Browsing by Subject "Isoenzymes"

Now showing 1 - 10 of 14
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    Allelic decomposition and exact genotyping of highly polymorphic and structurally variant genes
    (Springer Nature, 2018-02-26) Numanagić, Ibrahim; Malikić, Salem; Ford, Michael; Qin, Xiang; Toji, Lorraine; Radovich, Milan; Skaar, Todd C.; Pratt, Victoria M.; Berger, Bonnie; Scherer, Steve; Sahinalp, S. Cenk; Medicine, School of Medicine
    High-throughput sequencing provides the means to determine the allelic decomposition for any gene of interest-the number of copies and the exact sequence content of each copy of a gene. Although many clinically and functionally important genes are highly polymorphic and have undergone structural alterations, no high-throughput sequencing data analysis tool has yet been designed to effectively solve the full allelic decomposition problem. Here we introduce a combinatorial optimization framework that successfully resolves this challenging problem, including for genes with structural alterations. We provide an associated computational tool Aldy that performs allelic decomposition of highly polymorphic, multi-copy genes through using whole or targeted genome sequencing data. For a large diverse sequencing data set, Aldy identifies multiple rare and novel alleles for several important pharmacogenes, significantly improving upon the accuracy and utility of current genotyping assays. As more data sets become available, we expect Aldy to become an essential component of genotyping toolkits.
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    Characterization of the Mitochondrial Proteome in Pyruvate Dehydrogenase Kinase 4 Wild-Type and Knockout Mice
    (2009-06-24T12:51:58Z) Ringham, Heather Nicole; Wang, Mu; Harris, Robert; Witzmann, Frank
    The goal of this study was to determine the effect of a PDK4 (pyruvate dehydrogenase kinase isoenzyme 4) knock-out on mitochondrial protein expression. A 2-D gel based mass spectrometry approach was used to analyze the mitochondrial proteomes of PDK4 wild-type and knockout mice. Mitochondria were isolated from the kidneys of mice in both well-fed and starved states. Previous studies show PDK4 increases greatly in the kidney in response to starvation and diabetes suggesting its significance in glucose homeostasis. The mitochondrial fractions of the four experimental groups (PDK4+/+ fed, PDK4+/+ starved, PDK4-/- fed, and PDK4-/- starved) were separated via large- format, high resolution two-dimensional gel electrophoresis. Gels were scanned, image analyzed, and ANOVA performed followed by a pair-wise multiple comparison procedure (Holm-Sidak method) for statistical analysis. The abundance of a total of 87 unique protein spots was deemed significantly different (p<0.01). 22 spots were up- or down-regulated in the fed knockout vs. fed wild-type; 26 spots in the starved knockout vs. starved wild-type; 61 spots in the fed vs. starved wild-types; and 44 in the fed vs. starved knockouts. Altered protein spots were excised from the gel, trypsinized, and identified via tandem mass spectrometry (LC-MS/MS). Differentially expressed proteins identified with high confidence include ATP synthase proteins, fatty acid metabolism proteins, components of the citric acid cycle and electron transport chain. Proteins of interest were analyzed with Ingenuity Pathway Analysis (IPA) to examine relationships among the proteins and analyze biological pathways, as well as ontological analysis with Generic Gene Ontology (GO) Term Mapper. IPA found a number of canonical pathways, biological functions, and functional networks associated with the 87 proteins. Oxidative phosphorylation was the pathway associated with a majority of the proteins, while the largest network of proteins involved carbohydrate metabolism and energy production. Overall, the effects of starvation were more extensive on mitochondrial protein expression than the PDK4 knockout.
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    Discovery of a series of aromatic lactones as ALDH1/2-directed inhibitors
    (Elsevier, 2015-06-05) Buchman, Cameron D.; Mahalingan, Krishna K.; Hurley, Thomas D.; Department of Biochemistry & Molecular Biology, IU School of Medicine
    In humans, the aldehyde dehydrogenase superfamily consists of 19 isoenzymes which mostly catalyze the NAD(P)(+)-dependent oxidation of aldehydes. Many of these isoenzymes have overlapping substrate specificities and therefore their potential physiological functions may overlap. Thus the development of new isoenzyme-selective probes would be able to better delineate the function of a single isoenzyme and its individual contribution to the metabolism of a particular substrate. This specific study was designed to find a novel modulator of ALDH2, a mitochondrial ALDH isoenzyme most well-known for its role in acetaldehyde oxidation. 53 compounds were initially identified to modulate the activity of ALDH2 by a high-throughput esterase screen from a library of 63,000 compounds. Of these initial 53 compounds, 12 were found to also modulate the oxidation of propionaldehyde by ALDH2. Single concentration measurements at 10μM compound were performed using ALDH1A1, ALDH1A2, ALDH1A3, ALDH2, ALDH1B1, ALDH3A1, ALDH4A1, and/or ALDH5A1 to determine the selectivity of these 12 compounds toward ALDH2. Four of the twelve compounds shared an aromatic lactone structure and were found to be potent inhibitors of the ALDH1/2 isoenzymes, but have no inhibitory effect on ALDH3A1, ALDH4A1 or ALDH5A1. Two of the aromatic lactones show selectivity within the ALDH1/2 class, and one appears to be selective for ALDH2 compared to all other isoenzymes tested.
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    Discovery of novel regulators of aldehyde dehydrogenase isoenzymes
    (2011-05-30) Ivanova, Yvelina Tsvetanova; Hurley, Thomas D., 1961-; Goebl, Mark G.; Srour, Edward F.
    Recent work has shown that specific ALDH isoenzymes can contribute to the underlying pathology of different diseases. Many ALDH isozymes are important in oxidizing reactive aldehydes resulting from lipid peroxidation, and, thus, help maintain cellular homeostasis. Increased expression and activity of ALDH isozymes are found in many human cancers and are often associated with poor prognosis. Therefore, the development of inhibitors of the different ALDH enzymes is of interest as means to treat some of these disease states. Here I describe the results of assays designed to characterize the site of interaction and the mode of inhibition for the unique compounds that function as inhibitors of aldehyde dehydrogenase 2 and determine their respective IC50 values with intent to develop structure-activity relationships for future development.
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    Evaluation of aldehyde dehydrogenase 1 promoter polymorphisms identified in human populations
    (Ovid Technologies (Wolters Kluwer) - Lippincott Williams & Wilkins, 2003-09) Spence, John P.; Liang, Tiebing; Eriksson, C. J. Peter; Taylor, Robert E.; Wall, Tamara L.; Ehlers, Cindy L.; Carr, Lucinda G.; Department of Medicine, IU School of Medicine
    BACKGROUND: Cytosolic aldehyde dehydrogenase, or ALDH1A1, functions in ethanol detoxification, metabolism of neurotransmitters, and synthesis of retinoic acid. Because the promoter region of a gene can influence gene expression, the ALDH1A1 promoter regions were studied to identify polymorphism, to assess their functional significance, and to determine whether they were associated with a risk for developing alcoholism. METHODS: Sequence analysis was performed in the promoter region by using Asian, Caucasian, and African American subjects. The resulting polymorphisms were assessed for frequency in Asian, Caucasian, Jewish, and African American populations and tested for associations with alcohol dependence in Asian and African American populations of alcoholics and controls. The functional significance of each polymorphism was determined through in vitro expression analysis by using HeLa and HepG2 cells. RESULTS: Two polymorphisms, a 17 base pair (bp) deletion (-416/-432) and a 3 bp insertion (-524), were discovered in the ALDH1A1 promoter region: ALDH1A1*2 and ALDH1A1*3, respectively. ALDH1A1*2 was observed at frequencies of 0.035, 0.023, 0.023, and 0.012 in the Asian, Caucasian, Jewish, and African American populations, respectively. ALDH1A1*3 was observed only in the African American population, at a frequency of 0.029. By using HeLa and HepG2 cells for in vitro expression, the activity of the luciferase reporter gene was significantly decreased after transient transfection of ALDH1A1*3-luciferase compared with the wild-type construct ALDH1A1*1-luciferase. In an African American population, a trend for higher frequencies of the ALDH1A1*2 and ALDH1A1*3 alleles was observed in a population of alcoholics (p = 0.03 and f = 0.12, respectively) compared with the control population. CONCLUSIONS: ALDH1A1*2 and ALDH1A1*3 may influence ALDH1A1 gene expression. Both ALDH1A1*2 and ALDH1A1*3 produce a trend in an African American population that may be indicative of an association with alcoholism; however, more samples are required to validate this observation. The underlying mechanisms contributing to these trends are still unknown.
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    Kinetic Analysis of Primate and Ancestral Alcohol Dehydrogenases
    (2012-11-29) Myers, Candace R.; Hurley, Thomas D., 1961-; Goebl, Mark G.; Mosley, Amber L.
    Seven human alcohol dehydrogenase genes (which encode the primary enzymes involved in alcohol metabolism) are grouped into classes based on function and sequence identity. While the Class I ADH isoenzymes contribute significantly to ethanol metabolism in the liver, Class IV ADH isoenzymes are involved in the first-pass metabolism of ethanol. It has been suggested that the ability to efficiently oxidize ethanol occurred late in primate evolution. Kinetic data obtained from the Class I ADH isoenzymes of marmoset and brown lemur, in addition to data from resurrected ancestral human Class IV ADH isoenzymes, supports this proposal--suggesting that two major events which occurred during primate evolution resulted in major adaptations toward ethanol metabolism. First, while human Class IV ADH first appeared 520 million years ago, a major adaptation to ethanol occurred very recently (approximately 15 million years ago); which was caused by a single amino acid change (A294V). This change increases the catalytic efficiency of the human Class IV enzymes toward ethanol by over 79-fold. Secondly, the Class I ADH form developed 80 million years ago--when angiosperms first began to produce fleshy fruits whose sugars are fermented to ethanol by yeasts. This was followed by the duplication and divergence of distinct Class I ADH isoforms--which occurred during mammalian radiation. This duplication event was followed by a second duplication/divergence event which occurred around or just before the emergence of prosimians (some 40 million years ago). We examined the multiple Class I isoforms from species with distinct dietary preferences (lemur and marmoset) in an effort to correlate diets rich in fermentable fruits with increased catalytic capacity toward ethanol oxidation. Our kinetic data support this hypothesis in that the species with a high content of fermentable fruit in its diet possess greater catalytic capacity toward ethanol.
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    The liver isozyme of glycogen synthase
    (1987) Wang, Yuhuan