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Nemaline myopathy (NM) is a rare congenital disorder, the most common of congenital myopathies. It affects primarily the skeletal muscles and it is recognised by nemaline bodies in muscle tissue samples and muscle weakness. Mutation of eleven genes are known to lead to NM and the most frequent disease-causing variants are either recessive NEB variants or dominant ACTA1 variants. Variants in NEB are thought to be well tolerated and only 7% of them are hypothesized to be pathogenic. Over 200 pathogenic NEB-variants have been identified in Helsinki and the majority occurred in patients as a combination of two different variants. The missense variants were speculated to have a modifying effect on pathogenicity by affecting nebulin-actin or nebulin-tropomyosin interactions. Nebulin is a gigantic protein coded by NEB and is one of the largest proteins in vertebrates. It is located in the thin filament of the skeletal muscle sarcomere. Enclosed by terminal regions, nebulin has an extensive repetitive modular region that covers over 90% of the protein. The repetitive zone comprises of 26 modules called super repeats (SR). SRs consist of seven simple repeats. There are seven conserved SDXXYK actin-binding sites at each super repeat, one per simple repeat, and one conserved WLKGIGW tropomyosin-binding site. Due to its enormous size and highly repetitive sequence, nebulin is one of the least studied proteins in vivo, in vitro or in silico. In the NM patient database used for this study, there are 70 families with verified pathogenic mutations and in 30 of them, there were additional missense variants in NEB. These missense variants can be pathogenic modifying factors or have no impact on the phenotype. Seven missense variants were selected to study the effect of these mutations on actin-binding capacity compared to wild-type nebulin using the SR panel constructed previously by Laitila and Lehtonen. Also, due to the differences in actin-binding capacity of SRs compared to each other, one of the aims was to determine whether corresponding mutations in different SRs would have a similar or different effect on actin-binding capacity. For this aim, one missense mutation in the strongly actin-binding SR 1, and one in the weakly actin-binding SR 7 were selected from the NM database, and corresponding variants were created. Also, an in-frame deletion in SR7 found in the ExAC database and the corresponding mutation in SR1 were constructed for this study. The actin-binding strength was determined using actin co-sedimentation assay and actin affinity assay. The results for co-sedimentation assay indicate that missense variants can have an effect on nebulin-actin interactions and, therefore, can be a possible cause for NM. The corresponding mutations had no correlation in their effect on actin-binding strength, just the opposite. S1-m-2 decreased actin-binding strength of SR1 and S7-m-2 had no effect on SR7. Likewise, S7-m-1 and S7-del-1 decreased actin-binding strength of SR7 and corresponding mutations had no effect on SR1. The selected missense mutations found in NM patients in SRs 2 and 4 decreased actin-binding strength, if located at the actin-binding sites and in SR 10 increased the actin-binding strength, if located at the actin-binding site. The change in actin binding strength was defined as significant if the P-value was below 0.005. The more accurate affinity assay was performed as a trial only for S16 and S16-m-1, a variant at a tropomyosin-binding site close to an actin-binding site. It indicated a difference in actin-binding affinity missed by the actin co-sedimentation assay. The results are preliminary, but show big promise and should be optimized and implemented in the future missense mutation affinity studies. In an attempt to understand if the effect missense mutations have on nebulin-actin interaction is based on the change in nebulin structure, the 3D-structure of each produced fusion protein was predicted in silico. Considering that the variants were produced as GST-fusion proteins, the position and effect of GST in them is also a point of interest. In order to predict the structure of these large proteins, a combined approach was implemented using I-TASSER (Iterative Threading ASSEmbly Refinement) software. The software uses ab initio modeling, threading methods and atomic-level structure refinement to build an accurate 3D-model of a protein from sequence. According to the predicted 3D models of the fusion proteins, the GST-part of the proteins folds into a globular structure and acts as a core around which the nebulin fragments fold. The GST does not bind to actin and is positioned on the inside, which indicates minimal effect on nebulin-actin interaction, but may be a reason for an alternative nebulin fragment folding. The accuracy of the default set of programs in software does not give the definitive answer of the possible effect missense mutations can have on structural changes. However, I-TASSER approach for 3D-modeling is promising with further software optimization and can possibly serve as an effective bioinformatic tool in the future.

The Cl- and HCO3- electrochemical gradients across the plasma membrane dictate the electrical consequences of GABAA receptor (GABAAR) function and thereby play a significant role in neuronal GABA-mediated signalling. In adult pyramidal neurons, responses to GABA are maintained hyperpolarizing mainly by the action of K-Cl cotransporter isoform 2 (KCC2). KCC2 acts as a Cl- extrusion mechanism responsible for setting the intracellular Cl- concentration below the electrochemical equilibrium, a necessary condition for hyperpolarizing inhibition mediated by GABAARs. Recent evidence suggests that plasmalemmal KCC2 has a very high rate of turnover, pointing to a novel role for changes in KCC2 expression in diverse manifestations of neuronal plasticity. Some studies indicate that rapid down-regulation of KCC2 may be a general early response involved in various kinds of neuronal trauma. In this work, whole-cell patch-clamp was used to examine KCC2 function under a pharmacologically induced arrest of protein synthesis in living hippocampal brain slices from rat. The stability of KCC2 function was quantitatively assessed on the basis of the dendritic Cl- extrusion capacity in the presence of protein synthesis inhibitors cycloheximide and emetine. The parameter used for assessing extrusion capacity was a somato-dendritic Cl- gradient, which was imposed by a somatic Cl- load that resulted in a gradient of EGABA (ΔEGABA). The results of this study show that under general protein synthesis inhibitor-induced arrest of translation, KCC2 function persists unperturbed for at least 4 hours and hence that the cessation of mRNA translation cannot rapidly induce downregulation of KCC2-mediated Cl- extrusion. This finding precludes the use of protein synthesis inhibitors for rapid modulation of KCC2 function. Indirectly, the results presented here imply that the levels of KCC2 under pathophysiological conditions are primarily determined by the degradation rate and not by de novo synthesis.

Poor quality of sleep and the following health problems affecting daily life are in many cases caused by cognitive and physiological arousal resulted from a stressful event. Such stress detrimental to sleep may originate from psychosocial factors such as feelings of shame and social rejection. Our goal was to elucidate the impact of acute psychosocial stress occurring before bedtime on sleep macrostructure and the early night non-rapid eye movement sleep (NREMS). In addition, virtual reality solutions are emerging as options to simulate social threats in laboratory environments. We studied whether a virtual reality variation of a public speaking scenario was sufficient in producing a physiological stress response evident in heart rate variability (HRV) parameters. We compared two experimental groups of healthy young adults (n=34), which differed in the scenario completed within the virtual reality. The stress condition involved a public speaking simulation in front of an attentive virtual audience whereas the control condition involved listening to a neutral presentation in the same but empty virtual seminar room. The participants’ physiological responses were measured with a HRV monitor for 38 hours and the quality of sleep during the laboratory night following stress induction with electroencephalography (EEG). The examined early sleep period was divided into two separate cycles of NREMS, whose results were juxtaposed. For analysing frequency band activity during sleep, we processed the data from EEG with Fourier transformation to yield power spectral density values i.e. frequency activity values. Comparing the two conditions, we observed a distinct effect of stress both during the virtual public speaking scenario and in the subsequent early sleep in the participants from the stress group. We found a significant increase in heart rate and rising fluctuations in the LF/HF (HRV power spectrum high frequency/low frequency) ratio around the stress task period contrasting the results of the control condition, reflecting increased sympathetic tone in the stress group. In the following night, the percentage of stage N3 sleep significantly increased at the cost of N2 sleep during the first NREMS cycle in the stress condition, but this effect resolved in the second NREMS cycle where group differences were absent. As a key finding, the stress group exhibited higher beta frequency activity in proportion to delta activity throughout both cycles and sleep stages. This effect was significantly magnified in N3 sleep where the delta/beta activity ratio decreased in the stress group from cycle 1 to 2, indicating worsening quality of sleep as the night progressed. We reflected our results through a homeostatic point of view, where the increased high frequency beta activity at sleep onset and early sleep in the stress group might explain their increased N3 sleep duration in the first NREMS cycle. A stronger affinity for the important N3 sleep may be a sleep protective mechanism to counter the stress induced abnormally high frequency EEG activity at sleep onset and early sleep to ensure the restorative benefits of slow-wave activity.

Ischemic heart failure is the leading cause of death in the world. The disease is caused by coronary heart disease, in which the narrowed coronary arteries limit oxygen- and nutrient-rich blood from reaching the myocardial tissue. Obstructed arterial blood flow can cause myocardial necrosis and scarring. Scar tissue is non-contractile and poorly elastic. It can thus compromise the pumping capacity of the heart. Current medical and interventional therapies have only very limited efficacy to reduce myocardial scarring. Preclinical and clinical research efforts are underway to generate myocardial scar-reducing and regenerative therapies. In the field of cardiac cellular therapies, the delivery of cells has conventionally been based on intramyocardial injections. However, epicardial patches have been demonstrated to reduce scarring and promote myocardial healing. In addition to merely being a carrier or cover for the cellular transplant, the biomembrane of the patch can also be considered as an active element for the patch’s therapeutic activity. Thus, the properties of the biomembrane can have a major impact on both the cellular and the therapeutic tissue response. The aim of this Master's thesis was to build a standardized test set up to study the properties of the biomembrane. Biomembrane permeability to small (glucose, lactate) molecules and different size proteins was investigated. In addition, the set up was modified to enable the investigation of biomembrane properties on the survival of the grafted cells. Finally, the test set up was evaluated by studying the properties of ProxiCorTM, the biomembrane currently used together with autologous atrial micrografts (AAMs) in epicardial patch. As a result, the set up was successfully constructed and characterized. The ProxiCorTM membrane demonstrated permeability to both small molecules and proteins, and a stable pH was maintained across the membrane. ProxiCorTM enabled traverse serum-induced proliferation of cells compared to the control impermeable membrane. Taken together, these results prove the functionality of the test set up and thus support its further development.

Welander Distal Myopathy (WDM) is caused by the p.E384K mutation in the TIA1 gene. The mutation supposedly causes the disease by a gain-of-function mechanism related to the formation of stress granules (Hackman et al. 2013). Also environmental factors have been proposed to affect the development of the disease: an increased number of stress granules has been observed in cells treated with cold shock compared to cells kept in 37 °C (Hofmann et al. 2012). When patients with WDM-like symptoms have been screened for changes in TIA1, an p.N357S-change has been found enriched in these patients. The p.N357S-change has earlier been reported as a polymorphism. The change in question is located in the same prion-like domain in exon 5, in which the p.E384K-mutation also lies. Therefore, the p.N357S-change could affect the predisposition to aggregation. The pro gradu project is divided into two parts: • The effect of the p.N357S polymorphism on stress granule formation in arsenite and possibly other stress treated cells • The effect of cold shock on stress granule formation on wild type and p.E384K TIA1 The results indicate, that the p.N357S change in TIA1 causes a change in the translated protein’s behavior. Similarly to the p.E384K change, the p.N357S change also induces an increased amount of stress granules in arsenite treated cells. However, the results also show that the stress granules recover faster in fluorescence recovery after photobleaching (FRAP) studies p.N357S transfected cells as compared to TIA1 p.E384K and wild type transfected cells. The cold shock experiment indicates that there is a difference in the stress granule formation between cells transfected with p.E384K and wild type TIA1. This supports previously published results of the effect of the p.E384K change on the stress response and stress granule formation, and also the use of cold shock as a stress inducing treatment. Used methods: PCR, transformation, DNA-extraction, cell culture, transfection, induction of stress granule formation by arsenite treatment and cold shock. The cells are cultivated on well plates, imaged and the data is analyzed with an automatized high content image analysis method (the CellInsight-platform). p.N357S cells were also analyzed with FRAP.

Early life stress (ELS) has been associated with the development of psychiatric disorders such as anxiety and depression later in life. The central hypothesis is that these disorders are caused by a malfunctioning of the serotonin system and serotonin (5-HT) produced in the dorsal raphe nucleus (DRN). The DRN is anatomically connected to the medial prefrontal cortex (mPFC), especially to the infra- and prelimbic cortex, where 5-HT modulates behaviors such as impulsivity and cognitive flexibility. The DRN and mPFC mediate with low-frequency network oscillations, which are indicative of the state of the network and its funtional connectivity, as disturbances in these network oscillations have been connected to neuropsychiatric disorders. The aim of the thesis is to investigate whether and how ELS can influence the local field potential (LFP) activity of the mPFC and DRN and the functional connectivity of the DRN and mPFC. This is researched by characterizing and comparing the LFP activity recorded in the DRN, where 5-HTergic neurons are located, and in layer 5 of the infralimbic area of the mPFC. To accomplish these aims, a well-established animal model of early-life stress, the limited bedding and nesting model (LBN), was used. The model causes fragmented maternal care due to the stress of the dam, which in turn leads to the stress of the pups. Simultaneous multi-site recordings of LFP and multi-unit activity (MUA) within DRN and mPFC were performed in vivo during postnatal days (PND) 10-11 from control and LBN pups to characterize the network activity of these two brain areas and then investigate possible changes in their functional connectivity. The efficacy of the LBN model was determined by the observed decreased weight gain of LBN animals compared to controls. From the data, the LFP activity of the DRN and mPFC were characterized. The activity was characterized as power spectrum, wavelet spectrum, and MUA with DRN showing discontinuous activity with low signal-to-noise ratio and low frequency theta oscillations (4-12 Hz), while mPFC showed almost continuous activity with higher signal-to-noise ratio and developing gamma oscillations (20-50 Hz). The power of LFP signal of the areas was not found to be affected by ELS. To investigate if the coupling by synchrony between DRN and mPFC networks is altered by ELS, I analyzed wavelet coherence by computing coherence values between LFP signals in DRN and mPFC in a control and ELS for frequencies from 1 to 50Hz. The functional connectivity was affected by ELS. Statistically significant changes were observed in wavelet coherence in the lower frequencies of 1-2.8 Hz between the control and LBN treatment, suggesting impaired synchronization between DRN and mPFC at 1-2.8Hz frequency range immediately after ELS exposure at PND 10-11 mice. Caveats of the study were low signal-to-noise ratio of the recordings, the small group size of LBN animals (n=5) as well as the uneven sex distribution (male n=11, female n=3) which prevented the sex-based comparison of the effects of ELS. The thesis examines postnatal LFP brain activity in the DRN and mPFC and the functional connectivity between these brain areas. The results of the thesis show that ELS exposure is able to influence the functional connectivity of these two brain regions. The results support previous findings, which have found alterations in the functional connectivity of the neural networks underlying neuropsychiatric disorders in adulthood. The findings of this thesis suggest that ELS could affect the functional connectivity of a developing network and thus increase the risk of the development of neuropsychiatric disorders. Further studies are needed with larger group size, even gender balance, and better signal-to-noise ratio of recordings.

Biodiversity has been declining over the last decades due to land-use changes. Habitat loss and fragmentation are considered the key drivers of biodiversity loss. While evidence indicates that habitat loss has a negative impact on biodiversity, the effect of fragmentation itself is debated. The Habitat Amount Hypothesis proposes that fragmentation per se –more discontinuous habitat distribution but no difference in habitat amount- has no effect or even a positive effect on biodiversity. Studies have looked at its effect on species richness, but its impact on intraspecific genetic diversity is still unknown. In this thesis, I aimed to test this hypothesis using the Glanville fritillary butterfly, which has been extensively monitored in the Åland islands since 1990, as a model system. I studied how fragmentation per se affects genetic diversity of the focal populations, while controlling for the habitat amount within the landscape in the Åland islands. For this, I used an existing dataset for which larvae were sampled during two consecutive years and genotyped for 40 neutral SNPs, and calculated four genetic diversity indices in over 200 habitat patches with relatively high population abundance. Following Martin et al. (2021) protocol, I first defined the scale of effect. Then, to reduce the correlation between total habitat amount and number of habitat fragments, I split my dataset in two sub-datasets. Finally, I assessed for each sub-dataset the differences in genetic diversity between landscapes with different level of fragmentation and total habitat amount. The number of fragments had a neutral effect on the genetic diversity, supporting the habitat amount hypothesis. Moreover, the results suggest that all habitat fragments, even the small ones, are contributing to maintain the genetic diversity of the focal population. The species’ ecology, population dynamics and specific adaptations to a fragmented landscape might have led the Glanville fritillary butterfly to be especially resistant to fragmentation.

An increasing number of people are diagnosed with depression. One possible reason for the development of depression is faulty wiring and information processing in certain neural networks (network hypothesis) in the central nervous system. It has been shown that antidepressant drugs (ADs) can induce a juvenile-like plasticity state in the brain (iPlasticity) comparable to the plastic state of critical periods during development. iPlasticity enables the rewiring of neuronal networks in combination with environmental stimuli. At the molecular level, the binding of brain-derived neurotrophic factor (BDNF) to its high-affinity receptor tropomyosin kinase receptor B (TRKB) leads to TRKB dimerization and activation, triggering a downstream signalling cascade promoting brain plasticity. Activation of the TRKB signalling cascade is triggered by neuronal activity as well as AD treatment. Recent findings demonstrate that classical as well as rapid-onset ADs bind directly to the transmembrane domain of TRKB, leading to increased translocation of intracellularly stored TRKB to the plasma membrane and enhanced BDNF binding. Cholesterol, a sterol lipid known to regulate TRKB signalling, has been found to ensure optimal TRKB-BDNF signalling by changing the TRKB dimers’ relative orientation when altering the membrane thickness. A point mutation of TRKB tyrosine 433 to phenylalanine (TRKB.Y433F) has been found to hinder TRKB dimerization. Molecular dynamic simulations reveal that other membrane lipids are likely to participate in AD binding to TRKB. The aim of this thesis was to investigate whether lipid and drug compound treatments affect TRKB dimerization in Neuro2A cells expressing TRKB. Furthermore, we assessed whether the Y433F mutation modulates TRKB dimerization in such treatments. Protein fragment complementation assay (PCA) was used as in vitro protein-protein interaction assay to quantify dimerization of overexpressed TRKB carrying two split luciferase reporter proteins. Additionally, to avoid variability caused by transient transfection and be able to test large compound libraries, the establishment of a stably TRKB-expressing N2A cell line was initiated. The results show that lipid compounds, such as Allopregnanolone, as well as ADs, such as Imipramine and (2R,6R)-Hydroxynorketamine, increased TRKB dimerization in vitro in a dose-dependent manner within 40 minutes. The increase was more pronounced in the TRKB WT-expressing cells. This indicates that the compounds tested here may be directly interacting with TRKB, facilitating dimerization. Moreover, data seem to confirm previous research on the less effective TRKB.Y433F mutation. While stable expression of TRKB carrying one of the luciferase reporter proteins was successfully achieved in a monoclonal cell line, the amount of protein expressed seems to require further optimization before utilising it for PCA. In conclusion, lipid and AD treatments can induce an increase in TRKB dimerization in a dose-dependent fashion. Further investigations are needed to determine where the compounds bind and by which mechanisms they exert their effects on TRKB. Furthermore, the work on the stable cell line will be completed to avoid variability of transient transfection in the future.

Depression and anxiety are the two most common mental disorders worldwide, and especially common among women of reproductive age. Hence, they are also common problems among pregnant women. Maternal depression and anxiety not only compromise the mother’s quality of life during pregnancy but increase the risk of perinatal complications and poor child neurodevelopment. The biological mechanisms that underpin this transmission remain largely unknown. The placenta, a transient fetal organ functioning as an interface between the mother and the fetus, plays a pivotal role, as the placenta transmits all environmental cues to the fetus. This thesis aims to investigate differential gene expression in the first-trimester chorionic villi and birth placenta samples from women with depression and/or anxiety and healthy controls. Samples are collected and processed as a part of the InTraUterine sampling in early pregnancy (ITU) study and both chorionic villus samples (CVS) collected during the early pregnancy and delivery placenta samples were studied. I defined three different phenotypes based on (i) maternal depression and anxiety disorder diagnosis, (ii) antidepressant and anxiolytic medication purchases, or (iii) self-reported depressive and anxiety symptoms during pregnancy. Genome-wide analysis of differential gene expression was conducted with DESeq2 R-package and further gene set enrichment analysis was performed with a web-based platform FUMA. When comparing mothers with depressive and anxiety symptoms to asymptotic controls, but not those with or without diagnoses or medication purchases, I found 478 genes differentially expressed. In the enrichment analysis these genes related to immune response and inflammation, such as leukocyte and T cell activation, defense response, and cytokine production. Together these results indicate that maternal depressive and anxiety symptoms during pregnancy change the immune system functions in the placenta which may partly explain the adverse effects of maternal depression and anxiety on the developing fetus. These findings may afford a target for timely targeted interventions to prevent perinatal complications and the transmission of maternal depression and anxiety to the next generation.

Microplastics (MPs) are widespread environmental pollutants that have been detected in virtually all environmental compartments. Despite this, research has mainly focused on the impacts of microplastic on shorelines and at sea. The effects of MPs on terrestrial ecosystems has been sparsely investigated, and there are only a few studies on direct effects on terrestrial plants. Although plastic polymers are considered inert and non-hazardous, toxic additives are often added to the polymers during manufacture which may leach out into the environment, displaying ecotoxic effects. In this work, the effects of microplastic particles and microplastic leachate on the germination and growth of Lolium multiflorum (Italian ryegrass) was investigated. High density polyethylene (HDPE), which is one of the plastic polymers with the largest annual production, was chosen as the plastic material for investigation. New MPs, artificially aged MPs, MPs from the Lahti region, and MPs from Port Elizabet, South Africa was used in parallel to compare the effects of ageing and regional environmental factors on the ecotoxicity of MPs. The total germination percentage, mean germination rate, synchronization index, germination index, and time to 50% germination was investigated, as well as the root lengths, shoot lengths, root/shoot ratio, and fresh weights of the seedlings. The results showed that exposure to new and Lahti MPs and leachates severely inhibited the extent and speed of the germination of L. multiflorum, whereas all categories of MPs and leachates inhibited the growth to some extent. Most severe inhibition in germination and growth was seen for the new MP and new leachate, followed by Lahti MP and Lahti leachate. The root growth, shoot growth, and plant biomass were also severely reduced for these exposure media. For the aged and Port Elizabeth material, there were slight but significant (p < 0.05) inhibition in root lengths and fresh weights, but no significant inhibition in the germination parameters. These findings indicate that ageing severely reduces the ecotoxic effects of MPs, and that regional environmental factors affect the ecotoxicity of MPs. Microplastics from Port Elizabeth were significantly less toxic to L. multiflorum than MPs from the Lahti region, possibly due to the warmer climate in South Africa. Another explanation could be that the plastic material collected in Port Elizabeth wast older than the one from Lahti. There was little to no difference in germination and growth between seeds exposed to MPs or leachates of the same origin, indicating that it is the substances leaching out of the MPs that are responsible for their ecotoxicity.