Browsing by discipline "fysiologia ja neurotiede"

The arylhydrocarbon receptor (AHR) is known for its xenobiotic role. In the last decades we have realized it has an important role even in normal physiology. Earlier studies have shown different circadian behavior in mice and rats when AHR is activated with the environmental toxoid TCDD. Also, AHR knock-out (AHRKO) mice have shown to adapt quicker to new lighting conditions. The aim of this study was to chart AHRs role on the circadian behavior in rats, by comparing daily eating and drinking habits under normal lighting condition for 7 days and for 7 days after a 12-hour light shift. Tissue samples to be used in continuing studies were taken after the 14 days long follow up. These studies will chart how the circadian timekeeping genes are expressed in the central (suprachiasmatic nucleus) and periphery (liver) cells in AHRKO rats after an adaptation to phase shift compared to wild type rats. This way the study will provide information that will help us understand the role of AHR in different species regarding behavior and in continuing studies gene expression. In our study no differences in drinking and eating activity could be seen between AHRKO and wild type rats. Both groups adapted to new lighting conditions equally fast.

APECED (Autoimmune-Polyendocrinopathy-Candidiasis-Ectodermal-Dystrophy) is a severe, multiorgan autoimmune disease caused by mutations in the AIRE (autoimmune regulator) gene. APECED is a rare disease, however in Finland the frequency is significantly high (1:25 000) and APECED belongs to the ‘Finnish Disease Heritage’. The most common mutation worldwide is the so-called Finn-major mutation R257X that results in a truncation of the AIRE protein, which disrupts the indispensable functions of AIRE. Immune reactions towards body’s own components are typically prevented with various central and peripheral immune tolerance mechanisms. AIRE is essential for the proper development of central and peripheral tolerance and the absence of functional AIRE leads to a loss of immune tolerance and various autoimmune manifestations. Recent studies have suggested that AIRE also has functions in stem cells and actively contributes to the regulation network of pluripotency. Currently, the development of induced pluripotent stem cell (iPSC) technology has opened opportunities for precision medicine and for defining the cure for genetic diseases, such as APECED. The ultimate objective of our research group is to examine whether APECED could be cured via autologous, gene-corrected cell transplants with the use of induced pluripotent stem cells (iPSCs). As a requirement for such later therapeutic use and iPSC differentiation, the APECED patient-derived iPS cells needed to be characterized in detail. To assess, whether AIRE R257X mutation, present in APECED patients’ iPSCs, would cause defects in their stemness properties, the expression of AIRE and classical stem cell markers were examined with qPCR and immunocytochemistry and compared to healthy control iPSCs. The iPSC cells were also treated with spontaneous differentiation -inducing dimethyl sulfoxide (DMSO) to study, whether AIRE R257X mutation would affect the spontaneous differentiation of iPS cells. To further investigate the stemness and early developmental phase properties of APECED patient derived iPSCs, self-aggregated embryoid bodies (EBs) were generated and cultured. Immunocytochemistry was used to examine whether APECED EBs differ in stemness, proliferation or apoptosis from healthy individual’s EBs. The comparative Ct method (ΔΔCt) i.e. fold change revealed that APECED iPSC clones expressed all the classical stem cell markers similarly to healthy control iPSCs. DMSO treatment reduced the expression of stem cell markers in both healthy and APECED-derived iPSCs. The immunostaining results of iPSCs were consistent with the qPCR analysis. The overall growth properties as well as the immunocytochemical assays of stemness, proliferation and apoptosis markers did not show any significant difference between the APECED patient and healthy control derived EBs. Together the results indicate that the R257X mutation of the APECED patients does not affect stem cell properties such as stem cell marker expression and colony or the EB formation of the iPSCs. The results are contrary to previous studies in mice demonstrating the interspecific difference between mouse and human and denoting the importance of human samples completing the studies with animal models. As the APECED patient derived iPSCs did not exhibit any defects in their stemness properties, the later iPS differentiation and therapeutic use could be accomplished without hindrance. However, future work is still needed, as the small sample size in this preliminary test might introduce some biases to the results and hindered a relevant statistical analysis. Nevertheless, this thesis project was the first time APECED patient-derived iPSCs were characterized and has provided new information about the effect of AIRE mutation in APECED patient derived iPSCs.

Reptiles have long been studied in search of the mechanisms behind neuronal regeneration. This thesis delves into the regenerative areas of two emerging model species to the field of regenerative research: Pogona vitticeps (bearded dragon) and Pantherophis guttatus (corn snake). This fluorescent immunohistochemical study maps out and compares the constitutive proliferative zones in these two species to better define the focus of future comparative neurodegenerative experiments. A BrdU pulse chase experiment in conjunction with PCNA reveals proliferative zones in the lateral ventricular ependyma of both species. Stem cell niches were found in the ependymal lining adjacent to the medial cortex and dorsal ventricular ridge in both species, however, the nucleus sphericus ependyma was an active proliferative zone only in Pantherophis. Imaging of further markers in this study support the findings of the pulse chase experiment. High levels of the stem cell marker Sox2 was found in lateral ventricular ependymal cells in both species. The glial marker GFAP reveals a highly ordered array of radial glia in the cortical areas of Pogona, which is significantly reduced or absent in Pantherophis. And lastly the neuronal marker HU was found in the same cells that were BrdU positive and had migrated a short distance from the proliferative zones, which shows that the proliferative areas in the lateral ventricular lining do indeed produce neurons. The BrdU and PCNA marked cells were quantified in both species, and a brief comparison between the species showed that Pogona had a significantly higher number and concentration of proliferative cells in the proliferative zones than Pantherophis. Scattered BrdU positive cells that were neither neuronal nor positive for any other marker were also found scattered throughout the parenchyma of Pogona, and these cells remain uncharacterized. Differences between these two species are not surprising, as lizards are known to have better regenerative capabilities than snakes, however, more comparative research between these species is needed to gain further insight into the mechanisms behind their contrasting regenerative capabilities.

Hypothyroidism affected 337 370 people in Finland in 2019. The hypothalamus-pituitary negative feedback loop is used in the diagnostics of hypothyroidism. TSH, a pituitary hormone, is the most used diagnostic tool with the free thyroxine (T4) in a supporting role. L-T4 has been the main treatment option, since the discovery of peripheral deiodination. Biochemical and clinical euthyroidism is the aim of L-T4 therapy. There are no nationwide official treatment guidelines for hypothyroidism in Finland. The Finnish Endocrine Society has published their recommended guidelines in 2019. Studies have shown that 5–15 % of levothyroxine treated patients continue to report symptoms when they are biochemically euthyroid. The symptoms consist of typical symptoms of hypothyroidism: fatigue, cognitive symptoms, depression, anxiety and weight gain. The molecular basis of the symptoms is not yet known. These symptoms have notbeen studied in Finnish population. The aim of this study was to find out what symptoms levothyroxine treated patients report on Finnish social media support groups and view the current treatment of hypothyroidism and guidelines of treatment. This study was conducted by surveying patient-reported information from social media hypothyroidism related support groups. The posts were divided into two groups: hypothyreotic and athyreotic. The biochemical data and symptoms were collected from 137 posts in the athyreotic group and 191 in the hypothyreotic group. Only posts with TSH under or within the refence range and free T4 within the reference range wereincluded in the study. The results show that patients reported symptoms in 74 % of the posts viewed. 81 % of patients reported symptoms in the hypothyroidism group and 64.2 % in the athyreotic group. The most reported symptom in both groups was fatigue. Symptoms were reported within the normal TSH range (0.5-4 mU/l) and below the normal range (<0.5 mU/l). In asymptomatic patients the median TSH was 0.38 mU/l in the athyreotic group and 0.54 mU/l in the hypothyreotic group. Free T4 seems to be a little higher in the asymptomatic patients in both groups. 16.6-25 % the patients reported that they had had Free T3 measured. Free T3 seem to be higher in relation to free T4 in the athyreotic group that reported having no symptoms. L-T4 is the recommended treatment modality for hypothyroidism. Other options are synthetic combination treatment with L-T4 + L-T3 and desiccated thyroid extract (DTE).This study supports the view that hypothyroidism patients can have symptoms on levothyroxine treatment

Our hearing perception is based on the ability to discriminate mechanical sound waves and to amplify and transduce them into electrical stimuli.This function is based on the complex cellular organization of the cochlea, the hearing organ. The sensory epithelium in the organ of Corti spirals along the cochlear duct in a tonotopic arrangement: every sound frequency elicits the strongest response at allocation along this duct. Sound stimulus is detected by three rows of outer hair cells (OHCs) which amplify- and tone-discriminate the sound stimulus, and by one row of inner hair cells (IHCs), which transduce the mechanical stimulus into electric impulses. Basal regions of the cochlea detect high- frequency sounds and apical regions detect low- frequency sounds. The complexity and sensitivity of the cochlea is linked with its vulnerability to various traumas. Most kinds of damage to the mammalian hair cells is irreversible, because these cells are not capable of regeneration. Hearing impairment has many etiologies. Common to them is that damage is permanent and no pharmacotherapy is available. Hearing impairment is often a disabling condition and it has vast societal consequences. The number of hearing impaired people is constantly increasing and the WHO has estimated that 10% of the world`s population will suffer from disabling hearing loss in 2050. Mesencephalic astrocyte- derived neurotrophic factor (MANF) is an unconventional, ER-resident protein that promotes ER- homeostasis. It has been associated with cytoprotective functions in many neurodegenerative disease- models and shown to promote recovery after ischemic trauma. MANF expression has been previously found in many cell-types in the cochlea, including OHCs and IHCs. Its deficiency in a mouse model led to upregulation of ER-stress markers and a robust, tonotopic base –to apex gradient loss of outer hair cells and severe hearing loss. This study examines the role of MANF in noise-induced trauma in the hair cells of the cochlea. In a conditionally inactivated (Manf -/- cKO) mouse model in the C57BL/6J – background, where Manf has been inactivated from most of the cochlear cells, I studied, if Manf -deficiency sensitizes the cells to noise-induced cell death in two age-groups. I also examined the basic and noise- induced MANF expression, using two mouse- strains, C57BL/6J and CBA/Ca. I also examined OHC stereociliary bundle morphology to find out if noise induces morphological changes in Manf cKO-mice that differ from noise-exposed C57BL/6j wild type mice. This study found that OHCs have a low MANF- expression, whereas in IHCs the expression is strong. MANF is expressed in a base- to apex gradient in the OHCs of the two mouse-strains examined, in a uniform pattern, that correlates with vulnerability, implicating that low levels of MANF predispose basal OHCs to vulnerability. MANF expression in the IHCs was non-gradiental. Noise did not induce upregulation, as was expected, but instead noise induced downregulation of MANF in the basal region of the OHCs by an unknown mechanism in both mouse-strains.This suggests that noise-induced trauma induces ER dyshomeostasis, possibly independent of ER stress response pathways ,unfold protein response (UPR). This study also demonstrates that MANF deficiency sensitizes the OHCs to noise- induced trauma, resulting in more elevated OHC loss and hearing thresholds. This sensitization is mainly caused by a progressive degenerative changes seen in the OHC stereociliary bundles of Manf cKO-mice, and is associated with more severe noise-induced hearing loss. The results of my study suggest that MANF has an important, yet unknown, protective role in noise-induced trauma in OHCs. These results support the possible role of MANF as a therapeutic agent in a noise-induced trauma.

Kainate receptors (KARs) are glutamate receptors that modulate neurotransmission and neuronal excitability. They assemble from five subunits (GRIK1-5 or GluK1-5) present at both pre- and postsynaptic membranes. KAR function is regulated by neuropilin and tolloid-like (NETO) proteins, which also regulate postsynaptic GRIK2 abundance. Some KAR subunit gene variants associate with psychiatric disorders. Moreover, Grik1, Grik2 and Grik4 knock-out (KO) mice display changes in anxiety- and fear-related behaviours. In previous work, Neto2 KO mice expressed higher fear and impaired fear extinction in the fear conditioning paradigm. We hypothesised that this phenotype could be due to reduced KAR subunit abundance in fear-related brain regions, i.e. ventral hippocampus, amygdala and medial prefrontal cortex (mPFC). We specifically investigated GRIK2/3 and GRIK5 levels in the subcellular synaptosomal (SYN) fraction using western blot. We did not observe any difference between genotypes in any of the brain regions. However, our statistical power may have been insufficient, particularly for amygdala and mPFC. Also, an effect on synaptic KAR subunit abundance might be specific to either pre- or postsynaptic compartment, and thus more difficult to detect in SYN fractions. Alternatively, NETO2 absence may affect KAR actions instead of their subunit levels in fear-related brain regions, which could be examined through electrophysiological recordings. Ultimately, unravelling how a molecular system without NETO2 gives rise to fear behaviour in mice may lead to a better understanding of fear-related disorders in human and to new therapeutic strategies.