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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Protein-protein Interaction Between Two Key Regulators of One-carbon Metabolism in Saccaharomyces cerevisiae.

Khan, Aftab 27 July 2010 (has links)
One-carbon metabolism is an essential process that is conserved from yeast to humans. Glycine stimulates the expression of genes in one-carbon metabolism, whereas its withdrawal causes repression of these genes. The transcription factor Bas1p and the metabolic enzyme Shm2p have been implicated in this regulation. I have shown that Bas1p physically interacts with Shm2p through co-immunoprecipitation. Using chromatin immunoprecipitation (ChIP), I have also shown that the interaction between Bas1p and Shm2p occurs at the promoter of two genes in the one-carbon metabolism regulon and that the binding of Shm2p requires Bas1p. Using a yeast-two hybrid system, I have systematically truncated Bas1p from the C-terminal end to find a region responsible for the interaction with Shm2p. My data suggest that Shm2p is directly bound to Bas1p at the promoters of glycine regulated genes where it regulates the transcriptional activity of Bas1p in response to changes in glycine levels.
2

Protein-protein Interaction Between Two Key Regulators of One-carbon Metabolism in Saccaharomyces cerevisiae.

Khan, Aftab 27 July 2010 (has links)
One-carbon metabolism is an essential process that is conserved from yeast to humans. Glycine stimulates the expression of genes in one-carbon metabolism, whereas its withdrawal causes repression of these genes. The transcription factor Bas1p and the metabolic enzyme Shm2p have been implicated in this regulation. I have shown that Bas1p physically interacts with Shm2p through co-immunoprecipitation. Using chromatin immunoprecipitation (ChIP), I have also shown that the interaction between Bas1p and Shm2p occurs at the promoter of two genes in the one-carbon metabolism regulon and that the binding of Shm2p requires Bas1p. Using a yeast-two hybrid system, I have systematically truncated Bas1p from the C-terminal end to find a region responsible for the interaction with Shm2p. My data suggest that Shm2p is directly bound to Bas1p at the promoters of glycine regulated genes where it regulates the transcriptional activity of Bas1p in response to changes in glycine levels.
3

Dietary and genetic influences on neural tube defects

Fathe, Kristin Renee 16 September 2014 (has links)
Neural tube defects (NTDs) are a world health issue, affecting approximately 1 in every 1000 live births. These congenital defects arise from the improper closure of the neural tube during development, resulting in significant, life-threatening malformations of the central nervous system. Although it has been observed that supplementing women of child-bearing age with folates greatly decreases the chances of having an NTD affected baby, unfortunately these defects still occur. It is accepted that these complex disorders arise from a combination of genetic, environmental, and dietary influences. One such dietary influence is the one-carbon metabolism metabolite, homocysteine. Homocysteine is a byproduct of methylation reactions in the cell that exists in an inverse homeostasis with folate. Homocysteine can also undergo a transformation that allows it to then react with exposed lysine or cysteine residues on proteins, in a process known as N-homocysteinylation or S-homocysteinylation respectively. High levels of homocysteine have been long correlated with many disease states, including NTDs. One potential mechanism by which homocysteine confers its negative effects is through protein N-homocysteinylation. Here, a novel and high-throughput assay for N-homocysteinylation determination is described. This assay is shown to be accurate with mass spectrometry then shown to be biologically relevant using known hyperhomocysteinemia mouse models. This assay was then applied to a cohort of neural tube closure staged mouse embryos with two different genetic mutations that have previously been shown to predispose mice to NTDs. The genotypes explored here are mutations to the LRP6 gene and the Folr1 gene, both of which have been described as folate-responsive NTD mouse models. It was seen that maternal diet and embryonic genotype had the largest influence on the developmental outcome of these embryos; however, the inverse relationship between folate and homocysteine seemed to be established at this early time point, emphasizing the importance of the balance in one-carbon metabolism. One of these genes, LRP6, was then explored in a human cohort of spina bifida cases. Four novel mutations to the LRP6 gene were found and compared to the mouse model used in the previous study. One of the mutations found in the human population was seen to mimic that of the LRP6 mouse model, therefore expanding the potential of this NTD model. / text
4

One-carbon metabolism in lung cancer

Yao, Sha 11 November 2020 (has links)
No description available.
5

Genome damage and folate nutrigenomics in uteroplacental insufficiency.

Furness, Denise Lyndal Fleur January 2007 (has links)
Pregnancy complications associated with placental development affect approximately one third of all human pregnancies. Genome health is essential for placental and fetal development, as DNA damage can lead to pregnancy loss and developmental defects. During this developmental phase rapid DNA replication provides an increased opportunity for genome and epigenome damage to occur[1]. Maternal nutrition is one of the principal environmental factors supporting the high rate of cell proliferation and differentiation. Folate functions in one-carbon metabolism and regulates DNA synthesis, DNA repair and gene expression[1]. Deficiencies or defects in gene-nutrient interactions associated with one-carbon metabolism can lead to inhibition of cell division, cell cycle delay and an excessive apoptotic or necrotic cell death rate [2], which may affect placentation. This study is the first to investigate the association between genomic damage biomarkers in late pregnancy complications associated with uteroplacental insufficiency (UPI) including preeclampsia and intrauterine growth restriction (IUGR). The results indicate that genome damage in the form of micronucleated cells in peripheral blood lymphocytes at 20 weeks gestation is significantly increased in women at risk of developing an adverse pregnancy outcome. The observed OR for the high micronuclei frequency may be the highest observed for any biomarker selected in relation to risk of pregnancy complications to date (15.6 – 33.0). In addition, reduced apoptosis was observed in association with increased micronuclei, suggesting that the cells may have escaped specific cell-cycle checkpoints allowing a cell with DNA damage to proceed through mitosis. This study demonstrated that an increase in plasma homocysteine concentration at 20 weeks gestation is associated prospectively with the subsequent development of UPI, indicating a causal relationship. The MTR 2756 GG genotype was significantly associated with increased plasma homocysteine concentration and UPI. Furthermore, the MTHFD1 1958 single nucleotide polymorphism was associated with increased risk for IUGR. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1309296 / Thesis (Ph.D.) -- School of Paediatrics and Reproductive Health, 2007
6

Genome damage and folate nutrigenomics in uteroplacental insufficiency.

Furness, Denise Lyndal Fleur January 2007 (has links)
Pregnancy complications associated with placental development affect approximately one third of all human pregnancies. Genome health is essential for placental and fetal development, as DNA damage can lead to pregnancy loss and developmental defects. During this developmental phase rapid DNA replication provides an increased opportunity for genome and epigenome damage to occur[1]. Maternal nutrition is one of the principal environmental factors supporting the high rate of cell proliferation and differentiation. Folate functions in one-carbon metabolism and regulates DNA synthesis, DNA repair and gene expression[1]. Deficiencies or defects in gene-nutrient interactions associated with one-carbon metabolism can lead to inhibition of cell division, cell cycle delay and an excessive apoptotic or necrotic cell death rate [2], which may affect placentation. This study is the first to investigate the association between genomic damage biomarkers in late pregnancy complications associated with uteroplacental insufficiency (UPI) including preeclampsia and intrauterine growth restriction (IUGR). The results indicate that genome damage in the form of micronucleated cells in peripheral blood lymphocytes at 20 weeks gestation is significantly increased in women at risk of developing an adverse pregnancy outcome. The observed OR for the high micronuclei frequency may be the highest observed for any biomarker selected in relation to risk of pregnancy complications to date (15.6 – 33.0). In addition, reduced apoptosis was observed in association with increased micronuclei, suggesting that the cells may have escaped specific cell-cycle checkpoints allowing a cell with DNA damage to proceed through mitosis. This study demonstrated that an increase in plasma homocysteine concentration at 20 weeks gestation is associated prospectively with the subsequent development of UPI, indicating a causal relationship. The MTR 2756 GG genotype was significantly associated with increased plasma homocysteine concentration and UPI. Furthermore, the MTHFD1 1958 single nucleotide polymorphism was associated with increased risk for IUGR. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1309296 / Thesis (Ph.D.) -- School of Paediatrics and Reproductive Health, 2007
7

Biomarkers of one-carbon metabolism in colorectal cancer risk

Gylling, Björn January 2017 (has links)
One-carbon metabolism, a network of enzymatic reactions involving the transfer of methyl groups, depends on B-vitamins as cofactors, folate as a methyl group carrier, and amino acids, betaine, and choline as methyl group donors. One-carbon metabolism influences many processes in cancer initiation and development such as DNA synthesis, genome stability, and histone and epigenetic methylation. To study markers of one-carbon metabolism and inflammation in relation to colorectal cancer (CRC) risk, we used prediagnostic plasma samples from over 600 case participants and 1200 matched control participants in the population-based Northern Sweden Health and Disease Study cohort. This thesis studies CRC risk with respect to the following metabolites measured in pre-diagnostic plasma samples: 1) folate, vitamin B12, and homocysteine; 2) components of one-carbon metabolism (choline, betaine, dimethylglycine, sarcosine, and methionine); and 3) three markers of different aspects of vitamin B6 status. In addition, this thesis examines three homocysteine ratios as determinants of total B-vitamin status and their relation to CRC risk. In two previous studies, we observed an association between low plasma concentrations of folate and a lower CRC risk, but we found no significant association between plasma concentrations of homocysteine and vitamin B12 with CRC risk. We have replicated these results in a study with a larger sample size and found that low folate can inhibit the growth of established pre-cancerous lesions. Using the full study cohort of over 1800 participants, we found inverse associations between plasma concentrations of the methionine cycle metabolites betaine and methionine and CRC risk. This risk was especially low for participants with the combination of low folate and high methionine versus the combination of low folate and low methionine. Well-functioning methionine cycle lowers risk, while impaired DNA synthesis partly explains the previous results for folate. We used the full study cohort to study associations between CRC risk and the most common marker of vitamin B6 status, pyridoxal' 5-phosphate (PLP), and two metabolite ratios, PAr (4-pyridoxic acid/(PLP + pyridoxal)) estimating vitamin B6 related inflammatory processes and the functional vitamin B6 marker 3-hydroxykynurenine to xanthurenic acid (HK:XA). Increased vitamin B6-related inflammation and vitamin B6 deficiency increase CRC risk. Inflammation was not observed to initiate tumorigenesis. Total B-vitamin status can be estimated by three different recently introduced homocysteine ratios. We used the full study cohort to relate the ratios as determinants of the total B-vitamin score in case and control participants and estimated the CRC risk for each marker. Sufficient B-vitamin status as estimated with homocysteine ratios was associated with a lower CRC risk. These studies provide a deeper biochemical knowledge of the complexities inherent in the relationship between one-carbon metabolism and colorectal tumorigenesis.
8

Profiling Methylenetetrahydrofolate Reductase Throughout Mouse Oocyte and Preimplantation Embryo Development

Young, Kyla 29 March 2022 (has links)
The global DNA methylation pattern is erased and re-established during oogenesis and again in preimplantation (PI) embryo development. Understanding where these methyl groups come from and how the process of methylation is regulated is important, as disruptions could result in detrimental effects. The methionine cycle that produces the cellular methyl pool is linked to the folate cycle. The key enzyme linking theses cycles is Methylenetetrahydrofolate Reductase (MTHFR) which converts 5,10-methylenetetrahydrofolate to 5-methyltetrahydrofolate. Mthfr RNA and protein are present throughout mouse oocyte and PI embryo development, including the germinal vesicle, MII egg, 1-cell embryo, 2-cell embryo, morula and blastocysts. In MII eggs the protein appears to be heavier than in any other stage. This was reversed by treatment with Lambda Protein Phosphatase (LPP), indicating that MTHFR is phosphorylated in MII eggs. MTHFR was progressively phosphorylated beginning shortly after initiation of meiotic maturation, reaching maximal levels in MII eggs before decreasing after egg activation using strontium chloride. Potential kinases responsible for the phosphorylation of MTHFR have been identified however not in oocytes or PI embryos. DYRK1A/1 and GSK3A/B have both been suggested to mediate the phosphorylation, however when inhibited showed no effect on the oocyte sample. An LC-MS/MS assay was attempted to measure the activity of MTHFR in wildtype and knockout mouse liver samples, however unsuccessful in the amounts needed to be used for comparison to oocytes. Overall, MTHFR is present in the developing stages of interest and is mediated in some capacity by phosphorylation modifications around the MII stage of development.
9

Anoxic quaternary amine utilization by archaea and bacteria through a non-<i>L</i>-pyrrolysine methyltransferase; insights into global ecology, human health, and evolution of anaerobic systems

Ticak, Tomislav 27 April 2015 (has links)
No description available.
10

One-Carbon Metabolism Related B-Vitamins Alter The Expression Of MicroRNAS And Target Genes Within The Wnt Signaling Pathway In Mouse Colonic Epithelium

Racicot, Riccardo 13 July 2016 (has links)
ABSTRACT It has been widely recognized that microRNAs are involved in nearly all cellular processes that have been investigated and contribute to a variety of diseases including cancer. Our prior studies demonstrated the depletion of one-carbon metabolism related B-vitamins, including folate, vitamin B2, B6 and B12, induced a genomic DNA hypomethylation and an elevation of the tumorigenic Wnt signaling in mouse colonic epithelium. The present study aimed to define whether microRNAs serve as mediators between these B-vitamins and the Wnt signaling, and thereby influence intestinal tumorigenesis. MicroRNA expression profiles were measured using miRNA microarray and real-time PCR on colonic epithelial cells from Apc1638N mice fed with diets deplete or sufficient in those B-vitamins. In silico bioinformatic analysis were performed to predict microRNA gene targets within the Wnt signaling cascade. Out of 609 microRNA examined, 18 microRNAs were found to be either significantly (p < 0.05) or mildly (p < 0.10) differentially expressed in the colonic epithelium of mice fed the depleted diet when compared to the counterpart. Bioinformatic prediction of microRNA gene targets identified 40 genes within the Wnt pathway to have homology with microRNA seed sequences within their 3’-UTR or protein coding sequence. Of the 6 genes tested for experimentally target validation, the expression of Sfrp1 was shown to be significantly inhibited (p < 0.05) whereas β-catenin was shown to be significantly elevated (p < 0.05) with alterations of others in a fashion indicating the activation of Wnt signaling. These findings indicate that microRNAs may constitute a mechanism by which one-carbon B-vitamin depletions regulate the Wnt signaling pathway and thereby inform intestinal tumorigenesis.

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