Browsing by Subject "autophagy"

Autophagy is a cellular recycling and quality control process that eliminates cellular material in a non-selective or selective fashion. Macroautophagy is non-selective, and degrades macromolecules or damaged organelles to sustain cellular homeostasis. The selective autophagy of dysfunctional or excess mitochondria is known as mitophagy. The clinical importance of functional degradation is exemplified by the lysosomal storage disorders (LSDs), where lysosomal hydrolytic enzymes are absent or dysfunctional. Previous investigations of a rare infantile LSD indicated a change in autophagy and decreased mitochondrial content. The aim of this MSc thesis was to quantitatively compare macroautophagy and mitophagy in a cellular model of this rare LSD, by generating fluorescent macroautophagy and mitophagy reporter-expressing cell lines from patient material. Fibroblasts derived from patients diagnosed with a rare infantile LSD were transduced with lentiviruses carrying either mCherry-GFP-LC3 or mito-QC reporters, for the microscopic analysis of autophagy and mitophagy, respectively. I also monitored autophagic flux by traditional biochemistry in untreated and starved cells, in the presence or absence of lysosomal inhibitors (bafilomycin A1). Basal and iron-depletion induced mitophagy was profiled using confocal microscopy, quantitative cell biology and biochemistry. My findings suggest differential autophagic turnover in LSD patient-derived fibroblasts, with a marked accumulation of non-acidified autophagic structures. Basal mitophagy was elevated in two out of three LSD patient cell lines compared to unaffected controls. LSD patient cells exhibited altered mitochondrial content and network architecture compared to controls. These phenotypes were accompanied by distinct changes in the endo-lysosomal system and increased cell size. The patient-derived cells exhibit a profound accumulation of lysosomes and autophagic structures. My findings are in accordance with previous research in the field, suggesting perturbed macroautophagy in this rare LSD. The observations of altered mitochondrial homeostasis in this LSD provide a basis for future investigation. The reporter-expressing cells, generated as part of this MSc thesis project, will enable future studies of mechanisms that underlie phenotypic changes, and will complement essential in vivo work in this area.

Aging is the progressive accumulation of cellular dysfunction, stress and inflammation. The mitochondrial network plays a central role in the maintenance of cellular homeostasis, with a growing body of evidence assigning dysfunctional regulation of this network as cause or effect of age-related diseases including metabolic disorders, neuropathies, various forms of cancer and neurodegenerative diseases. Neuronal sensitivity to changes in energy supply and metabolic homeostasis make neurons especially susceptible to alterations in the mitochondrial network. Mitophagy, a specified form of autophagy, is the selective degradation and quality control mechanism of mitochondria by engulfment and fusion with acidic endolysosomal compartments of the cell. Mitophagy has been extensively characterised in cultured cells and short-lived model organisms. However, our understanding of physiological mitophagy during mammalian aging is unknown. This study utilizes mito-QC mitophagy reporter mice that enable in vivo detection and monitoring of mitochondrial turnover due to the distinct physicochemical properties of the tandem GFP-mCherry reporter. Using cohort groups of young and aged reporter mice, age-dependent alterations of mitophagy were quantified in the cerebellum and the outer nuclear layer (ONL) of the retina. Specific autophagy and mitophagy markers were used to assess the longitudinal alterations in the mitophagic landscape. Images of fixed brain tissue sections were attained by high-speed spinning disc confocal microscopy for the quantitative and histological analysis. This study characterises the longitudinal alterations of mitophagy in distinct regions of the central nervous system (CNS) of mitophagy reporter mice, demonstrating tissue-specific alterations in mitochondrial turnover throughout physiological time. Åldrande kan definieras som den successiva ackumuleringen av cellulär dysfunktion, stress och inflammation. I upprätthållandet av cellens funktioner och homeostas har det mitokondriella nätverket en central roll. Omfattande forskning visar att åldersrelaterade sjukdomar såsom neuropati, ämnesomsättningssjukdomar, olika cancerformer samt neurodegenerativa sjukdomar föranleds av mitokondriell dysfunktion. Neuroner är beroende av oavbruten energitillförsel och upprätthållen metabolisk homeostas, vilket gör dem speciellt mottagliga för förändringar i det mitokondriella nätverket. Mitofagi är en selektiv form av autofagi som degenererar och kvalitetskontrollerar mitokondrier genom att leverera dem till lysosomer där de bryts ned av hydrolytiska enzymer. Den aktuella kunskapen inom regleringen av och mekanismerna bakom mitofagi baserar sig på gedigen forskning av kortlivade organismer och cellkulturer. Däremot är vår kunskap inom åldrandets inverkan på mitofagi i däggdjur begränsad. I denna studie används musmodellen mito-QC vars rapportörgen består av ett binärt GFP-mCherry-komplex som besitter olika fysikaliska och kemikaliska egenskaper, vilket möjliggör upptäckt och analys av mitofagi in vivo. En kvantitativ jämförelse av mitofagi i unga och åldrande möss genomfördes i vävnadssnitt av cerebellum och av det yttre nukleära lagret av retinan. Specifika autofagi- och mitofagimarkörer användes för att utvärdera de longitudinella förändringarna i mitokondriell degenerering. Bilder för kvantitativ och histologisk analys erhölls med höghastighets spinning-disk-konfokalmikroskop. Denna forskning karaktäriserar de longitudinella förändringarna av mitofagi i definierade regioner av det centrala nervsystemet i musmodellen mito-QC och presenterar vävnadsspecifika förändringar i degenereringen av mitokondrier under åldrandets framskridande.

Autophagy is a pathway for cells to degrade intracellular components that are no longer needed or are detrimental for the cells. It is essential for cell homeostasis and survival and has been related to various diseases and pathophysiology. Autophagy is a complex process and there are still several unclear und unknown aspects to it. Regulation of autophagy is essential to prevent unwanted and escess activation, and several pathways and molecules, both stimulatory and inhibitory, are included. Different signaling pathways are sensitive to a variety of environmental clues. Two main autophagy pathways are mTOR-dependent pathway and mTOR-independent pathway. Induction of autophagy in the latter pathway is dependent on the interaction of Bcl-2 and Beclin 1. Prolyl oligopeptidase (PREP) is a peptidase enzyme that has several substrates. PREP-inhibition by KYP-2047 can reduce aggregation of α-synuclein in two ways: by increasing rate of autophagy and by decreasing dimerization. The aim of this study was to find out how PREP affects the interaction between Bcl-2 and Beclin 1 and how this affects autophagy. Based on previous studies, PREP-inhibition seems to increase the amount of Beclin 1 and to affect the phosphorylation of Bcl-2 and Beclin 1, leading to dissociation of the complex. Hypothesis was to see differences in colocalization of Bcl-2 and Beclin 1 in cells treated with different PREP-modifications and for PREP-inhibition to decrease the colocalization. Human embryonic kidney cells 293 (HEK-293) and hPREP knockout cell line created from them by using CRISPR/Cas9-silencing were used in the experiments. Two experiments were performed on regular HEK-cells: inhibitor experiment with KYP-2047 (1 or 10 µM) and overexpression experiment (transfection with either active or inactive hPREP plasmid). After immunofluorescence staining, cells were analysed with confocal microscope and colocation analysis of Bcl-2 and Beclin 1 was performed. The intensity of Beclin 1 in the nuclei was stronger than in other parts of the cell in all samples, which could indicate a stronger activity of its nuclear tasks compared to autophagy. However, the antibody used for immunofluorescence has most likely caused this staining pattern. Based on previous knowledge, it was expected to see differences in colocalization of Bcl-2 and Beclin 1 in cells treated with different PREP-modifications. However, there were no significant differences in colocalization of Beclin 1 and Bcl-2 in any of the experiments but it was nearly 100 percent in all treatments. Since rate of autophagy in cells was not detected, it is impossible to determine, if there were changes in autophagy that were not reflected as changes in colocalization of these two proteins. It is possible that even a small change in colocalization can affect the rate of autophagy or there might be subpopulations where the interaction is interrupted and these changes are so small that they are not detectable with the methods used in this experiment. Both Bcl-2 and Beclin 1 also have functions not related to autophagy, which could be one reason behind the results gained in this study.

In this master’s thesis project, I studied the association of lipid molecules phosphatidylinositol 4-phosphate (PI4P) and phosphatidylinositol 3-phosphate (PI3P) with autophagy in neurons. One of the aims of the study is to determine the level of basal autophagy in primary hippocampal neurons and to come up with a protocol for autophagosome observation without forcing radical changes in cell culture conditions. Other mammalian cells have extremely weak basal autophagy, but they increase it significantly in response to starvation, for example. However, neurons are extremely sensitive to any changes in their surroundings. They change their morphology, behaviour and biochemical properties, and often they simply do not survive. Therefore, the goal is a protocol for successful autophagy observation with minimal external influence. Despite the debate around basal autophagy in neurons, I observed high levels of basal autophagy in neuronal cells incubated in media without supplements. Also, my observations revealed that the inhibition of the last step of autophagosome processing with Bafilomycin A1, was enough to cause the massive accumulation of large autophagosomes. Results demonstrated that primary hippocampal neurons exhibit high levels of basal autophagy, suggesting that on the contrary to other mammalian cells neurons might not have enough potential to increase autophagy when it is induced pharmacologically or by stressful conditions. This would explain why autophagy induction is often claimed to be ineffective for neuronal cultures. The main goal is to observe and compare PI4P presence on autophagosomes in normal conditions and when autophagosome:lysosome fusion is inhibited with Bafilomycin A1. The side goal is to observe PI3P presence on autophagosomes as well. I transfected primary hippocampal neurons with fluorescent probes for PI4P or PI3P as well as for autophagosome-related protein LC3. Localization data was collected with live-cell imaging on a confocal microscope. As expected, PI3P was not detected on autophagosomes located in soma. It is involved in the initial vesicle biogenesis in distal axons but not in later events taking place closer to the cell body. PI4P showed high degree of colocalization with LC3, indicating PI4P presence on autophagosomes, but only when the fusion was presumably inhibited by Bafilomycin A1. These results suggest that PI4P appears on autophagosomes either as a result of compensatory pathway, where autophagosomes fuse with late endosomes instead of lysosomes; or as a molecule normally involved in autophagosome:lysosome fusion. Literature supports the latter explanation, but it cannot be confirmed without further research. These results give an insight into PI4P role in neuronal autophagy and might be relevant for the future research of autophagy disruption and aggregate accumulation in neuronal diseases as a consequence of abnormal lipid signalling, lipid metabolism and transport.