
- aging (1)
- allostatic load (1)
- amino acid analysis (1)
- amygdala (1)
- anhedonia (1)
- animal behavior (1)
- antioxidant nutrients (1)
- anxiety-like behavior (1)
- association (1)
- attention (1)
- attention deficit/hyperactivity disorder (1)
- blood flow (1)
- cadherin-13 (CDH13) (1)
- celecoxib (1)
- cell membranes (1)
- childhood maltreatment (1)
- chip analyses (1)
- chronic social stress (1)
- citalopram (1)
- collagens (1)
- comparative genomics (1)
- copy number variation (1)
- cross-species comparison (1)
- crystal structure (1)
- dangerous world (1)
- deficit hyperactivity disorder (1)
- depression (1)
- developmental plasticity (1)
- dicholine succinate (1)
- dorsal raphe (1)
- electroencephalogram (EEG) (1)
- elevated plus-maze (1)
- emotion (1)
- energy metabolism (1)
- environment interaction (1)
- environmental enrichment (1)
- events (1)
- false belief (1)
- fear conditioning (1)
- fear response (1)
- female aggression (1)
- fgf (1)
- forced swimming (1)
- genetic variants (1)
- genome-wide association (1)
- glucose (1)
- glucose transporter (1)
- glycogen synthase kinase-3 β (GSK-3β) (1)
- hippocampal neurogenesis (1)
- hippocampal plasticity (1)
- humans (1)
- hyperactivity (1)
- impulsivity (1)
- induced pluripotent stem cells (1)
- inducible cyclooxygenase-2 (COX-2) (1)
- inflammation (1)
- insulin receptor (1)
- insulin receptor (IR) (1)
- integrins (1)
- ischemic stroke (1)
- knockout mice (1)
- lactosylceramide alpha-2,3-sialyltransferase (ST3GAL5) (1)
- lerned helplessness (1)
- life history (1)
- life stress (1)
- linked polymorphic region (1)
- long-term potentiation (1)
- major depression (1)
- match-mismatch (1)
- maternal care (1)
- membrane potential (1)
- membrane proteins (1)
- metaanalysis (1)
- moderation (1)
- molecular medicine (1)
- molecular neuroscience (1)
- mouse (1)
- mouse model (1)
- mouse-brain (1)
- myelination (1)
- neurodegeneration (1)
- neuroscience (1)
- oxidative stress (1)
- panic disorder (1)
- phosphorylated glycogen synthase kinase-3beta (pGSK-3beta) (1)
- platelet activation (1)
- platelet aggregation (1)
- platelets (1)
- polygenic risk score (1)
- polymorphism (1)
- positive interneurons (1)
- post-traumatic stress disorder (1)
- predation stress (1)
- predictive adaptive response hypothesis (1)
- radial glia (1)
- rare mendelian disorders (1)
- response inhibition (1)
- rhesus macaques (1)
- s allele (1)
- serotonin transporter gene (1)
- sex differences (1)
- sialic acid (1)
- sialyltransferase (1)
- sleep EEG (1)
- stress resilience (1)
- substance abuse disorder (1)
- synaptic plasticity (1)
- theory of mind (1)
- toll-like receptors (1)
- translational panic model (1)
- tryptophan hydroxylase-2 (Tph2) (1)
- venturesomeness (1)
- white-matter integrity (1)
Institute
- Lehrstuhl für Molekulare Psychiatrie (34) (remove)
Attention-deficit/hyperactivity disorder (ADHD) is a neurodevelopmental disorder with an estimated heritability of around 70%. In order to fully understand ADHD biology it is necessary to incorporate multiple different types of research. In this thesis, both human and animal model research is described as both lines of research are required to elucidate the aetiology of ADHD and development new treatments. The role of a single gene, Adhesion G protein-coupled receptor L3 (ADGRL3) was investigated using a knockout mouse model. ADGRL3 has putative roles in neuronal migration and synapse function. Various polymorphisms in ADGRL3 have been linked with an increased risk of attention deficit/hyperactivity disorder (ADHD) in human studies. Adgrl3-deficient mice were examined across multiple behavioural domains related to ADHD: locomotive activity, visuospatial and recognition memory, gait impulsivity, aggression, sociability and anxiety-like behaviour. The transcriptomic alterations caused by Adgrl3-depletion were analysed by RNA-sequencing of three ADHD-relevant brain regions: prefrontal cortex (PFC), hippocampus and striatum. Increased locomotive activity in Adgrl3-/- mice was observed across all tests with the specific gait analysis revealing subtle gait abnormalities. Spatial memory and learning domains were also impaired in these mice. Increased levels of impulsivity and sociability accompanying decreased aggression were also detected. None of these alterations were observed in Adgrl3+/- mice. The numbers of genes found to exhibit differential expression was relatively small in all brain regions sequenced. The absence of large scale gene expression dysregulation indicates a specific pathway of action, rather than a broad neurobiological perturbation. The PFC had the greatest number of differentially expressed genes and gene-set analysis of differential expression in this brain region detected a number of ADHD-relevant pathways including dopaminergic synapses as well as cocaine and amphetamine addiction. The most dysregulated gene in the PFC was Slc6a3 which codes for the dopamine transporter, a molecule vital to current pharmacological treatment of ADHD. The behavioural and transcriptomic results described in this thesis further validate Adgrl3 constitutive knockout mice as an experimental model of ADHD and provide neuroanatomical targets for future studies involving ADGRL3 modified animal models.
The study of ADHD risk genes such as ADGRL3 requires the gene to be first identified using human studies. These studies may be genome based such as genome wide association studies (GWAS) or transcriptome based using microarray or RNA sequencing technology. To explore ADHD biology in humans the research described in this thesis includes both GWAS and trancriptomic data. A two-step transcriptome profiling was performed in peripheral blood mononuclear cells (PBMCs) of 143 ADHD subjects and 169 healthy controls. We combined GWAS and expression data in an expression-based Polygenic Risk Score (PRS) analysis in a total sample of 879 ADHD cases and 1919 controls from three different datasets. Through this exploratory study we found eight differentially expressed genes in ADHD and no support for the genetic background of the disorder playing a role in the aberrant expression levels identified. These results highlight promising candidate genes and gene pathways for ADHD and support the use of peripheral tissues to assess gene expression signatures for ADHD.
This thesis illustrates how both human and animal model research is required to increase our understanding of ADHD. The animal models provide biological insight into the targets identified in human studies and may themselves provide further relevant gene targets. Only by combining research from disparate sources can we develop the thorough understanding on ADHD biology required for treatment development, which is the ultimate goal of translational science research.
Behavioral profiles are influenced by both positive and negative experiences as well as the genetic disposition. Traditionally, accumulating adversity over lifetime is considered to predict increased anxiety like behavior ("allostatic load"). The alternative "mismatch hypothesis" suggests increased levels of anxiety if the early environment differs from the later-life environment. Thus, there is a need for a whole-life history approach to gain a deeper understanding of how behavioral profiles are shaped. The aim of this study was to elucidate the effects of life history on the behavioral profile of mice varying in serotonin transporter (5-HIT) genotype, an established mouse model of increased anxiety-like behavior. For this purpose, mice grew up under either adverse or beneficial conditions during early phases of life. In adulthood, they were further subdivided so as to face a situation that either matched or mismatched the condition experienced so far, resulting in four different life histories. Subsequently, mice were tested for their anxiety-like and exploratory behavior. The main results were: (1) Life history profoundly modulated the behavioral profile. Surprisingly, mice that experienced early beneficial and later escapable adverse conditions showed less anxiety-like and more exploratory behavior compared to mice of other life histories. (2) Genotype significantly influenced the behavioral profile, with homozygous 5-HTT knockout mice displaying highest levels of anxiety-like and lowest levels of exploratory behavior. Our findings concerning life history indicate that the absence of adversity does not necessarily cause lower levels of anxiety than accumulating adversity. Rather, some adversity may be beneficial, particularly when following positive events. Altogether, we conclude that for an understanding of behavioral profiles, it is not sufficient to look at experiences during single phases of life, but the whole life history has to be considered.
Cadherin-13 (CDH13) is a member of the cadherin superfamily that lacks the typical transmembrane domain for classical cadherins and is instead attached to the cell membrane with a GPI-anchor. Over the years, numerous genome-wide association (GWA) studies have identified CDH13 as a risk factor for neurodevelopmental disorders, including attention- deficit/hyperactivity disorder (ADHD) and autism spectrum disorder. Further evidence using cultured cells and animal models has shown that CDH13 plays important roles in cell migration, neurite outgrowth and synaptic function of the central nervous system. Research in our laboratory demonstrated that the CDH13 deficiency resulted in increased cell density of serotonergic neurons of the dorsal raphe (DR) in developing and mature mouse brains as well as serotonergic hyperinnervation in the developing prefrontal cortex, one of the target areas of DR serotonergic neurons. In this study, the role of CDH13 was further explored using constitutive and serotonergic system-specific CDH13-deficient mouse models. Within the adult DR structure, the increased density of DR serotonergic neurons was found to be topographically restricted to the ventral and lateral-wing, but not dorsal, clusters of DR. Furthermore, serotonergic hyperinnervation was observed in the target region of DR serotonergic projection neurons in the lateral wings. Unexpectedly, these alterations were not observed in postnatal day 14 brains of CDH13-deficient mice. Additionally, behavioral assessments revealed cognitive deficits in terms of compromised learning and memory ability as well as impulsive-like behaviors in CDH13-deficient mice, indicating that the absence of CDH13 in the serotonergic system alone was sufficient to impact cognitive functions and behavioral competency. Lastly, in order to examine the organization of serotonergic circuitries systematically and to tackle limitations of conventional immunofluorescence, a pipeline of the whole-mount immunostaining in combination with the iDISCO+ based rapid tissue clearing techniques was established. This will facilitate future research of brain neurotransmitter systems at circuitry and/or whole-brain levels and provide an excellent alternative for visualizing detailed and comprehensive information about a biological system in its original space. In summary, this study provided new evidence of CDH13’s contribution to proper brain development and cognitive function in mice, thereby offering insights into further advancement of therapeutic approaches for neurodevelopmental disorders.
Background: During early prenatal stages of brain development, serotonin (5-HT)-specific neurons migrate through somal translocation to form the raphe nuclei and subsequently begin to project to their target regions. The rostral cluster of cells, comprising the median and dorsal raphe (DR), innervates anterior regions of the brain, including the prefrontal cortex. Differential analysis of the mouse 5-HT system transcriptome identified enrichment of cell adhesion molecules in 5-HT neurons of the DR. One of these molecules, cadherin-13 (Cdh13) has been shown to play a role in cell migration, axon pathfinding, and synaptogenesis. This study aimed to investigate the contribution of Cdh13 to the development of the murine brain 5-HT system.
Methods: For detection of Cdh13 and components of the 5-HT system at different embryonic developmental stages of the mouse brain, we employed immunofluorescence protocols and imaging techniques, including epifluorescence, confocal and structured illumination microscopy. The consequence of CDH13 loss-of-function mutations on brain 5-HT system development was explored in a mouse model of Cdh13 deficiency.
Results: Our data show that in murine embryonic brain Cdh13 is strongly expressed on 5-HT specific neurons of the DR and in radial glial cells (RGCs), which are critically involved in regulation of neuronal migration. We observed that 5-HT neurons are intertwined with these RGCs, suggesting that these neurons undergo RGC-guided migration. Cdh13 is present at points of intersection between these two cell types. Compared to wildtype controls, Cdh13-deficient mice display increased cell densities in the DR at embryonic stages E13.5, E17.5, and adulthood, and higher serotonergic innervation of the prefrontal cortex at E17.5.
Conclusion: Our findings provide evidence for a role of CDH13 in the development of the serotonergic system in early embryonic stages. Specifically, we indicate that Cdh13 deficiency affects the cell density of the developing DR and the posterior innervation of the prefrontal cortex (PFC), and therefore might be involved in the migration, axonal outgrowth and terminal target finding of DR 5-HT neurons. Dysregulation of CDH13 expression may thus contribute to alterations in this system of neurotransmission, impacting cognitive function, which is frequently impaired in neurodevelopmental disorders including attention-deficit/hyperactivity and autism spectrum disorders.
Cadherin-13 (CDH13), a unique glycosylphosphatidylinositol-anchored member of the cadherin family of cell adhesion molecules, has been identified as a risk gene for attention-deficit/hyperactivity disorder (ADHD) and various comorbid neurodevelopmental and psychiatric conditions, including depression, substance abuse, autism spectrum disorder and violent behavior, while the mechanism whereby CDH13 dysfunction influences pathogenesis of neuropsychiatric disorders remains elusive. Here we explored the potential role of CDH13 in the inhibitory modulation of brain activity by investigating synaptic function of GABAergic interneurons. Cellular and subcellular distribution of CDH13 was analyzed in the murine hippocampus and a mouse model with a targeted inactivation of Cdh13 was generated to evaluate how CDH13 modulates synaptic activity of hippocampal interneurons and behavioral domains related to psychopathologic (endo) phenotypes. We show that CDH13 expression in the cornu ammonis (CA) region of the hippocampus is confined to distinct classes of interneurons. Specifically, CDH13 is expressed by numerous parvalbumin and somatostatin-expressing interneurons located in the stratum oriens, where it localizes to both the soma and the presynaptic compartment. Cdh13\(^{-/-}\) mice show an increase in basal inhibitory, but not excitatory, synaptic transmission in CA1 pyramidal neurons. Associated with these alterations in hippocampal function, Cdh13\(^{-/-}\) mice display deficits in learning and memory. Taken together, our results indicate that CDH13 is a negative regulator of inhibitory synapses in the hippocampus, and provide insights into how CDH13 dysfunction may contribute to the excitatory/inhibitory imbalance observed in neurodevelopmental disorders, such as ADHD and autism.
SLC2A3 encodes the predominantly neuronal glucose transporter 3 (GLUT3), which facilitates diffusion of glucose across plasma membranes. The human brain depends on a steady glucose supply for ATP generation, which consequently fuels critical biochemical processes, such as axonal transport and neurotransmitter release. Besides its role in the central nervous system, GLUT3 is also expressed in nonneural organs, such as the heart and white blood cells, where it is equally involved in energy metabolism. In cancer cells, GLUT3 overexpression contributes to the Warburg effect by answering the cell's increased glycolytic demands. The SLC2A3 gene locus at chromosome 12p13.31 is unstable and prone to non‐allelic homologous recombination events, generating multiple copy number variants (CNVs) of SLC2A3 which account for alterations in SLC2A3 expression. Recent associations of SLC2A3 CNVs with different clinical phenotypes warrant investigation of the potential influence of these structural variants on pathomechanisms of neuropsychiatric, cardiovascular, and immune diseases. In this review, we accumulate and discuss the evidence how SLC2A3 gene dosage may exert diverse protective or detrimental effects depending on the pathological condition. Cellular states which lead to increased energetic demand, such as organ development, proliferation, and cellular degeneration, appear particularly susceptible to alterations in SLC2A3 copy number. We conclude that better understanding of the impact of SLC2A3 variation on disease etiology may potentially provide novel therapeutic approaches specifically targeting this GLUT.
The current diagnostic criteria of the Diagnostic and Statistical Manual of Mental Disorders are being challenged by the heterogeneity and the symptom overlap of psychiatric disorders. Therefore, a framework toward a more etiology-based classification has been initiated by the US National Institute of Mental Health, the research domain criteria project. The basic neurobiology of human psychiatric disorders is often studied in rodent models. However, the differences in outcome measurements hamper the translation of knowledge. Here, we aimed to present a translational panic model by using the same stimulus and by quantitatively comparing the same outcome measurements in rodents, healthy human subjects and panic disorder patients within one large project. We measured the behavioral–emotional and bodily response to CO\(_{2}\) exposure in all three samples, allowing for a reliable cross-species comparison. We show that CO\(_{2}\) exposure causes a robust fear response in terms of behavior in mice and panic symptom ratings in healthy volunteers and panic disorder patients. To improve comparability, we next assessed the respiratory and cardiovascular response to CO\(_{2}\), demonstrating corresponding respiratory and cardiovascular effects across both species. This project bridges the gap between basic and human research to improve the translation of knowledge between these disciplines. This will allow significant progress in unraveling the etiological basis of panic disorder and will be highly beneficial for refining the diagnostic categories as well as treatment strategies.
This thesis explores the development of monoaminergic systems in the central nervous system (CNS) of zebrafish. The serotonergic cells of the hypothalamus pose the main focus of the present work. Most vertebrates except for mammals possess serotonin (5-HT) synthesising cells in more than one region of the CNS. In zebrafish such regions are, e.g. the hypothalamus, the raphe nuclei and the spinal cord. Serotonin functions as a neurotransmitter and neuromodulator in the CNS. Presumably due to its neuromodulatory tasks hypothalamic serotonergic cells are in contact with the cerebrospinal fluid (CSF), which expands the field of potential serotonergic targets tremendously. This highlights that serotonergic CSF-contacting (CSF-c) cells are vital for the execution of many functions and behaviours. Further, the hypothalamic serotonergic clusters constitute the largest population of serotonergic cells in the CNS of zebrafish. Together, these facts emphasise the need to understand the development and function of serotonergic CSF-c cells in the hypothalamus. Few studies have dealt with this subject, hence, information about the development of these cells is scarce. The zinc-finger transcription factor fezf2, and Fibroblast growth factor (Fgf)-signalling via the ETS-domain transcription factor etv5b are known to regulate serotonergic cell development in the hypothalamus (Bosco et al., 2013; Rink and Guo, 2004). However, the main Fgf ligand responsible for this mediation has not been determined prior to this work. The present thesis identifies Fgf3 as a crucial Fgf ligand. To achieve this result three independent strategies to impair Fgf3 activity have been applied to zebrafish embryos: the fgf3t24152 mutant, an fgf3 morpholino-based knock-down and the CRISPR/Cas9 technique. The investigations show that Fgf3 regulates the development of monoaminergic CSF-c cells in the hypothalamus. Additionally, Fgf3 impacts on cells expressing the peptide hormone arginine vasopressin (avp). Most interestingly, the requirement for Fgf3 by these cells follows a caudo-rostral gradient with a higher dependence on Fgf3 by caudal cells. This also seems to be the case for dopaminergic CSF-c cells in the hypothalamus (Koch et al., 2014). Moreover, etv5b a downstream target of Fgf-signalling is demonstrated to be under the control of Fgf3. With regard to serotonergic CSF-c cell development, it is shown that fgf3 is expressed several hours before tph1a and 5-HT (Bellipanni et al., 2002; Bosco et al., 2013). Together with the result that the hypothalamus is already smaller before mature serotonergic CSF-c cells appear, this argues for an early impact of Fgf3 on serotonergic specification. This hypothesis is supported by several findings in this study: the universal decrease of proliferating cells in the hypothalamus and simultaneous increase of cell death after fgf3 impairment. Complementary cell fate experiments confirm that proliferating serotonergic progenitors need Fgf3 to commit serotonergic specification. Further, these results corroborate findings of an earlier study stating that hypothalamic serotonergic progenitors require Fgf-signalling via etv5b to maintain the progenitor pool (Bosco et al., 2013). Additionally, the transcriptome of the hypothalamus has been analysed and 13 previously overlooked transcripts of Fgf ligands are expressed at developmental stages. The transcriptome analysis provides evidence for a self-compensatory mechanism of fgf3 since expression of fgf3 is upregulated as a consequence of its own impairment. Moreover, the Fgf-signalling pathway appears to be mildly affected by fgf3 manipulation. Together, Fgf-signalling and especially Fgf3 are established to be of critical importance during hypothalamic development with effects on serotonergic, dopaminergic CSF-c and avp expressing cells. Furthermore, this thesis provides two strategies to impair the tph1a gene. Both strategies will facilitate investigations regarding the function of hypothalamic serotonergic CSF-c cells. Finally, the presented findings in this study provide insights into the emergence of the posterior recess region of the hypothalamus, thereby, contributing to the understanding of the evolution of the vertebrate hypothalamus.
Central insulin receptor-mediated signaling is attracting the growing attention of researchers because of rapidly accumulating evidence implicating it in the mechanisms of plasticity, stress response, and neuropsychiatric disorders including depression. Dicholine succinate (DS), a mitochondrial complex II substrate, was shown to enhance insulin-receptor mediated signaling in neurons and is regarded as a sensitizer of the neuronal insulin receptor. Compounds enhancing neuronal insulin receptor-mediated transmission exert an antidepressant-like effect in several pre-clinical paradigms of depression; similarly, such properties for DS were found with a stress-induced anhedonia model. Here, we additionally studied the effects of DS on several variables which were ameliorated by other insulin receptor sensitizers in mice. Pre-treatment with DS of chronically stressed C57BL6 mice rescued normal contextual fear conditioning, hippocampal gene expression of NMDA receptor subunit NR2A, the NR2A/NR2B ratio and increased REM sleep rebound after acute predation. In 18-month-old C57BL6 mice, a model of elderly depression, DS restored normal sucrose preference and activated the expression of neural plasticity factors in the hippocampus as shown by Illumina microarray. Finally, young naive DS-treated C57BL6 mice had reduced depressive- and anxiety-like behaviors and, similarly to imipramine-treated mice, preserved hippocampal levels of the phosphorylated (inactive) form of GSK3 beta that was lowered by forced swimming in pharmacologically naive animals. Thus, DS can ameliorate behavioral and molecular outcomes under a variety of stress- and depression-related conditions. This further highlights neuronal insulin signaling as a new factor of pathogenesis and a potential pharmacotherapy of affective pathologies.
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.