Global ETD Search

121	Cellular design of heparan sulfate : The NDST enzymes and their regulation Carlsson, Pernilla January 2008 (has links) <p>Heparan sulfate proteoglycans are proteins with long, unbranched heparan sulfate (HS) polysaccharide chains attached to them. They are found on cell surfaces and in basement membranes where they exert their action by interacting with a wide range of enzymes and signaling molecules and are thereby involved in a range of various processes both during embryonic development and in adult physiology.</p><p>A great part of the biological functionality of proteoglycans can be directly related to the polysaccharide part. HS chains display very variable sulfation patterns where highly sulfated regions are responsible for a large part of the biological activity. The biosynthesis of HS is a complex process in which a number of enzymes are involved. Better comprehension of how this process is regulated could reveal clues to how formation of HS sulfation patterns occurs, and thereby how HS functionality is controlled.</p><p>This thesis is focusing on regulation of one of the enzymes responsible for HS sulfation, glucosaminyl N-deacetylase/N-sulfotransferase (NDST), in an attempt to understand these mechanisms better. Different aspects of NDST regulation were studied in three projects:</p><p>I) “Heparin/heparan sulfate biosynthesis: Processive formation of N-sulfated domains”, where the sulfate donor PAPS is shown to influence the manner in which NDST modifies the substrate, affecting the domain structure of the polysaccharide.</p><p>II) “Heparan sulfate biosynthesis: Characterization of an NDST1 splice variant”, where a splice variant of NDST1 which appears to influence NDST1 protein levels and affect HS structure is described.</p><p>III) “Heparan sulfate biosynthesis in zebrafish: Five NDST genes with distinct expression patterns during embryonic development”, in which five zebrafish NDSTs were cloned and shown to be expressed in a temporally and spatially regulated manner.</p> heparan sulfate heparin proteoglycan NDST PAPS Golgi Cell and molecular biology Cell- och molekylärbiologi
122	Chromatin Remodeling by BRG1 and SNF2H : <i>Biochemistry and Function</i> Asp, Patrik January 2004 (has links) <p>Chromatin is a highly dynamic, regulatory component in the process of transcription, repair, recombination and replication. The BRG1 and SNF2H proteins are ATP-dependent chromatin remodeling proteins that modulate chromatin structure to regulate DNA accessibility for DNA-binding proteins involved in these processes. The BRG1 protein is a central ATPase of the SWI/SNF complexes involved in chromatin remodeling associated with regulation of transcription. SWI/SNF complexes are biochemically hetero-geneous but little is known about the unique functional characteristics of the various forms. We have shown that SWI/SNF activity in SW13 cells affects actin filament organization dependent on the RhoA signaling pathway. We have further shown that the biochemical composition of SWI/SNF complexes qualitatively affects the remodeling activity and that the composition of biochemically purified SWI/SNF complexes does not reflect the patterns of chromatin binding of individual subunits. Chromatin binding assays (ChIP) reveal variations among subunits believed to be constitutive, suggesting that the plasticity in SWI/SNF complex composition is greater than suspected. We have also discovered an interaction between BRG1 and the splicing factor Prp8, linking SWI/SNF activity to mRNA processing. We propose a model whereby parts of the biochemical heterogeneity is a result of function and that the local chromatin environment to which the complex is recruited affect SWI/SNF composition.</p><p>We have also isolated the novel B-WICH complex that contains WSTF, SNF2H, the splicing factor SAP155, the RNA helicase II/Guα, the transcription factor Myb-binding protein 1a, the transcription factor/DNA repair protein CSB and the RNA processing factor DEK. The formation of this complex is dependent on active transcription and links chromatin remodeling by SNF2H to RNA processing.</p><p>By linking chromatin remodeling complexes with RNA processing proteins our work has begun to build a bridge between chromatin and RNA, suggesting that factors in chromatin associated assemblies translocate onto the growing nascent RNA.</p> chromatin chromatin remodeling SWI/SNF ISWI BRG1 SNF2H Prp8 RNA transcription Cell and molecular biology Cell- och molekylärbiologi
123	Regulation of RNA Editing : The impact of inosine on the neuronal transcriptome Behm, Mikaela January 2017 (has links) The transcriptome of the mammalian brain is extensively modified by adenosine to inosine (A-to-I) nucleotide conversion by two adenosine deaminases (ADAR1 and ADAR2). As adenosine and inosine have different base pairing properties, A-to-I RNA editing shapes the functional output of both coding and non-coding RNAs (ncRNAs) in the brain. The aim of this thesis was to identify editing events in small regulatory ncRNAs (miRNAs) and to determine their temporal and spatial editing status in the developing and adult mouse brain. To do this, we initially analyzed the editing status of miRNAs from different developmental time points of the mouse brain. We detected novel miRNA substrates subjected to A-to-I editing and found a general increase in miRNA editing during brain development, implicating a more stringent control of miRNAs as the brain matures. Most of the edited miRNAs were found to be transcribed as a single long consecutive transcript from a large gene cluster. However, maturation from this primary miRNA (pri-miRNA) transcript into functional forms of miRNAs is regulated individually, and might be influenced by the ADAR proteins in an editing independent matter. We also found that edited miRNAs were highly expressed at the synapse, implicating a role as local regulators of synaptic translation. We further show that the increase in editing during development is explained by a gradual accumulation of the ADAR enzymes in the nucleus. Specifically for ADAR2, we found a developmentally increasing interaction with two factors, importin-α4 and Pin1, that facilitate nuclear localization of the editing enzyme. We have also found that selectively edited stem loops often are flanked by other long stem loop structures that induce editing in cis. This may explain why multiple pri-miRNAs are edited within the same cluster. In conclusion, this thesis has significantly increased the understanding of the dynamics of both editing substrates and enzymes in the developing and mature brain. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 2: Manuscript.</p> RNA editing ADAR miRNA Neuron Brain development Synapse Cell and Molecular Biology Cell- och molekylärbiologi
124	Effects of Free Fatty Acids on Insulin and Glucagon Secretion : – with special emphasis on the role of Free fatty acid receptor 1 Kristinsson, Hjalti January 2017 (has links) Prevalence of type 2 diabetes mellitus (T2DM) is still rising and even so in the juvenile population. Obesity is highly associated with increased risk for developing T2DM. The development has been related to elevated fasting concentrations of the pancreatic islet hormones insulin and glucagon as well as to an increase in plasma lipids that occurs during obesity. Specifically, research has indicated that chronic exposure to high levels of saturated free fatty acids cause dysfunction in islet alpha- and beta-cells. Fatty acids can affect islet cells by various mechanisms one of which is the G-protein coupled receptor FFAR1/GPR40. The role of the receptor in the effects of fatty acids on pancreatic islet-cell function is not clear. The aim of this thesis was to clarify the role of FFAR1 in how fatty acids, and more specifically the long-chain saturated fatty acid palmitate, affect insulin and glucagon secretion. In children and adolescents with obesity elevated fasting levels of insulin and glucagon were positively correlated with lipid parameters. Specifically, plasma triglycerides and free fatty acids were positively correlated with insulin and glucagon at fasting as well as with visceral adipose tissue volume. Elevated glucagon levels at fasting were associated with worsening of glucose tolerance in the same population. In in vitro studies of isolated human islets palmitate stimulated basal insulin and glucagon secretion as well as mitochondrial respiration at fasting glucose levels. The effect was mediated by FFAR1 and fatty acid beta-oxidation. At higher glucose concentrations the receptor was involved in the potentiation of insulin secretion from isolated human islets and insulin-secreting MIN6 cells. Furthermore, we found that the effects of palmitate on hormone secretion were associated with enhanced mitochondrial respiration mediated by FFAR1 Gαq signaling and PKC activity as well as increased intracellular metabolism induced by the fatty acid. When islets were exposed to palmitate for long time periods and in the presence of FFAR1 antagonist, normalized insulin and glucagon secretion during culture and insulin response to glucose after culture were observed. In MIN6 cells chronic palmitate treatment increased mitochondrial uncoupling irrespective of FFAR1 involvement. However, FFAR1 antagonism during palmitate exposure resulted in elevated respiration and reduced apoptosis. In conclusion, children and adolescents with obesity have elevated fasting concentrations of insulin and glucagon that correlate with free fatty acids and fatty acid sources. High glucagon levels are linked to worsening of glucose tolerance in these subjects. In vitro the combination or synergy of FFAR1 activation and intracellular metabolism caused by palmitate is decisive for both the short-term enhancement effects and the negative chronic effects on insulin and glucagon secretion. FFAR1 GPR40 palmitate lipotoxicity islets of Langerhans type 2 diabetes obesity Cell and Molecular Biology Cell- och molekylärbiologi
125	Influence of neuromodulators and mechanical loading on pathological cell and tissue characteristics in tendinosis / Betydelsen av neuromodulatorer och mekanisk belastning för cell- och vävnadsförändringar vid tendinos Fong, Gloria January 2017 (has links) Background: Tendinosis is a painful chronic, degenerative condition characterized by objective changes in the tissue structure of a tendon. Hallmark features in tendinosis tendons include increased number of cells (hypercellularity), extracellular matrix (ECM) degradation and disorganized collagen. The progression of these pathological changes seen in tendinosis is neither well characterized nor fully understood. Studies have suggested that there are biochemical and mechanical elements involved in tendinosis. From a biochemical perspective, studies have shown that the tendon cells, tenocytes, produce a number of neuronal signal substances/neuromodulators, such as substance P (SP) and acetylcholine (ACh), traditionally thought to be confined to the nervous system. Furthermore, it has been shown that the expression of these neuromodulators is elevated in tendinosis tendons as compared to normal healthy tendons. Interestingly, studies on other tissue types have revealed that both SP and ACh can induce tissue changes seen in tendinosis, such as hypercellularity and collagen disorganization. From a mechanical angle, it has been suggested that overload of tendons, including extensive strain on the primary tendon cells (tenocytes), causes the degenerative processes associated with tendinosis. In vivo studies have shown that in overloaded tendons, the presence of neuromodulators is elevated, not least SP, which also precedes the development of the tissue changes seen in tendinosis. This further supports the importance of combining biochemical factors and mechanical factors in the pathogenesis of tendinosis. Hypotheses: In this thesis project, we hypothesize: 1) that neuromodulators, such as SP and ACh when stimulating their preferred receptors, the neurokinin 1 (NK-1 R) and muscarinic receptors (mAChRs), respectively, can cause increased tenocyte proliferation; 2) that the effects of SP and ACh on tenocyte proliferation converge mechanistically via a shared signalling pathway; 3) that mechanical loading of tenocytes results in increased production of SP by the tenocytes; and 4) that SP enhances collagen remodelling by tenocytes via NK-1 R. Model system: In vitro studies offer insight into the function of healthy tendon matrix and the etiology of tendinopathy. Using a cell culture model of human primary tendon cells, highly controlled experiments were performed in this thesis project to study a subset of biological and mechanical parameters that are implicated in tendinosis. The FlexCell® Tension System was used to study the influence of mechanical loading on tenocytes. As well, a collagen gel contraction assay was used to examine the intrinsic ability of tenocytes to reorganise type I collagen matrices under the influence of the neuromodulator SP. Results: The studies showed that exogenous administration of SP and ACh results in increased tenocyte proliferation that is mediated via activation of the ERK1/2 mitogenic pathway when the preferred receptors of SP and ACh, the NK-1 R and mAChRs, respectively, are stimulated. Furthermore, the studies resulted in the novel finding that SP and ACh both converge mechanistically via transforming growth factor (TGF)-β1 and that a negative feedback mechanism is present in which TGF-β1 downregulates the expression of mAChRs and NK-1 R. The studies also showed that SP can increase collagen remodelling and upregulate expression of genes related to tendinosis. Finally, it was established that tenocytes are mechanoresponsive by showing that cyclic mechanical loading increases the expression of SP by human tenocytes. Conclusions: This thesis work concludes that stimulation of NK-1 R and mAChRs results in proliferation of human tenocytes, which both involve the ERK1/2 signalling pathway. It also shows that SP and ACh converge mechanistically via TGF-β1 in their contribution to tenocyte proliferation. The role of hypercellularity in tendinosis tissue is unknown. Possibly, it has different roles at different stages of the disease. The findings also show that SP increases collagen remodelling, suggesting that increased SP not only results in hypercellularity but also contributes to the collagen morphology in tendinosis. substance P acetylcholine transforming growth factor neuromodulators mechanical loading tendinosis Cell and Molecular Biology Cell- och molekylärbiologi
126	Differential gene expression in the heart of hypoxic chicken fetuses (<em>Gallus gallus</em>) Nindorera, Yves January 2009 (has links) <p>Evidence has shown that hypoxic hearts have greater heart/fetus mass ratio. However, it is still unclear if either hyperplasia or hypertrophy causes the relatively increased heart mass. Furthermore, the genes that might be involved in the process have not yet been identified. In the present study, the cardiac transcriptome was analyzed to identify differentially expressed genes related to hypoxia. Eggs were incubated for 15 and 19 days in two different environments, normoxic and hypoxic. Normalized microarray results were analyzed to isolate differentially expressed probes using the Affymetrix chip. Total RNA was also isolated from another set of fetuses incubated in the same conditions and used to perform a qPCR in order to confirm the microarray results. In the four groups (15N, 15H, 19N, 19H), some probes were differentially expressed. From the eggs incubated for 15 days, the microarray revealed five probes that were differentially expressed according to the criteria (p<0.01 and absolute fold change FC>2) in the two programs (PLIER & RMA) used to normalize the data. From the eggs incubated up to 19 days, eight probes were differentially expressed in both programs. No further tests were performed on the 19 days fetuses since there was no significant difference in that group after incubation for the heart/fetus mass ratio. Apolipoprotein-A1, p22, similar to ENS-1 and b2 adrenergic receptor were further tested in qPCR (15 days sample). The differently expressed genes are linked to cell division and should be further studied to identify their function, especially the similar to ENS-1.</p> Cardiac myocytes hypertrophy hypoxia microarray quantitative PCR Biology Biologi Cell and molecular biology Cell- och molekylärbiologi Genetics Genetik
127	Nucleotide-binding Proteins in the Plant Thylakoid Membrane Heurtel Thuswaldner, Sophie January 2006 (has links) <p>Life on Earth is dependent on the oxygen produced through photosynthesis. The thylakoid membrane is the site for the light-driven reactions of photosynthesis, which oxidize water and supply energy in the form of ATP, mainly for carbon fixation. The utilization of ATP in the lumenal space of the thylakoid has not been considered in the past. In the latest years, increasing evidence for nucleotide metabolism in the thylakoid lumen of plant chloroplasts has been presented; ATP transport across the thylakoid membrane, and GTP binding to the PsbO extrinsic subunit of the water-oxidizing photosystem II (PSII) complex.</p><p>In this thesis, various methods for prediction, identification, and characterization of novel plant proteins, are described. Nucleotide-binding motifs and nucleotide-dependent processes are reviewed, and the experimental data is discussed. 1) A thylakoid ATP/ADP carrier (TAAC) in Arabidopsis thaliana was identified and functionally characterized, and 2) the spinach PsbO protein was characterized as a GTPase. The Arabidopsis At5g01500 gene product is predicted as a chloroplast protein and to be homologous to the well-studied mitochondrial ADP/ATP carrier. The putative chloroplast localization was confirmed by transient expression of a TAAC-green fluorescent protein fusion construct. Immuno detection with peptide-targeted antibodies and immunogold electron microscopy showed the thylakoid as the main localization of TAAC, with a minor fraction in the chloroplast envelope. TAAC is readily expressed in etiolated seedlings, and its level remains stable throughout the greening process. Its expression is highest in developing green tissues and in leaves undergoing senescence or abiotic stress. It is proposed that the TAAC protein supplies ATP for energy-dependent reactions during thylakoid biogenesis and turnover. Recombinant TAAC protein was functionally integrated in the cytoplasmic membrane of Escherichia coli, and was shown to specifically transport ATP/ADP in a protonophore-sensitive manner, as also reported for mitochondrial AACs.</p><p>The PsbO protein stabilizes the oxygen-evolving complex of PSII and is ubiquitous in all oxygenic photosynthetic organisms, including cyanobacteria, green algae, and plants. So far only the 3D-structure of the cyanobacterial PsbO is available. Four GTP-binding motifs in the primary structure of spinach PsbO were predicted from comparison with classic GTP-binding proteins. These motifs were only found in the plant PsbOs, in the -barrel domain of the homologous 3D-structure. Using circular dichroism and intrinsic fluorescence spectroscopy, it was shown that MgGTP induces specific structural changes in the PsbO protein. Spinach PsbO has a low intrinsic GTPase activity, which is considerably stimulated when associated with a dimeric PSII complex. GTP stimulates the dissociation of PsbO from PSII under both inhibitory and non-inhibitory light conditions. A role for PsbO as a GTPase in the function of the oxygen-evolving complex and PSII repair is proposed.</p> plant Arabidopsis photosynthesis thylakoid membrane nucleotide-binding Cell and molecular biology Cell- och molekylärbiologi
128	Integrin Signalling Schelfaut, Roselien January 2005 (has links) <p>Integrins are receptors presented on most cells. By binding ligand they can generate signalling pathways inside the cell. Those pathways are a linkage to proteins in the cytosol. It is known that tumor cells can survive and proliferate in the absence of a solid support while normal cells need to be bound to ligand. To understand why tumour cells act that way, we first have to know how ligand-binding to integrins affect the cell. This research field includes studies on activation of proteins by integrins and the following protein-protein interactions.</p><p>The part of the research that I did, focused on the activation of PI3K by integrins and the question whether Ras is included in that pathway. I also studied the conformation changes of the integrins and tried to identify factors which regulate these changes.</p><p>Known is that Ras can activate PI3K. But we wanted to know if this is a step in the activation of PI3K by integrins. So if this would be a fact then Ras must be activated by integrins.</p><p>To see if integrins could activate Ras I did a pull down assay. GTP loaded Ras was isolated through its affinity for Raf. Only when Ras is in its activated state then it is GTP loaded, otherwise it is GDP loaded. In the experiment we also compared the β1A and the β1B splice variants. As result we could see that both splice variants probably can activate Ras. By blotting with anti-PI3K antibody we looked if PI3K had bound to Ras but no clear result could be obtained.</p><p>Integrins presented on blood cells are mostly in the inactive state while adherent cells have integrins which are mostly in the active state. PI3K has been shown, for blood cells, to be involved in the conformation regulation of integrins. Possibly, there is a positive circle that for blood cells just has to be switched on. It could be that the integrins in adherent cells are active because the cells are adhesive. By being adhesive, PI3K is activated. PI3K may then activate the integrins, through which the integrins stay in the active state. This circle could be broken at two points: we could inhibit PI3K or we could make the cells un-adhesive. I analysed this in cell attachment assay and by binding of conformation-specific integrin antibodies in FACScan. From the results we could not find any evidence that the whole idea around the positive circle is correct. Surprisingly we saw that the integrin value at the surface decrease if you add PI3K inhibitor. This could be due to distribute recirculation of integrins from the cytoplasm to the cell surface.</p><p>β1- and β3-integrins are both widely spread, but no functional difference could be shown already. Previous results suggest that there is a difference between migrations of those two types. To ensure this suggestion I did a wound assay. Hereby I compared the migration of different cell types, with different integrins on their surface and on different ligands.</p> Cell and molecular biology Cell- och molekylärbiologi
129	<i>N</i>-Sulfation and Polymerization in Heparan Sulfate Biosynthesis Presto, Jenny January 2006 (has links) <p>Heparan sulfate (HS) is a glycosaminoglycan present in all cell types covalently attached to core proteins forming proteoglycans. HS interacts with different proteins and thereby affects a variety of processes. The biosynthesis of HS takes place in the Golgi network where a complex of the enzymes EXT1 and EXT2 adds N-acetyl glucosamine and glucuronic acid units to the growing chain. The HS chain is <i>N</i>-sulfated by the enzyme <i>N</i>-deacetylase <i>N</i>-sulfotransferase (NDST). <i>N</i>-Sulfation occurs in domains where further modifications (including <i>O</i>-sulfations) take place, giving the chain a complex sulfation pattern.</p><p>In this thesis, new data about the regulation of NDST enzyme activity is presented. By studying NDST1 with active site mutations overexpressed in HEK 293 cells we show that <i>N</i>-deacetylation is the rate-limiting step in HS <i>N</i>-sulfation and that two different NDST molecules can work on the same GlcN unit.</p><p>By analyzing recombinant forms of NDST1 and NDST2 we determined the smallest substrate for <i>N</i>-deacetylation to be an octasaccharide. Importantly, the sulfate donor PAPS was shown to regulate the NDST enzymes to modify the HS chain in domains and that binding of PAPS had a stimulating effect on <i>N</i>-deacetylase activity. </p><p>We could also show that increased levels of NDST1 were obtained when NDST1 was coexpressed with EXT2, while coexpression with EXT1 had the opposite effect. We suggest that EXT2 binds to NDST1, promoting the transport of functional NDST1 to the Golgi network and that EXT1 competes for binding to EXT2. </p><p>Using cell lines overexpressing EXT proteins, it was demonstrated that overexpression of EXT1 increases HS chain length and coexpression of EXT2 results in even longer chains. The enhancing effect of EXT2 was lost when EXT2 was carrying mutations identical to those found in patients with hereditary multiple exostoses, a syndrome characterized by cartilage-capped bony outgrowths at the long bones.</p><p>.</p> Cell and molecular biology Heparan sulfate N-deacetylase / N-sulfotransferase NDST EXT1 EXT2 Biosynthesis Cell- och molekylärbiologi
130	Proteomic Analysis of Peroxisomal Proteins Mi, Jia January 2007 (has links) <p>Peroxisome is a ubiquitous eukaryotic organelle with a single-layer membrane. It maintains various functions that differ depending on the species and cell types, as well as the environmental or developmental conditions.</p><p>In the first part of this thesis, the peroxisomal protein content was systematically analyzed in different organs in mouse from different ages using proteomic approaches. Thirty-one peroxisomal proteins were identified and ten putative peroxisomal proteins were suggested. The results indicate that peroxisomal proteins show a tissue-specific functional response to the aging process that is probably dependent on their differential regeneration capacity. Besides, alteration in the fatty acid metabolism could alter membrane protein functions; decrease in catalase expression in kidney may contribute to oxidative stress and isoprenoid biosynthesis could contribute to decline in bile salt synthesis. The ability to detect changes in the peroxisomal proteome associated with organ impairment during the course of aging would provide a conceptual framework to understand the role of peroxisome in aging.</p><p>In the second part, peroxisome proteomics was used as a novel approach in marine pollution assessment. The peroxisomal protein expression profiles were obtained and identified from mussel Mytilus sp. exposed to different pollutants, in both laboratory and field experiments. The identified proteins were involved in α- and β–oxidation pathways, xenobiotics and amino acid metabolism, cell signalling, oxyradical metabolism, peroxisomal assembly, respiration and cytoskeleton pathway, etc. Generally, these findings suggest that protein expression signatures could become a valuable tool to monitor the presence of pollutants in marine environment.</p> Cell and molecular biology peroxisome proteomics biomarker aging pollution assessment Cell- och molekylärbiologi

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