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Diese Arbeit widmet sich der Untersuchung einer Kopienzahlvariante (CNV) im Erbgut, die zu
einer genomischen Duplikation des SLC2A3-Gens führt. Die Auswirkungen der SLC2A3-
Duplikation wurden im Zellkulturmodell und durch bildgebende Verfahren untersucht. Für die
SLC2A3-Duplikation konnte eine populationsspezifische Assoziation mit ADHS gezeigt
werden (Merker et al. 2017). SLC2A3 kodiert für den neuronalen Glukosetransporter GLUT3,
der u.a. Prozesse der Neurotransmitterfreisetzung und Synaptogenese vermittelt und daher
wichtig für die Hirnreifung ist. Mögliche Endpunkte für Endophänotypen, die auf einem
alterierten Glukosemetabolismus basieren, sind dysfunktionale Hungerregulationsmechanismen
ebenso wie eine veränderte neurale Reaktivität gegenüber emotionalen Stimuli
und Belohnungsreizen.
In zwei peripheren Zellmodellen konnte gezeigt werden, dass die SLC2A3-Duplikation
Gen-Dosis-abhängig zu einer Steigerung der basalen SLC2A3-mRNA Expression führt. Ein
Expressionsunterschied auf Proteinebene konnte jedoch nicht gefunden werden. Metabolischer
Zellstress durch Aushungern der Zellkulturen und eine niedrige Glukosekonzentration im
Zellkulturmedium führten zu einer signifikanten Erhöhung des schon unter basalen
Bedingungen vorhandenen SLC2A3-Expressionsunterschiedes zwischen Duplikations- und
Kontrollzelllinien. Dies deutet darauf hin, dass die SLC2A3-Duplikation bei verminderter
zellulärer Energiezufuhr zu einer Überkompensation der Glukoseaufnahme führt.
In einer fMRT-Untersuchung wurden erwachsene ADHS-Patienten mit SLC2A3-
Duplikation mit ADHS-Patienten und gesunden Kontrollen mit jeweils 2 Genkopien
hinsichtlich ereigniskorrelierter neuraler Aktivität als Antwort auf emotionale Stimuli und
Essensreize verglichen. Es konnte gezeigt werden, dass die SLC2A3-Duplikation zu einer
veränderten Reaktivität gegenüber hochkalorischen Essensreizen führt, was sich in einem durch
maschinelles Lernen identifizierten multivariaten neuralen Antwortmuster und einer relativen
Unterschätzung des Kaloriengehaltes hochkalorischer Nahrung zeigt. Bei der univariaten
Gesamthirn-Analyse der Bilddaten wurden keine signifikanten Gruppenunterschiede gefunden,
was darauf hinweist, dass unter den gewählten Versuchsbedingungen keine fokal
umschriebenen Gruppenunterschiede der Hirnaktivierung bestehen.
Diese Arbeit zeigt, dass die SLC2A3-Duplikation zu einer Erhöhung der SLC2A3-
Genexpression mit bisher unbekannten Auswirkungen auf nachgeschaltete Stoffwechselwege
und zu einem komplex veränderten neuralen Antwortmuster führt, das durch einen linearen
Zusammenhang nicht zu beschreiben ist. Weitere Untersuchungen auf Zellebene und eine
Erweiterung der bildgebenden Verfahren könnten zu einer besseren Einordnung der SLC2A3-
Duplikation bezüglich ihres Anteils an der endophänotypischen Varianz der ADHS führen.
SNAP25 (Synaptosomal-Associated Protein of 25 kDa; part of the SNARE complex) is involved in the docking and fusion of synaptic vesicles in presynaptic neurons necessary for the regulation of neurotransmitter release, as well as in axonal growth and synaptic plasticity. In humans, different single nucleotide polymorphisms of SNAP25 have repeatedly been associated with attention deficit/hyperactivity disorder (ADHD). Thus, in this study heterozygous Snap25 knockout mice were investigated as a model of ADHD.
Heterozygous (+/-) Snap25 knockout mice as well as their wild-type (+/+) littermates were reared under control conditions or underwent a Maternal Separation (MS) procedure. Starting at the age of 2 months, mice were tested for locomotor activity in a repeated long-term Open Field (OF) task, for attention deficits and impulsive behavior in the 5 Choice Serial Reaction Time Task (5CSRTT), for anxiety-like behavior in the Light-Dark Box (LDB) and for depression-like behavior in the Porsolt Forced Swim Test (FST). The brains of these mice were subsequently tested for the expression of several ADHD related genes in a quantitative Real-Time PCR (qRT-PCR) study. Another group of female mice (+/+; +/-) underwent a one hour OF test after oral administration of 45 mg/kg Methylphenidate (MPH) or placebo.
To find an optimized dosage for this MPH challenge, a pilot study was performed. Wild-type C57BL/6 mice were tested in a long-term OF with several dosages of MPH both intraperitoneally (i.p.) and orally. The brains of these animals were afterwards investigated for neurotransmitter concentrations. In this pilot study the dosages of MPH that were similarly behaviorally effective without causing symptoms of overdosing were 7.5-15 mg/kg intraperitoneally and 30-60 mg/kg orally. However, even though it was possible to find intraperitoneal and oral doses that correlate behaviorally, the neurochemistry was mostly different.
In the study on Snap25-deficient mice, unstressed controls showed a hyperactive phenotype in the second of two long-term OF sessions (60 min) spaced three weeks apart. Considering all groups, there was a significant interaction of stress and genotype in the second session, with animals subjected to MS being overall hyperactive with no genotype differences. In the training phase of the 5CSRTT only effects of stress were found, with MS animals finding and consuming fewer rewards. In the single test trial, several genotype effects became apparent, with tendencies for the number of correct nose pokes and the number of rewards eaten, and a significant effect for the number of rewards eaten directly after the correct response. In all of these variables +/- mice performed worse than their wild-type littermates. In the LDB +/- mice entered the lit compartment of the arena earlier than the controls, thus showing attenuated anxiety-like behavior. Regarding depressive-like behavior in the FST, male +/- mice spent significantly less time struggling than male +/+ mice. In the gene expression study, +/- mice had lower expression levels of Maoa and Comt, and higher expression levels of Nos1 than wild-types. Finally, the locomotor activity response to MPH was exaggerated in +/- mice as compared to controls.
Heterozygous Snap25 knockout mice show some of the behavioral characteristics of ADHD, as for example a mild hyperactivity in a familiar environment, difficulties in the correct execution of a given task and even some behavior that can be interpreted as delay aversion. Additionally, expression levels of three ADHD related genes were changed in these animals. Although the exaggerated locomotor activity response to MPH is not to be expected of an ADHD model, the difference in the response between +/+ and +/- mice nonetheless implicates a potential dysfunction of the brain dopaminergic system.
Neuropsychiatric disorders, such as attention-deficit/hyperactivity disorder (ADHD), represent a burden which deeply impair the patient’s life. Neurobiological research has therefore increasingly focused on the examination of brain neurotransmitter systems, such as the serotonin (5-HT) system, since a dysfunction has been repeatedly implicated in the pathology of these diseases. However, investigation of functional human neurons in vitro has been restricted by technical limitations for a long time until the discovery of human induced pluripotent stem cells (iPSCs) revolutionized the field of experimental disease models. Since the pathogenesis of neuropsychiatric disorders involves a complex genetic component, genome-wide association studies (GWAS) revealed numerous risk genes that are associated with an increased risk for ADHD. For instance, the novel ADHD candidate gene SLC2A3 which encodes the glucose transporter-3 (GLUT3), facilitates the transport of glucose across plasma membranes and is essential for the high energy demand of several cell types, such as stem cells and neurons. Specifically, copy number variants (CNVs) of SLC2A3 might therefore impact cerebral glucose metabolism as well as the assembly of synaptic proteins in human neurons which might contribute to the pathogenesis of ADHD.
We hypothesized that an altered SLC2A3 gene dosage in human neurons can exert diverse protective or detrimental effects on neurodevelopmental processes as well as the coping of glucometabolic stress events, such as hypo- and hyperglycaemic conditions. The generation of specific iPSC lines from ADHD patients and healthy probands served as basis to efficiently differentiate stem cells into 5-HT specific neurons. Using this neuronal culture, we were able to examine effects of SLC2A3 CNVs on the basal expression of SCL2A3 and GLUT3 in human neurons. Furthermore, the focus was on potentially altered coping of the cells with glucose deprivation and the treatment with specific high- and low glycaemic media.
High-resolution fluorescence imaging in combination with electrophysiological and molecular biological techniques showed that:
1) The generated human iPSCs are fully reprogrammed human stem cells showing typical characteristics of embryonic stem cell-like morphology, growth behaviour, the ability to differentiate into different cell types of the human body and the expression of pluripotency-specific markers.
2) The neuronal subtype derived from our stem cells display typical characteristics of 5-HT specific median and dorsal neurons and forms synapses reflected by the expression of pre- and postsynaptic proteins.
3) Even if SLC2A3 CNVs influence SLC2A3 and GLUT3 basal expression, no significant alterations in gene and protein expression caused by hyper- and hypoglycaemic conditions, nor in the assembly of proteins associated with synapse formation could be observed in human iPSC-derived neurons.