Browsing by Subject "toksisuus"
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(2023)Alpha-beta-hydrolase domain containing proteins (ABHD) are involved in lipid metabolism and its regulation in human and animal cells. Approximately 50 of these proteins have been identified and their physiological and pathophysiological functions are still further investigated. ABHD2, ABHD3, ABHD4, ABHD5, ABHD6, ABHD12 and ABHD16 are involved in the metabolism of glycerin esters and phospholipids, in particular lipid mediator 2-arachidonoylglycerol (2-AG) and its metabolites have a significant effect on neuroinflammation via the endocannabinoid system. ABHD12 and ABHD16A were at the center of focus in this thesis as enzymes regulating phosphatidylserine and pro-inflammatory lysophosphatidylserine. In this study, toxicity of five (5) abietane terpene derivatives was tested using mouse E15/16 prenatal cortical neurons, cultured in 96-well plates. There were totally 8 plates cultured in three different batches, 60 cell containing wells per each plate. Wells from each plate were divided into treatment groups of 17, three concentrations of every five compound, control and VEH groups. Those concentrations were 0,1 µM, 1 µM and 10 µM, and for the last two plates 1 µM, 10 µM and 100 µM. Treatment was also separated into three batches like the cell culturing. After treatment, number of living cortical neurons in each treatment groups were counted. For that, cells were treated with immunofluorescent NeuN and DAPI antigens and the fluorescence was imagined with automated microscope. CellProfiler was used to recognize and count the number of living cortical neurons. Immunofluorescent MAP2 antigens were also used but because the shape of MAP2-fluorescing cells, CellProfiler could not recognize them. Intensity of MAP2-fluorescence were measured from those imaged, so the work would not be wasted. One-way ordinary variance analyze ANOVA was carried out for the data to figure out if there were statistically significant results. For compound TAC174, there were several significant results with different concentrations but unfortunately, some results showed signs of toxicity and others improved cell-growth. Some significant results were also found with compounds TAC121, TAC147 and TAD40 showing sings of toxicity, but reliability of those results was questioned. Only one compound, TAC150 was not showing clear toxicity towards mouse cortical neurons, at least with lower concentrations. For conclusion, there were no clear or significant results if these compounds are toxic for cortical neurons. TAC150 showed the least sings of toxicity, therefore it could possibly be considered for further studies in medical field.
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(2019)Heart failure is a disease of major social and economic impact. The disease is most commonly onset by extensive cardiomyocyte death following a myocardial infarction. Five-year mortality of heart failure is higher than some cancers. Loss of cardiac muscle tissue leads to pathological thickening and fibrosis of the left ventricular wall, which eventually further diminish cardiac function. Cardiomyocytes hardly proliferate, which also exacerbates the problem. Several cell signalling pathways are indicated in pathological reprogramming of the heart and the exact significance of these pathways remains to be demonstrated. Treatment strategies based on renewing cardiac muscle, such as direct injection of stem cells into the myocardium, have failed to reach clinically significant effects on heart failure patients. Direct inhibition of pathological cardiac reprogramming by using small molecule modulators remains as an auspicious strategy to treat heart failure. GATA4, or GATA binding protein 4, is a transcription factor expressed mainly in heart, lung, intestine, gonad and liver tissues, which regulates tissue renewal and cell proliferation by controlling protein transcription. GATA4 binds to GATA sequences in DNA with two zinc finger moieties and enables transcription of target genes. Interactions of GATA4 and several other transcription factors are in central role of guiding heart development, hypertrophy and fibrosis. One of these transcription factors is NKX2-5, which synergistically interacts with GATA4. Inhibition of this interaction in rat myocardial infarction model has been shown to protect against development of heart failure. A screening campaign against the transcriptional synergy of GATA4 and NKX2-5 found potent small molecule inhibitors of this interaction, but these compounds are characterised with stem cell toxicity. The aim of the study was to design and synthesise novel derivatives of GATA4-NKX2-5 synergy inhibitor hit molecule with reduced stem cell toxicity. Modifications on the phenyl ring of the hit molecule were designed, which either increase electron density of the ring or possibly alter the torsional angle between the phenyl and isoxazole ring moieties. Activity of the compounds was studied on a luciferase reporter gene system in COS-1 cells and toxicity was analysed on IMR90 human induced pluripotent stem cell line. 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium (MTT) bromide and lactate dehydrogenase (LDH) assays were selected to measure toxicity on stem cells. Stem cell toxicity of several previously synthesised compounds was assayed in parallel with the novel derivatives. Ten novel derivatives were designed, synthesised and assayed. Four of the new compounds, a mono-ortho-methyl, a di-ortho-methyl, a di-meta-methoxy and cyclohexyl derivatives were found to be equipotent inhibitors of reporter gene activity compared to the hit compound. Additionally, the mono-ortho-methyl, di-ortho-methyl and di-meta-methoxy derivatives were less toxic to stem cells than the hit molecule in the MTT assay. Several other derivatives were found to be less toxic, but also non-active in the luciferase assay. None of the studied compounds exhibited notable necrotic toxicity on stem cells, as examined by the LDH assay. According to this study it may be concluded that substituents of the hit molecule phenyl ring may be altered to decrease stem cell toxicity of the compound. Some of the alterations, most notably substituents in the para-position of the phenyl ring and substitution of the phenyl ring with smaller saturated hydrocarbon rings, diminish the activity of the hit compound. Remarkable toleration of ortho-substitution reinforces the hypothesis of phenyl-isoxazole torsional angle significance for toxicity. On the other hand, addition of two methoxy groups to both meta positions most likely lacks any substantial effect on the torsional angle, which implies another mechanism of toxicity avoidance. Activity and improved safety of the novel inhibitors should be confirmed in animal models before any decisive conclusions on the effects of structural modifications on the hit molecule can be made. In addition, other mechanisms of toxicity should be studied with relevant cell-based assays.
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