Global ETD Search

1	Study of serine palmitoyltransferase and de novo synthesis of sphingolipids Wei, Jia 06 April 2009 (has links) We have studied the molecular and biological consequences of overexpression of serine palmiotyltransferase (SPT) using HEK293 cells stably transfected with SPTLC1 and SPTLC2 (termed "SPT1/2 cells"). The effects of the elevated SPT activity were analyzed by liquid chromatography, electrospray ionization tandem mass spectrometry. Most sphingolipid subspecies were elevated in SPT1/2 cells, with disproportionately higher dihydrosphingolipids and ceramides with stearic acid. Sphingomyelins were lower, however, which does not appear to be due to faster degradation, but possibly by substitution by dihydrosphingomyelins. Despite large increases in potentially growth inhibitory and lethal ceramides, SPT1/2 cells grow faster than HEK293 cells. We also noted by confocal microscopy that endogenous SPT1 is not only in the endoplasmic reticulum, but also in the nucleus and focal adhesions, which was confirmed by elimination of SPT1 using SPTLC1 siRNA and co-immunoprecipitation of SPT1 with vinculin. The appearance of SPT1 in focal adhesions is lost when cells reach confluence and reappears after a scratch assay to reinitiate migration; furthermore, SPTLC1 siRNA causes cell rounding. Thus, in addition to its "traditional" role in de novo sphingolipid biosynthesis in the ER, SPT1 is present in other cellular compartments and is required for normal cell morphology and migration. It is possible that some of the previously unnoticed properties of SPT1 are due to alternative isoforms because we have found at least one splice variant that is expressed in HEK293 cells. Sphingolipid Serine palmitoyltransferase Sphingolipids
2	Studies on the structure, mechanism and inhibition of serine palmitoyltransferase Wadsworth, John Michael January 2015 (has links) Sphingolipids and ceramides are essential components of cellular membranes and important signalling molecules. Because of a growing appreciation for their diverse biological roles, understanding of the biosynthesis and regulation of sphingolipids has recently become a key goal in drug discovery. Serine palmitoyltransferase (SPT) is a pyridoxal 5′-phosphate (PLP)-dependent enzyme that catalyses the condensation between L-serine and a long-chain acyl thioester such as palmitoyl-CoA (C16-CoA). This first step in sphingolipid biosynthesis is conserved in all organisms studied to date, from microbes to man. The fungal natural product myriocin is a potent inhibitor of SPT; however, the molecular details of inhibition are not fully understood. Myriocin contains a long alkyl chain and a polar head group thus it displays features of both SPT substrates. Therefore, the prevailing hypothesis is that inhibition of SPT occurs because myriocin acts as a mimic of a key transition state of the catalytic mechanism. Through a combination of UV-vis spectroscopy, mass spectrometry, x-ray crystallography and enzyme inhibition assays it has been possible to study the interaction between S. paucimobilis SPT and myriocin. I have shown that myriocin initially forms an inhibitory PLP:myriocin aldimine complex in the active site that displays a Ki of 967 nM. Interestingly, this complex is susceptible to unexpected, slow enzymatic degradation. The mechanism for myriocin breakdown has been elucidated as a retro-aldol type reaction, which results in cleavage of the C2-C3 bond producing a C18 aldehyde. This aldehyde is then capable of covalently modifying the active site lysine265, forming a second (suicide) inhibitory complex and rendering the enzyme catalytically inactive. Substitution of the active site lysine produced SPT K265A, an inactive enzyme that did not catalyse the breakdown of the PLP:myriocin complex. However, the determination of the crystal structure of the SPT K265A:PLP-myriocin complex revealed that the myriocin had undergone decarboxylation. Nevertheless, this SPT:PLP:decarboxymyriocin structure revealed details about myriocin’s mechanism of inhibition for the first time. The novel mechanism of myriocin degradation has implications on the structure activity relationship (SAR) and design of drugs targeted towards SPT, the role of feedback regulation by long chain aldehydes and further expands the range of reactions catalysed by this important enzyme. As well as inhibition studies the structure of bacterial SPT was also examined by preparing an N-terminally truncated S. paucimobilis SPT. This version, shortened by 21 amino acids, was ~5-fold slower than the wild-type enzyme and suggests that the N-terminus may play a role in catalysis. Additional work has been undertaken to study an unusual membrane-bound viral SPT, composed of two naturally fused open reading frames (SPT2-SPT1) with the proposed SPT2 domain at the N-terminus and the SPT1 domain at the C-terminus. To study soluble mimics of this interesting fusion I prepared a bacterial S. paucimobilis SPT fused wild-type and mutant construct and isolated a fused SPT2-SPT1 with what appears to be single PLPbinding site. 615.1
3	Effects of Increasing Intravenous Glucose Infusions on Lactation Performance, Metabolic Profiles, and Metabolic Gene Expression in Dairy Cows BahaaAldeen, Al-Trad 24 June 2010 (has links) (PDF) Knowledge on the precise effects of surplus glucose supply in dairy cows is limited by the lack of information on how intermediary metabolism adapts at different levels of glucose availability. Therefore, a gradual increase of glucose supply via intravenous glucose infusion was used in the present study to test the dose effect of surplus provision of glucose on the metabolic status and milk production of dairy cows. Furthermore, the effects of increasing levels of surplus glucose on mRNA expressions and activities of rate-limiting enzymes involved in hepatic gluconeogenesis were investigated. Based on a previous finding that a positive energy balance may decrease hepatic carnitine palmitoyltransferase (CPT) enzyme activity, it was also of interest whether skeletal muscle CPT activity is downregulated in a similar manner during positive energy balance. Twelve midlactating Holstein-Friesian dairy cows were continuously infused over a 28-d experimental period with either saline (SI group, six cows) or 40% glucose solutions (GI group, six cows). The infusion dose was calculated as a percentage of the daily energy (NEL) requirements by the animal, starting at 0% on d 0 and increasing gradually by 1.25%/d until a maximum dose of 30% was reached by d 24. Dose was then maintained at 30% NEL requirement for 5 d. No infusions were made between d 29-32. Liver and skeletal muscle biopsies were taken on d 0, 8, 16, 24, and 32. Body weight (BW) and back fat thickness (BFT) were recorded on biopsies days. Blood samples were taken every 2 d. In addition, blood samples over 24 h (6-h intervals) were taken the days before each biopsy. Milk and urine samples were taken on biopsies days. BW and BFT increased linearly with increasing glucose dose for GI cows. No differences were observed in the dry matter intake, milk energy output, and energy corrected milk yield between groups. However, milk protein percentage and yield increased linearly in the GI group. Only occasional increases in blood glucose and insulin concentrations were observed in blood samples taken at 1000 h every 2 d. However, during infusion dose of 30% NEL requirements on d 24, GI cows developed postprandial hyperglycemia associated with hyperinsulinemia, coinciding with glucosuria. The revised quantitative insulin sensitivity check index (RQUIKI) indicated linear development of insulin resistance for the GI treatment. GI decreased serum concentrations of beta-hydroxybutyrate (BHBA) and blood urea nitrogen and tended to decrease the serum concentration of non-esterified fatty acids (NEFA). Liver glycogen content increased, while glycogen content in skeletal muscle only tended to increase by GI. No significant changes were observed in the activities and relative mRNA expression levels of hepatic phosphoenolpyruvate carboxykinase and glucose 6-phospatase. The activity of fructose 1,6-bisphosphatase (FBPase) and relative mRNA expression levels of pyruvate carboxylase (PC) were decreased in the GI group but only during the high dose of glucose infusion. Hepatic CPT activity decreased with GI and remained decreased on d 32. The hepatic expression levels of CPT-1A and CPT-2 mRNA were not significantly altered but tended to reflect the changes in enzyme activity. No effect of glucose infusion was observed on skeletal muscle CPT activity. The aforementioned adaptations were reversed four days after the end of glucose infusions except for those of BW, BFT, and lipid metabolism (i.e. serum BHBA and NEFA concentrations, hepatic CPT activity). It is concluded that mid-lactation dairy cows on an energy-balanced diet direct intravenously infused glucose predominantly to body fat reserves but not to increased lactation performance. Cows rapidly adapted to increasing glucose supply but experienced dose-dependent development of insulin resistance corresponding with postprandial hyperglycemia/hyperinsulinemia and glucosuria at dosages equivalent to 30% NEL requirements. The catalytic capacity of key hepatic gluconeogenesis enzymes in mid-lactating dairy cows is not significantly affected by nutritionally relevant increases of glucose supply. Only very high dosages selectively suppress PC transcription and FBPase activity. Finally, it can be concluded that suppression of CPT activity by positive energy balance appears to be specific for the liver in midlactating dairy cows. Glucose infusion Dairy cows Lactation performance Hepatic gluconeogenesis Carnitine palmitoyltransferase Glukoseinfusion Milchkühe Laktationsleistung Hepatische Gluconeogenese Carnitin-Palmitoyltransferase ddc:610
4	Effects of Increasing Intravenous Glucose Infusions on Lactation Performance, Metabolic Profiles, and Metabolic Gene Expression in Dairy Cows BahaaAldeen, Al-Trad 30 March 2010 (has links) Knowledge on the precise effects of surplus glucose supply in dairy cows is limited by the lack of information on how intermediary metabolism adapts at different levels of glucose availability. Therefore, a gradual increase of glucose supply via intravenous glucose infusion was used in the present study to test the dose effect of surplus provision of glucose on the metabolic status and milk production of dairy cows. Furthermore, the effects of increasing levels of surplus glucose on mRNA expressions and activities of rate-limiting enzymes involved in hepatic gluconeogenesis were investigated. Based on a previous finding that a positive energy balance may decrease hepatic carnitine palmitoyltransferase (CPT) enzyme activity, it was also of interest whether skeletal muscle CPT activity is downregulated in a similar manner during positive energy balance. Twelve midlactating Holstein-Friesian dairy cows were continuously infused over a 28-d experimental period with either saline (SI group, six cows) or 40% glucose solutions (GI group, six cows). The infusion dose was calculated as a percentage of the daily energy (NEL) requirements by the animal, starting at 0% on d 0 and increasing gradually by 1.25%/d until a maximum dose of 30% was reached by d 24. Dose was then maintained at 30% NEL requirement for 5 d. No infusions were made between d 29-32. Liver and skeletal muscle biopsies were taken on d 0, 8, 16, 24, and 32. Body weight (BW) and back fat thickness (BFT) were recorded on biopsies days. Blood samples were taken every 2 d. In addition, blood samples over 24 h (6-h intervals) were taken the days before each biopsy. Milk and urine samples were taken on biopsies days. BW and BFT increased linearly with increasing glucose dose for GI cows. No differences were observed in the dry matter intake, milk energy output, and energy corrected milk yield between groups. However, milk protein percentage and yield increased linearly in the GI group. Only occasional increases in blood glucose and insulin concentrations were observed in blood samples taken at 1000 h every 2 d. However, during infusion dose of 30% NEL requirements on d 24, GI cows developed postprandial hyperglycemia associated with hyperinsulinemia, coinciding with glucosuria. The revised quantitative insulin sensitivity check index (RQUIKI) indicated linear development of insulin resistance for the GI treatment. GI decreased serum concentrations of beta-hydroxybutyrate (BHBA) and blood urea nitrogen and tended to decrease the serum concentration of non-esterified fatty acids (NEFA). Liver glycogen content increased, while glycogen content in skeletal muscle only tended to increase by GI. No significant changes were observed in the activities and relative mRNA expression levels of hepatic phosphoenolpyruvate carboxykinase and glucose 6-phospatase. The activity of fructose 1,6-bisphosphatase (FBPase) and relative mRNA expression levels of pyruvate carboxylase (PC) were decreased in the GI group but only during the high dose of glucose infusion. Hepatic CPT activity decreased with GI and remained decreased on d 32. The hepatic expression levels of CPT-1A and CPT-2 mRNA were not significantly altered but tended to reflect the changes in enzyme activity. No effect of glucose infusion was observed on skeletal muscle CPT activity. The aforementioned adaptations were reversed four days after the end of glucose infusions except for those of BW, BFT, and lipid metabolism (i.e. serum BHBA and NEFA concentrations, hepatic CPT activity). It is concluded that mid-lactation dairy cows on an energy-balanced diet direct intravenously infused glucose predominantly to body fat reserves but not to increased lactation performance. Cows rapidly adapted to increasing glucose supply but experienced dose-dependent development of insulin resistance corresponding with postprandial hyperglycemia/hyperinsulinemia and glucosuria at dosages equivalent to 30% NEL requirements. The catalytic capacity of key hepatic gluconeogenesis enzymes in mid-lactating dairy cows is not significantly affected by nutritionally relevant increases of glucose supply. Only very high dosages selectively suppress PC transcription and FBPase activity. Finally, it can be concluded that suppression of CPT activity by positive energy balance appears to be specific for the liver in midlactating dairy cows. info:eu-repo/classification/ddc/610 ddc:610
5	Structural and mechanistic studies of the pyridoxal 5'-phosphate-dependent enzyme serine palmitoyltransferase Mykhaylyk, Bohdan January 2018 (has links) Sphingolipids (SLs) are complex lipid-derived structures that are essential components of cell membranes in eukaryotes and some bacteria. SLs and their complex derivatives ceramides are known to be involved in multiple processes such as the formation of lipid rafts, cell signalling and membrane trafficking. The first step of SL biosynthesis is universal to all sphingolipid-producing organisms from bacteria to humans and is catalysed by the enzyme serine palmitoyltransferase (SPT). SPT is a member of the alpha-oxoamine synthase (AOS) family of pyridoxal- 5'-phosphate-dependent enzymes. All AOS family enzymes retain a high degree of structural homology and catalyse the decarboxylative Claisen-like condensation of amino acids with thioester substrates. The SPT enzyme catalyses the formation of the universal SL precursor, 3-ketodihydrosphingosine (KDS), by condensation of L-serine and coenzyme A-derived palmitic acid. Being the key controller in SL biosynthesis, SPT plays a big role in regulating natural and pathological processes. A lot of research interest has been recently generated by SLs isolated from bacterial members of the human microbiome and their roles in human health. Increasing evidence suggests that some of these SLs possess immunoregulatory effects and can have a direct impact on the immunity of the host. Bacteroides fragilis is a commensal gut-dwelling bacterium that belongs to a few human microbionts known to produce unique iso-branched sphingolipids (isoSLs); these have been shown to influence the human iNKT cell count. The production of SLs in B.fragilis is completely regulated by a gene product BF2461. In this work, BF2461 was expressed and purified; using a combination of UV-vis spectrometry, enzymatic assays, mass spectrometry and protein X-ray crystallography, it has been confirmed to be an SPT. The substrate specificity of the BfSPT has been assessed with a range of different chain-length substrates, including less common 15 and 17-carbon chain length coenzyme A substrates. The enzyme can produce different types of SL precursors with a preference for the 16-carbon chain substrate palmitoyl- CoA. However, at high levels of PCoA, a substrate inhibition is observed that might point to a natural control mechanism employed by the bacterium in favour of producing iso-branched SLs (isoSLs). The structure of BfSPT has been elucidated in a complex with its amino acid substrate L-serine. Search and analysis of putative SPTs from other microbiome-associated bacteria that produce isoSLs show that they share high similarity with an average amino acid conservation of 74%, suggesting they might be adapted to a particular type of substrate. In this respect, BfSPT might be the first isoSL-producing SPT to be structurally characterised, and the first one to have a direct impact on human health. Further structural data were obtained on protein complexes with L-cycloserine and L-penicillamine, some common inhibitors of the PLP-dependent enzymes. The structure obtained in the presence of L-penicillamine provides the first direct structural evidence of the inhibitory mechanism by a thiazolidine complex formation in the active site of a PLP-dependent enzyme. These findings shed light on certain aspects of the reaction and inhibition mechanisms of BfSPT as well as opening new prospects into researching this interesting target and its impact on the human microbiome.
6	Development of an assay for fatty acyl-CoAs using liquid chromatography-electrospray ionization-tandem mass spectrometry and its application to the stable isotope labeling and quantitation of sphingolipid metabolism Haynes, Christopher Allen 16 November 2009 (has links) Fatty acyl-Coenzyme As are metabolites of lipid anabolism and catabolism. A method was developed for their quantitation in extracts of cultured mammalian cells using liquid chromatography-electrospray ionization-tandem mass spectrometry (LC-ESI-MS/MS). Palmitoyl-CoA (C16:0-CoA) is utilized for de novo sphingolipid biosynthesis catalyzed by serine palmitoyltransferase (SPT), which condenses palmitoyl-CoA and serine to form 3-ketosphinganine. After reduction to form sphinganine (Sa), dihydroceramide synthase (CerS) can N-acylate the Sa using a second fatty acyl-CoA molecule, forming dihydroceramide (DHCer). The CerS enzyme family utilizes different acyl chain lengths of fatty acyl-CoAs in an isoform-specific manner, resulting in DHCer with N-acyl chains ranging from C16 to C26 [and even longer] in mammalian tissues. DHCer is trans-4,5-desaturated to yield ceramide, which is further metabolized by the addition of moieties at the 1-O-position, forming sphingomyelin (SM) and ceramide monohexose (CMH). The rates of fatty acyl-CoA and sphingolipid biosynthesis were determined using stable isotope-labeling and LC-ESI-MS/MS analysis of the analyte isotopologues and isotopomers. Isotopic labeling of palmitoyl-CoA with [U-13C]-palmitate in HEK293 and RAW264.7 cells was robust and rapid (~ 60% labeling of the metabolite pool in 3 hr). Isotopic labeling of sphingolipids indicated utilization of [M + 16]-palmitoyl-CoA by SPT and CerS isoforms in both cell types. Metabolic flux modeling was applied to the data for [U-13C]-palmitate activation to [M + 16]-palmitoyl-CoA and its subsequent utilization in de novo sphingolipid biosynthesis, and this analysis indicated rapid turn-over rates for palmitoyl-CoA and ceramide in both cell types. Palmitate treatment of cultured cells alters their metabolic status and gene expression, therefore labeling of palmitoyl-CoA by treatment with [1-13C]-acetate was employed. A distribution of mass-shifted palmitoyl-CoA species (isotopologues) is observed based on the number of incorporations of [1-13C]-acetate during de novo biosynthesis, requiring computational analysis to derive two parameters: the isotopic enrichment of the precursor pool, and the fraction of palmitoyl-CoA that was biosynthesized during the experiment. Previous reports by others describe mass isotopomer distribution analysis (MIDA) and isotopomer spectral analysis (ISA) for this purpose, and both calculation approaches indicated concurrent results. In summary, the quantitation of fatty acyl-CoAs and their isotopic enrichment during stable isotope-labeling studies of lipid metabolism can provide data that significantly change the interpretation of analyte quantitation in these experiments, as demonstrated here for investigations of de novo sphingolipid biosynthesis. Serine palmitoyltransferase [1-13C]-acetate [U-13C]-palmitate HEK293 RAW264.7 Sphingolipids Radiolabeling Fatty acids
7	Molecular Basis of Diverse PagP::Lipid Interactions in Gram-Negative Bacteria / Diverse PagP::Lipid Interactions in Gram-Negative Bacteria Miller, Sanchia January 2018 (has links) PagP is an integral outer membrane enzyme that transfers a palmitoyl group from a phospholipid to lipid A and the polar headgroup of phosphatidylglycerol (PG). Palmitoyl-lipid A and palmitoyl-PG (PPG) have been implicated in resistance to host immune defenses. PagP proteins are diverse, the E. coli PagP belongs to the major clade of PagP homologs and palmitoylates lipid A regiospecifically at the 2-position, whereas P. aeruginosa PagP belongs to the minor clade of PagP homologs and instead palmitoylates lipid A regiospecifically at the 3’-position. Our objective was to understand how PagP has been adapted in nature to interact with multiple lipid substrates and products. We investigated the structure-function relationships of key major clade homologs, to show that Bordetella PagP palmitoylates lipid A at the 3’-position and employs surface residue T29 in its palmitoyltransferase reaction. Legionella PagP palmitoylates lipid A at the 2-position and was confirmed to select a palmitate chain from a pool including iso-methyl branched phospholipids characteristic of this species. PagP is usually encoded as a single copy on the chromosome in most bacteria, but two copies of pagP are found in endophytic bacteria. These duplicated PagP homologs from the major clade branch into two subclades, namely chromosomal and plasmid-based PagP homologs. The chromosomal PagP homologs exhibit interacting periplasmic D61 and H67 residues, which are naturally mutated in plasmid-based PagP homologs, and are associated with a conformational change in the -barrel that determines its ability to palmitoylate PG. Chromosomal PagPs can convert PPG to bis(monoacylglycero)phosphate (BMP) and lysophosphatidylglycerol (LPG) through a periplasmic active site controlled by the invariant Y87 residue of E. coli PagP. Plasmid-based PagP homologs appear to have been adapted instead as monofunctional lipid A palmitoyltransferases. These results points to a common ancestor for PagP proteins. Knowledge gained from these studies can be applied to protein engineering. / Thesis / Doctor of Philosophy (PhD) PagP Outer membrane protein lipid A palmitoylation protein conformation change palmitoyltransferase diversity
8	Serine palmitoyltransferase and ceramide kinase in embryo development of loblolly pine Zhu, Cuihua 16 January 2008 (has links) Using the known sequences for serine palmitoyltransferase (SPT) and ceramide kinase (CERK) from Arabidopsis, candidates for the corresponding genes in Loblolly pine were cloned and examined during embryogenesis. The cloned two cDNA sequences from Loblolly pine, which has similarity of 81% and 88% respectively to two subunits of SPT1 and SPT2 in Arabidopsis, were presumed as the Loblolly pine SPT1 and SPT2 (Pt-SPT1 and Pt-SPT2). A few different versions of Pt-SPT1 mRNAs (2223 nts, 756 nts, 822 nts, and 754 nts respectively), most likely the alternative splicing results, were found. Three of these mRNAs are capable of encoding proteins. The long version (2223 nts) encodes a protein with 484 amino acids (Pt-SPT1); two short versions (822 nts, 756 nts) encode a 90 a.a. protein. Another cDNA sequence of 2396 nts encodes a protein of 493 a.a. (Pt-SPT2). Both predicted Pt-SPT1 and Pt-SPT2 proteins possess highly conserved serine palmitoyltransferase functional domains (E value 5.7e-61). Their expression patterns are different between somatic and zygotic embryogenesis. Two different versions of mRNAs, with 2786 nts (long), and 2320 nts (short) respectively, of ceramide kinases in Loblolly pine (Pt-CERKs) have been cloned. The long version encodes a protein with 721 a.a.; the short version with 560 a.a. The expression patterns for these two CERK mRNAs are different during embryo development. The long version is constitutively expressed, while the short one is only expressed in some stages with much lower expression level. Overexpression Pt-CERKL, Pt-CERKS, and Pt-CERKF in E.coli and function analysis in vitro show that all Pt-CERKs appear to have the same catalytic functions as their homologs in human and Arabidopsis, but with different efficiency. The catalytic efficiency was dramatically lower in the short Pt-CERK protein compared with the long Pt-CERK protein and Pt-CERKF. The membrane system is not necessary for the catalytic reactions of these three Pt-CERKs in vitro and Pt-CERKs were less dependent on the Ca2+ ions. Thus, these studies have provided the first information about SPT- and CERK- like proteins in loblolly pine, and open new avenues of investigation for the roles of sphingolipids in embryonic development. Loblolly pine Ceramide kinase Somatic embryogenesis Zygotic embryogenesis Serine palmitoyltransferase Sphingolipids Arabidopsis Cloning Loblolly pine Sphingolipids Plant embryology
9	The impact of Congenital Long QT Syndrome on First Nations children and youth in Northern British Columbia Bene Watts, Simona 23 August 2020 (has links) Background: Long QT syndrome (LQTS) is a cardiac condition which predisposes individuals to syncope, seizures, and sudden cardiac death. There is a high prevalence of congenital LQTS in a First Nations community in Northern British Columbia due to the founder variant p.V205M in the KCNQ1 gene. Additionally, two other variants of interest are present in this population: the KCNQ1 p.L353L variant, previously noted to modify the phenotype of LQTS in adults, and the CPT1A p.P479L variant, a metabolic variant common in Northern Indigenous populations associated with hypoglycemia and sudden unexpected infant death. Methods: We performed a mixed methods study to better understand the impact of LQTS in children and youth in this First Nations community. To learn about the clinical impact of LQTS, and better understand the effects of the KCNQ1 and CPT1A variants in children, we used statistical analysis to compare the cardiac phenotypes of 211 First Nations children with and without the p.V205M, p.L353L and p.P479L variants, alone and in combination. Ordinary Least Squares linear regression was used to compare the highest peak corrected QT interval (QTc). The peak QTc is an electrocardiogram measurement used in risk stratification of LQTS patients. Logistic regression was used to compare the rates of syncope and seizures experienced in childhood. Additionally, to learn about the lived-experience of LQTS, we interviewed one young First Nations adult about her experiences growing up with LQTS as a teenager. From this interview, we conducted a qualitative case study analysis using Interpretative Phenomenological Analysis. All research was done in partnership with the First Nations community using community-based participatory methods. Results: We found that the p.V205M variant conferred a 22.4ms increase in peak QTc (p<0.001). No other variants or variant interaction effects were observed to have a significant impact on peak QTc. No association between the p.V205M variant and loss of consciousness (LOC) events (syncope and seizures) was observed (OR(95%CI)=1.3(0.6-2.8); p=0.531). However, children homozygous for p.P479L were found to experience 3.3 times more LOC events compared to non-carriers (OR=3.3(1.3-8.3); p=0.011). With regard to the qualitative portion of the thesis, four superordinate (main) themes emerged from the case study: Daily life with Long QT Syndrome, Interactions with Medical Professionals, Finding Reassurance, and The In-Between Age. We found that even though our participant was asymptomatic and felt that she was not impacted by LQTS in her daily life, she considered certain elements of the condition to be stressful, such as taking a daily beta-blocker. Conclusion: These results suggest that while the KCNQ1 p.V205M variant is observed to significantly prolong the peak QTc, the CPT1A p.P479L variant is more strongly associated with LOC events in children from this community. More research is needed to further determine the effect of these variants; however, our preliminary findings suggest management strategies, such as whether beta-blockers are indicated for p.V205M carriers, may need to be reassessed. The importance of developing a holistic, well-balanced approach to medical care, taking into consideration the personal perspectives and unique medical circumstances of each child is exemplified in this study. / Graduate long QT syndrome LQTS Gitxsan First Nations carnitine palmitoyltransferase 1A CPT1A youth children well-being pediatric health pediatrics
10	Conséquences d’une restriction de croissance intra-utérine et du sexe biologique sur le métabolisme des acides gras dans les cardiomyocytes de rats foetaux Gravel, Cynthia 05 1900 (has links) Il est désormais accepté qu'un environnement foetal défavorable prédispose à des maladies chroniques qui surviennent à l'âge adulte. Il a été démontré dans notre laboratoire qu'une diminution de perfusion placentaire induit une redistribution du débit sanguin vers le coeur chez le foetus ainsi qu’une restriction de croissance intrautérine. De plus, un remodelage et une diminution de la contractilité des cardiomyocytes ont été observés chez les femelles devenues adultes. En période périnatale, l’utilisation des acides gras comme substrat énergétique devient plus importante que celle du glucose au niveau des cardiomyocytes. Considérant qu'un mécanisme s'est mis en place in utero, nous émettons l’hypothèse que le transfert de la voie de l’utilisation du glucose vers l’utilisation des acides gras se fait plus tôt chez les foetus en restriction de croissance. L’objectif de cette étude est de mesurer, dans les coeurs foetaux, les constituants du métabolisme des acides gras, soit le transporteur principal des acides gras, la carnitine palmitoyltransférase‒1‒alpha, ainsi que ses protéines associées soit l’acyl‒CoenzymeA synthétase‒1 et le canal anionique voltage‒dépendant de type 1. Nous mesurerons l’activité du cytochrome c oxydase et le nombre de mitochondries. L’influence du sexe et la condition foetale (restriction de croissance intrautérine vs contrôle) seront comparés. Nous avons observé que l’expression protéique de la carnitine palmitoytransférase‒1α et de l’acyl‒CoenzymeA synthétase‒1 est significativement augmentée, mais pas celle du canal anionique voltage‒dépendant de type 1, dans les coeurs de foetus en restriction de croissance intrautérine femelles. Le nombre et l’activité des mitochondries est semblable dans tous les groupes. Ces résultats suggèrent que la condition foetale et le sexe altèrent la quantité du transporteur des acides gras, la carnitine palmitoytransférase‒1α, au niveau traductionnel sans toutefois affecter l’activité du cytochrome c oxydase et le nombre de mitochondries. À long terme, nos études permettront de mieux comprendre les conséquences et causes de la RCIU afin d’en permettre la prévention. / It is widely accepted that an adverse fetal environment predisposes to chronic diseases that occur in adulthood. In our laboratory, it has been shown that a decrease in placental perfusion induced blood flow redistribution to the heart in fetus as well as an intrauterine growth restriction. Furthermore, remodeling and decreased contractility of cardiomyocytes were observed in adult offspring females. In perinatal period, the use of fatty acids as an energy substrate becomes more important than glucose in cardiomyocytes. Whereas a mechanism is in place in utero, we proposed the hypothesis that the transfer from the use of glucose as fuel towards fatty acids occurs earlier in intrauterine growth restriction fetuses. The objective of this study is to measure, in fetal hearts, the components of fatty acid metabolism, the main carrier of fatty acids, carnitine palmitoyltransférase‒1α, and its associated proteins namely acyl‒coenzymeA synthase‒1 and voltage‒dependant anion channel 1. We will measure the cytochrome c oxidase activity and the number of mitochondria. Influence of sex and fetal condition (intrauterine growth restriction vs control) will be compared. We observed that protein expression of carnitine palmitoyltranferase-1α and acyl-coenzyme A synthetase long-chain 1 is significantly increased, but not that of the voltage-dependant anion channel 1, in hearts of female fetus IUGR. The number and the activity of mitochondria are similar in all the groups. These results suggest that fetal condition and sex alter the quantity of the acid transporter carnitine palmitoyltranferase-1α has at the translation level without affecting the activity of the cytochrome c oxidase and the number of mitochondria. Mitochondries Grossesse Diète faible en sodium Low-sodium diet Pregnancy Mitochondria Carnitine palmitoyltransferase-1-alpha Carnitine palmitoyltransférase-1-alpha

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