Browsing by Subject "TrkB"

In recent years, psychedelics have shown promise in the treatment of conditions like depression and addiction. The therapeutic effects of psychedelics have been linked to their ability to increase plasticity in the brain, an effect that has also been seen for antidepressants. Brain-derived neurotrophic factor (BDNF) is a member of the neurotrophin family, which has an important role in the development of the nervous system, as well as promotion of neuronal survival and differentiation during adulthood. BDNF, through its receptor TrkB, has been implicated in antidepressant action, and BDNF-TrkB signalling is involved in many aspects of plasticity. Recently, antidepressants have been reported to bind directly to TrkB, and through this binding mediate their plasticity-enhancing, as well as behavioural effects. Psychedelics have been shown to increase structural and functional plasticity, but the mechanisms behind these effects are not fully understood. For example, the serotonergic receptor 5-HT2A is known to be behind the acute hallucinogenic effects of psychedelics, but its role in plasticity is still debated. The aim of this study was to investigate the mechanisms of LSD-induced plasticity. The dimerization of TrkB was examined after LSD treatment in the protein-fragment complementation assay (PCA). Phosphorylation of TrkB signalling markers mTOR and ERK, which have known effects on plasticity, was assessed in Western blot, and the total expression of BDNF was examined with the enzyme-linked immunosorbent assay (ELISA). The timeline of the effects was investigated, and the involvement of 5-HT2A in TrkB dimerization and the phosphorylation of ERK was assessed by combining LSD treatment with the 5-HT2A antagonist M100907. Dimerization was also assessed in a TrkB mutant (Y433F) that has previously been shown to disrupt antidepressant effects on plasticity. These experiments showed that LSD treatment increased TrkB dimerization as well as phosphorylation of mTOR and ERK. The Y433F mutation interfered with LSD-induced TrkB dimerization, but the effects of LSD on TrkB dimerization or ERK phosphorylation were not blocked by M100907. Together, these data suggest that 5-HT2A is not involved in LSD-induced promotion of TrkB dimerization or ERK phosphorylation. The increases in phosphorylation and dimerization were found to be most robust after a 1 h LSD treatment, however an increase in BDNF expression was seen in cortical neuron cultures only after a 24 h treatment with LSD. The results reported in this study support the view that 5-HT2A might not be needed for the plasticity-inducing effects of psychedelics. If this is true, the development of treatments that target plasticity without hallucinatory effects could be possible. Overall, this research provides insight into the mechanisms of LSD-induced plasticity and offers new and interesting directions for future research in the field.

It is well known that the central nervous system is a highly isolated tissue. Because of this the physico-chemical criteria to be met by an orally administered central nervous system drug are very strict. This work describes methods that can be used to select drug candidates and screening collections that have a higher possibility of being relevant to central nervous system drug development projects. This work also argues that small molecular space is so vast that it is difficult to imagine any progress without focusing screening collections in some way or another. Given that most available commercial compounds are very similar in some respects, it is very much possible that this presents a bottle-neck for the progress of drug development as a whole. Therefore, research on novel methods for compound production are also evaluated. In addition, this work describes the miniaturization and automation of a previously published ELISA-based assay. This assay measures the activation of a tyrosine kinase receptor (TrkB), expressed in a fibroblast cell line. The receptor, and it's endogenous ligand, Brain-derived neurotrophic factor, have been linked to the mechanism of action of previously discovered medical interventions used in the treatment of depression. Such an assay can be used to discover either small molecule agonists or antagonists acting upon the receptor. These molecules could possibly be clinically relevant in the treatment of depressive disorders and anxiety. It is demonstrated that it is indeed possible to miniaturize and automate the method, making it significantly more suitable for high-throughput screening. The original method was carried out in 24-well plates, transferring the samples to another plate for measurement. The new design uses 96-well plates and performs the entire process on the same plate.

Pharmacologically induced neuronal plasticity holds unprecedented potential in treatment of several neurological disorders, such as depression. Several antidepressant drugs have been shown to induce neuronal plasticity by stimulating BDNF (brain-derived neurotrophic factor) receptor TrkB (tropomyosin receptor kinase B). Studies with rapid-acting antidepressant treatments suggest delta range slow wave EEG (electroencephalography) activity to function as a potential non-invasive biomarker for activation of TrkB-related neuroplastic signaling responses. A sedative GABAA-agonist THIP (gaboxadol) has been shown to induce slow wave EEG activity (SWA) and preliminary studies suggest it to activate TrkB signaling as well. The aim of the present study was to examine the potential connection between SWA, neuroplastic signaling responses and neuronal inhibition by utilizing EEG measurements and THIP administration in genetic and developmental mouse models. The pharmaco-EEG experiments showed acute THIP administration (6 mg/kg, i.p.) to increase SWA in wild-type but not in GABAA δ-subunit knockout mice. TrkB signaling responses from similar treatment groups showed a trend of increased TrkB-related protein phosphorylation in wild-type but not in GABAA δ-subunit knockout mice indicating a positive connection between SWA, neuronal inhibition and TrkB-related signaling response. Autophosphorylation response of TrkB and related proteins in mice of different age showed most TrkB phosphorylation in postnatal day 16 (P16) mouse pups, whereas phosphorylation response of CREB and p70S6k was the highest in postnatal day 8 (P8) mouse pups. Since SWA emerges during the second postnatal week in mice, the obtained result further supports the connection between SWA and TrkB signaling. Acute THIP administration caused no significant phosphorylation changes in P8 or P16 mouse pups. The results support the hypothesis of a positive connection between SWA, neuronal inhibition and TrkB-related signaling response. Further studies with different excitatory and inhibitory interventions are required to better understand the role of neuronal excitation and inhibition in TrkB signaling responses and corresponding EEG signatures.

Currently, there is an undeniable need for more effective treatments of depression. The efficacy of traditional antidepressant drugs becomes apparent after multiple weeks of treatment. New advancements in depression treatments have been made, as glutamatergic NMDA-receptor antagonist ketamine is seen to ameliorate symptoms rapidly, even only hours after drug administration. Understanding ketamine’s mechanism of action as an antidepressant could enable the development of more effective antidepressant drugs. The critical molecular level component in ketamine’s antidepressant effect is considered to be the activation of TrkB tyrosine receptor kinase B, which subsequently leads to the initiation of signaling pathways, which regulate synaptic plasticity. So far, it has not been examined; whether there is a difference in ketamine’s antidepressant effect based on the dosing-time of day. The aim of the present study was to find out if there is a variation between ketamine’s effect on synaptic plasticity and the circadian phase in which the drug is administered. Ketamine’s (200 or 50 mg/kg, i.p.) effects were studied in C57BL/6J–mice during light phase (mouse’s inactive phase) and dark phase (mouse’s active phase) of the day. The phase of the day didn’t affect the activity of TrkB signaling in its related parts (pTrkBTyr816, pGSK3βSer9, p-p70S6KTyr421/Ser424 and p-p44/42MAPKThr202/Tyr204) in prefrontal cortex samples which were analysed in Western blot assay. Ketamine increased dose-dependently the phosphorylation of GSK3βSer9 and p70S6KTyr421/Ser424 as well as decreased p-p44/42MAPKThr202/Tyr204 at 30 minutes after drug administration in both phases of the day. Ketamine (200 mg/kg, i.p.) also lowered the glucose concentration measured from the trunk blood. To examine the effect of hypoglycemia on the activity of TrkB signaling another experiment was conducted. The hypoglycemia induced by insulin detemir (6 IU/kg, i.p.) didn’t affect any measured protein phosphorylation at 60 minutes after drug administration. The results of this study support the notion of ketamine’s rapid and dosedependent induction of neuroplasticity. The possible role of hypoglycemia in ketamine's neuropharmacology should be investigated in future studies.

Subanesthetic-dose ketamine, an N-methyl-D-aspartate receptor (NMDAR) blocker, exerts rapid antidepressant effects that sustain long after its elimination from the body. The precise mechanism remains unknown, but regulation of TrkB (tropomyosin receptor kinase B), ERK (extracellular-regulated kinase 1 and 2), GSK3β (glycogen synthase kinase 3β) and mTOR (mammalian target of rapamycin) signaling within the prefrontal cortex (PFC) have been deemed important for its antidepressant-like effects in rodents. In addition, activation of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors (AMPARs) is thought to be an important step in its mechanism. Nitrous oxide (N2O), another NMDAR antagonist and a putative rapid-acting antidepressant, regulates the same molecular pathways as ketamine in the rodent PFC. The fast pharmacokinetics of N2O have been exploited to show that markers of neuronal excitation, including phosphorylation of ERK, are upregulated in the PFC during its acute pharmacological effects (NMDAR blockade), while regulation of TrkB, GSK3β and P70S6K emerges only upon N2O withdrawal. In the first part of this study, we investigated the N2O-induced biochemical changes associated with neuronal excitation and BDNF-TrkB signaling in the PFC and further, the requirement for AMPAR activation in inducing them. We focused on the effects seen after the acute pharmacological effects of N2O. N2O (65% for 20 min) was administered to adult male C57BL/6 mice with or without pretreatment with AMPAR antagonist (NBQX, 10 mg/kg) and PFC samples were collected 15 minutes after stopping N2O delivery. Within this time N2O is expected to be completely eliminated. The brain samples were analyzed using western blot, enzyme-linked immunosorbent assay and quantitative reverse transcription PCR. We observed that N2O increased levels of phosphorylated TrkB, GSK3β and P70S6K, and these effects were not attenuated by NBQX pretreatment. At the same time, we observed a decrease in the levels of phosphorylated ERK, which was attenuated in mice that received NBQX prior to N2O. Tissue levels of BDNF protein or messenger RNA (exon IV) were not different between control and experimental groups. These results indicate that the mechanism of N2O is associated with TrkB and ERK signaling that are regulated independently of each other. It appears that AMPAR activation is not required for TrkB signaling, although it might play a role in ERK signaling. Further, N2O-induced TrkB phosphorylation in the PFC is not associated with changes in total levels of BDNF. In the second part of the study, we aimed to search for new ketamine-like NMDAR blockers with antidepressant potential. Ketamine was used as a query compound for in silico substructure search to find commercial ketamine analogs. The retrieved ketamine analogs were filtered by their computed ADMET properties and then further screened virtually by docking them to the pore region of NMDAR complex (protein data bank code: 4TLM), around the predicted binding site of ketamine. Finally, we sought to study if selected ketamine analogs could elicit ketamine-like effects on TrkB and ERK signaling in mouse primary cortical neurons. However, we did not proceed to test the analogs since ketamine (positive control) did not show any effects on TrkB or ERK phosphorylation in our culture. Overall, this study advances the understanding of the mechanism of N2O, possibly giving new insight of the antidepressant mechanisms of NMDAR-blocking agents more generally. Additionally, we found promising ketamine analogs that await experimental testing.

Current pharmacological treatments for major depressive disorder leave many patients unresponsive to treatment or treatment response is delayed by weeks. More effective treatments with quicker effect onset are therefore needed. Ketamine, an N-methyl-D-aspartate (NMDA) receptor antagonists has demonstrated sustained rapid antidepressant activity after single dose. Precise mechanisms behind this effect are unknown, however some crucial contributors to ketamine-induced behavioural effects in rodents include phosphorylation of Tropomyosin receptor kinase B (TrkB), ribosomal protein s6 kinase (p70s6k), glycogen synthase kinase 3 (GSK3), mitogen activated protein kinases (MAPKs), and activation of α-amino-3-hydroxy-5- methyl-4- isoxazolepropionic acid receptors (AMPAR). Similar TrkB related signaling cascades are also activated with another NMDA receptor antagonist and a putative rapid-acting antidepressant, nitrous oxide (N2O). During acute effects of N2O, cortical excitation increases MAPK phosphorylation and upregulates expression of activity dependent immediate early genes (IEG; c-Fos and Bdnf IV). Phosphorylation of TrkB, GSK3 and p70s6k appearing only after N2O has been eliminated suggest that TrkB signaling is induced as an adaptive response to treatment. The first objective of this study was to corroborate previous results from our group to validate our gas administration set up and protein analysis protocol. To analyze N2O-induced phosphorylation of proteins implicated in ketamine’s behavioral effects in mice, we treated C57BL/6J male mice with either room air (control) or 65% nitrous oxide for 20 minutes. After gas exposure and 15-minute washout period, medial prefrontal cortex samples were dissected to be analyzed with western blotting. In this study nitrous oxide exposure did not induce increased TrkB signaling in nitrous oxide withdrawal. Another aim of this study was to investigate the involvement of AMPARs in inducing cortical excitation with N2O. Pretreatment of AMPAR antagonist (10 mg/kg, NBQX) or saline was given to C57BL/6J male mice 10 minutes prior to 1 hour exposure to 50 % O2 or 50 % N2O, a N2O dose previously shown to induce IEG expression. One hour after gas exposure mice were euthanized and mPFCs were dissected and analyzed with reverse transcriptase quantitative PCR (RT-qPCR). No regulation in IEG expression was induced with nitrous oxide, NBQX pretreatment or combination compared to control. Additional studies factoring in limitations of this study are needed to uncover the involvement of AMPAR in inducing cortical excitation and antidepressant-like behavioral effects of N2O in preclinical models of depression.

Myelin is a lipid-rich substance wrapped around nerve axons that can be adaptively modified in response to neuronal activity and experience. Recent research has revealed myelination of parvalbumin (PV) inhibitory interneurons, critical for brain oscillations and balance. Defects in PV interneuron myelination have been linked to psychiatric disorders, like schizophrenia. Tropomyosin receptor kinase B (TrkB) signaling has been shown to be important for myelination. Moreover, fluoxetine, an antidepressant, binds to TrkB receptors in PV interneurons, enhancing plasticity. While previous studies support the importance of PV interneuron mediated TrkB signaling for anti-depressant induced neural plasticity, its effect on PV interneuron myelination remains unexplored. The objective of this thesis was to investigate whether TrkB signaling, and fluoxetine affect the overall and PV-interneuron specific myelination in the medial prefrontal cortex (mPFC) in mice. Using immunohistochemical analysis, we assessed myelin changes through node of Ranvier morphology and myelin immunostaining intensity in control and in mice with heterozygous conditional TrkB deletion in PV interneurons (hereafter referred to as TrkB KO), with or without fluoxetine. We found that fluoxetine increases node length in TrkB KO mice, while reduced TrkB signaling shortens paranodes in PV neurons compared to controls. Our findings also depict that fluoxetine and PV-mediated TrkB signaling do not alter the overall myelination of the mPFC. The findings of this work provide mechanistic insights into PV interneuron myelination in the mPFC, with potential implications for demyelinating and psychiatric conditions where PV myelination plays a role.