Your search keyword '"Lee, W. N."' showing total 8 results

1. Loss of regulation of lipogenesis in the Zucker diabetic (ZDF) rat.

Author

Lee, W.-N. Paul and Bassilian, Sara

Subjects

*LEPTIN, *LIPID synthesis

Abstract

Studies the role of leptin in the regulation of lipogenesis in rat. Effects of dietary macronutrient composition on lipogenesis; Synthesis of palmitate and stereate by chain elongation; Adaptation to changes in fat-to-carbohydrate ratio of the diet; Effects of the peripheral loss of leptin.

Published

2000

2. Measurement of gluconeogenesis and mass isotopomer analysis based on [U-13C] glucose.

Author

Radziuk, Jerry and Lee, W.-N. Paul

Subjects

*GLUCONEOGENESIS, *EXCHANGE reactions

Abstract

Evaluates methods in measuring rates of gluconeogenesis based on [U-13C] glucose label redistribution. Molecular approach to the estimation of gluconeogenesis rates; Interactions between the gluconeogenetic pathway and the tricarboxylic acid cycle; Basis of different methods in measuring gluconeogenesis rates.

Published

1999

3. Mass isotopomer study of the nonoxidative pathways of the pentose cycle with [1,2-13C2]glucose.

Author

Lee WN, Boros LG, Puigjaner J, Bassilian S, Lim S, and Cascante M

Subjects

Carbon Isotopes, Glucosephosphate Dehydrogenase metabolism, Humans, Lactic Acid metabolism, Palmitates metabolism, Pentoses metabolism, Ribose metabolism, Transaldolase metabolism, Transketolase metabolism, Tumor Cells, Cultured, Glucose metabolism, Pentose Phosphate Pathway physiology

Abstract

We present a single-tracer method for the study of the pentose phosphate pathway (PPP) using [1,2-13C2]glucose and mass isotopomer analysis. The metabolism of [1,2-13C2]glucose by the glucose-6-phosphate dehydrogenase, transketolase (TK), and transaldolase (TA) reactions results in unique pentose and lactate isotopomers with either one or two 13C substitutions. The distribution of these isotopomers was used to estimate parameters of the PPP using the model of Katz and Rognstad (J. Katz and R. Rognstad. Biochemistry 6: 2227-2247, 1967). Mass and position isotopomers of ribose, and lactate and palmitate (products from triose phosphate) from human hepatoma cells (Hep G2) incubated with 30% enriched [1,2-13C2]glucose were determined using gas chromatography-mass spectrometry. After 24-72 h incubation, 1.9% of lactate molecules in the medium contained one 13C substitution (m1) and 10% contained two 13C substitutions (m2). A similar m1-to-m2 ratio was found in palmitate as expected. Pentose cycle (PC) activity determined from incubation with [1,2-13C2]glucose was 5.73 +/- 0.52% of the glucose flux, which was identical to the value of PC (5.55 +/- 0.73%) determined by separate incubations with [1-13C] and [6-13C]glucose, 13C was found to be distributed in four ribose isotopomers ([1-13C]-, [5-13C]-, [1,2-13C2]-, and [4,5-13C2]ribose). The observed ribose isotopomer distribution was best matched with that provided from simulation by substituting 0.032 for TK and 0.85 for TA activity relative to glucose uptake into the model of Katz and Rognstad. The use of [1,2-13C2]glucose not only permits the determination of PC but also allows estimation of relative rates through the TK and TA reactions.

Published

1998

4. In vivo study of the biosynthesis of long-chain fatty acids using deuterated water.

Author

Ajie HO, Connor MJ, Lee WN, Bassilian S, Bergner EA, and Byerley LO

Subjects

Animals, Deuterium Oxide, Fatty Acids chemistry, Female, Male, Mice, Mice, Hairless, Models, Biological, Palmitates metabolism, Peptide Chain Elongation, Translational, Rats, Rats, Sprague-Dawley, Regression Analysis, Fatty Acids metabolism

Abstract

To determine the contributions of preexisting fatty acid, de novo synthesis, and chain elongation in long-chain fatty acid (LCFA) synthesis, the synthesis of LCFAs, palmitate (16:0), stearate (18:0), arachidate (20:0), behenate (22:0), and lignocerate (24:0), in the epidermis, liver, and spinal cord was determined using deuterated water and mass isotopomer distribution analysis in hairless mice and Sprague-Dawley rats. Animals were given 4% deuterated water for 5 days or 8 wk in their drinking water. Blood was withdrawn at the end of these times for the determination of deuterium enrichment, and the animals were killed to isolate the various tissues for lipid extraction for the determination of the mass isotopomer distributions. The mass isotopomer distributions in LCFA were incompatible with synthesis from a single pool of primer. The synthesis of palmitate, stearate, arachidate, behenate, and lignocerate followed the expected biochemical pathways for the synthesis of LCFAs. On average, three deuterium atoms were incorporated for every addition of an acetyl unit. The isotopomer distribution resulting from chain elongation and de novo synthesis can be described by the linear combination of two binomial distributions. The proportions of preexisting, chain elongation, and de novo-synthesized fatty acids as a percentage of the total fatty acids were determined using multiple linear regression analysis. Fractional synthesis was found to vary, depending on the tissue type and the fatty acid, from 47 to 87%. A substantial fraction (24-40%) of the newly synthesized molecules was derived from chain elongation of unlabeled (recycled) palmitate.

Published

1995

5. In vivo measurement of fatty acids and cholesterol synthesis using D2O and mass isotopomer analysis.

Author

Lee WN, Bassilian S, Ajie HO, Schoeller DA, Edmond J, Bergner EA, and Byerley LO

Subjects

Animals, Deuterium Oxide, Gas Chromatography-Mass Spectrometry, Isotope Labeling methods, Kinetics, Male, Rats, Rats, Sprague-Dawley, Time Factors, Brain metabolism, Cholesterol biosynthesis, Liver metabolism, Sciatic Nerve metabolism, Spinal Cord metabolism, Stearic Acids metabolism

Abstract

The synthesis of palmitate, stearate, and cholesterol in liver and nervous tissues (brain, cord, and nerve) of Sprague-Dawley rats was determined using deuterated water (D2O) and mass isotopomer analysis. Rats were given 4% deuterium in their drinking water after each receiving an intraperitoneal priming dose. Animals were killed at 1, 2, 4, and 8 wk for deuterium enrichment in body water and determination of mass isotopomer distribution in lipids from various tissues. In 1 wk, the enrichment in the body water reached a plateau of 2.6%, which is 65% of that in the drinking water. We observed the maximum incorporation number (N) in all lipids to be higher than those previously observed, being 22, 24, and 30 for liver palmitate, stearate, and cholesterol, respectively, and N may vary among tissues. Using a single exponential model, we found the half-time (t1/2) and the plateau levels of the newly synthesized lipids of the nervous tissues (t1/2 values ranging from 5 to 28 days) to be different from those of the liver (t1/2 values < or = 4 days) in this relatively long-term study. Mass isotopomer distribution analysis and D2O can be used not only to quantitate the replacement rate of many lipids in various compartments but may also be used to elucidate the tissue-specific synthetic pathways from N.

Published

1994

6. Measurement of fractional lipid synthesis using deuterated water (2H2O) and mass isotopomer analysis.

Author

Lee WN, Bassilian S, Guo Z, Schoeller D, Edmond J, Bergner EA, and Byerley LO

Subjects

Animals, Cholesterol biosynthesis, Evaluation Studies as Topic, Glucose pharmacology, Humans, Liver Neoplasms, Experimental metabolism, Liver Neoplasms, Experimental pathology, Models, Biological, Palmitic Acid, Palmitic Acids metabolism, Sarcoma, Experimental metabolism, Sarcoma, Experimental pathology, Stearic Acids metabolism, Tissue Distribution, Tumor Cells, Cultured, Deuterium Oxide, Lipids biosynthesis, Physiology methods

Abstract

Fractional biosynthesis of palmitate, stearate, and cholesterol was determined with deuterated water (2H2O) using mass isotopomer analysis in Hep G2 and MCA sarcoma cells in culture. The method employed differs from previous ones in that the number of deuterium atoms from 2H2O incorporated into newly synthesized molecules was determined and not assumed. After correction for background natural abundances, the isotopomer distribution due to deuterium incorporation in fatty acids and cholesterol was shown to follow a simple binomial distribution depending on the deuterium enrichment in water (p) and the maximum number of deuterium atoms incorporated per molecule (N). Under a wide range of 2H2O enrichments, N could be determined to be 17 for palmitate, 20 for stearate, and 20 for cholesterol by regression analysis or from a series of consecutive mass isotopomer ratios. The fraction derived from de novo synthesis was given by the ratio of the observed to the theoretical deuterium enrichment, which is the product (N x p). The new synthesized fraction of palmitate and stearate by Hep G2 cells for the length of the experiment was found to be 77 and 65%, respectively. These values were confirmed by experiments with [U-13C]glucose as the precursor. In MCA sarcoma cells grown in lipid-poor medium, the average values for fractional synthesis of palmitate, stearate, and cholesterol were 70, 35, and 70%, respectively. This approach should be generally applicable to the simultaneous determined of fractional synthesis of a number of compounds with either deuterium or 13C tracers. Its application is only limited by the accuracy of mass spectrometric analysis.

Published

1994

7. Application of mass isotopomer analysis for determination of pathways of glycogen synthesis.

Author

Katz J and Lee WN

Subjects

Animals, Carbon Isotopes, Gas Chromatography-Mass Spectrometry methods, Hexosephosphates metabolism, Isotope Labeling methods, Liver metabolism, Glucose metabolism, Liver Glycogen biosynthesis

Abstract

An elementary exposition of the application of mass spectroscopy to studies with substrates labeled uniformly with 13C is presented. A procedure to obtain mass isotopomer spectra, corrected for natural abundance, of products labeled with 13C in several positions is outlined. The calculation for enrichment, a term equivalent to specific activity with radioisotopes, is shown. Examples of mass isotopomer patterns of blood glucose and glycogen are presented, and calculations of the contribution of the direct path to hepatic glycogen synthesis and the dilution of glucose-derived pyruvate are shown. The analysis of mass isotopomer patterns recently offered by C. Des Rosiers, B. R. Landau, and H. Brunengraber [Am. J. Physiol. 259 (Endocrinol. Metab. 22): E757-E762, 1990] is critically examined.

Published

1991

8. Blood glucose turnover during high- and low-intensity exercise.

Author

Cooper DM, Barstow TJ, Bergner A, and Lee WN

Subjects

Adult, Epinephrine blood, Heart physiology, Heart Rate, Humans, Insulin blood, Lactates blood, Male, Norepinephrine blood, Oxygen Consumption, Pulmonary Gas Exchange, Respiratory Physiological Phenomena, Rest, Blood Glucose metabolism, Exercise

Abstract

We hypothesized that whole body glucose uptake (Rd) during exercise is not related in a simple, linear manner to O2 uptake (VO2). To test this, seven healthy male subjects (age range 23-34 yr) were studied in the postabsorptive but not glycogen-depleted state. Three conditions were examined: 1) rest, 2) 40 min of constant exercise in which the work rates were carefully chosen to consist of low-intensity exercise (no elevated blood lactate, a mean of 40% maximal VO2), and 3) 40 min of high-intensity exercise (markedly elevated blood lactate, 79% maximal VO2). Gas exchange was measured breath by breath, and glucose uptake and production were measured using [6,6-2H2]glucose. Low-intensity exercise (n = 7) resulted in a small but not statistically significant increase in mean Rd [3.06 +/- 0.37 (SE) mg.min-1.kg-1] compared with resting values (2.87 +/- 0.39 mg.min-1.kg-1) despite a fourfold increase in the production of CO2 and VO2. By contrast, the high-intensity exercise Rd (n = 5, 6.98 +/- 0.67 mg.min-1.kg-1) was significantly greater than the resting value (3.03 +/- 0.56 mg.min-1.kg-1). Results of glucose production were virtually the same. Similarly, mean levels of epinephrine and norepinephrine increased significantly above resting values during high- but not low-intensity exercise. Our data demonstrate that whole body glucose dynamics and regulation during 40 min of exercise do not change in a simple linear manner with respect to metabolic rate.

Published

1989