High-Throughput Measurement of Lipid Turnover Rates Using Partial Metabolic Heavy Water Labeling

Goh, Byoungsook; Kim, Jin-Woo; Seo, Seungwoo; Kim, Tae‐Young

doi:10.1021/acs.analchem.7b05428

Cited by 11 publications

(12 citation statements)

References 44 publications

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“…Thus, the convergence of lipidomics and metabolomics can be anticipated to provide extraordinary insight into myelinomics. An indication of the analytical and quantitative power of this approach has been demonstrated using HeLa cells [64,65]. In short, we anticipate that our correlated structural and biochemical study will promote a broad, comprehensive approach that is informative about structure, function, and metabolism in both health and disease.…”

Section: Discussionmentioning

confidence: 96%

“…Thus, the convergence of lipidomics and metabolomics can be anticipated to provide extraordinary insight into myelinomics. The analytic and quantitative power of this approach has been demonstrated using HeLa cells (Goh et al, 2018; Kim et al, 2019). Further, in the experimental paradigm we used here for stable isotope incorporation via D 2 O-spiked drinking water, not only was myelin labeled, but one can surmise a priori that all tissues in the mice were deuterated, and differentially for the pups vs. the dam.…”

Section: Discussionmentioning

confidence: 99%

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Metabolically-Incorporated Deuterium in Myelin Localized by Neutron Diffraction and Identified by Mass Spectrometry

Baumann

Denninger

Domin

et al. 2021

Preprint

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Myelin is a natural and dynamic multilamellar membrane structure that continues to be of significant biological and neurological interest, especially its biosynthesis and assembly in the context of its normal formation and renewal, and pathological breakdown. To explore further the usefulness of neutron diffraction in the structural analysis of myelin, we investigated the use of in vivo labeling by metabolically incorporating via drinking water nontoxic levels of deuterium (2H; D) into pregnant dams and their developing embryos. All of the mice were sacrificed when the pups were about 60 days old. Myelinated nerves were dissected, fixed in glutaraldehyde and examined by neutron diffraction. Parallel samples that were unfixed were frozen for mass spectrometry (MS). Analysis of the neutron diffraction patterns of the sciatic nerves from deuterium-fed mice (D mice) versus the controls (H mice) showed no appreciable differences in myelin periodicity, but major differences in the intensities of the Bragg peaks. The neutron scattering density profiles showed an appreciable increase in density at the center of the membrane bilayer in the D mice, particularly in the pups. MS analysis of the lipids isolated from the trigeminal nerves demonstrated that the level of D was greater in the pups compared to their mother: 97.6% +/- 2.0% (n=54; range 89.6% to 99.6%) versus 60.6% +/- 26.4% (n=27; range 11.4% to 97.3%). Deuteration in the mother also varied by lipid species, and among lipid subspecies. Three molecular species of phosphatidylcholine (PC), phosphatidylinositol (PI), and diglycerol (DG) were the most deuterated lipids, and sulfatide (SHexCer), one species of sphingomyelin (SM), and triacylglycerol (TG) were the least deuterated. The distribution pattern of deuterium in the D pups was always bell-shaped, and the average number of D atoms ranged from a low of ~4 in fatty acid (FA), to a high of ~9 in cerebroside (HexCer). By contrast, in D dam only about one third of the lipids had symmetric bell-shaped distributions; most had more complex, overlapping distributions that were weighted toward a lower average number of D atom labels. The average number of D atoms ranged from a low of ~3 to 4 in FA and in one species of SHexCer, to a high of 6 to 7 in HexCer and SM. In D pups, the consistently high level of deuteration can be attributed to their de novo lipogenesis during gestation and continuation of rapid myelination postnatally. In D dam, the widely varying levels of deuteration of lipids likely depends on the relative metabolic stability of the particular lipid species during myelin maintenance in the mature animal. Our current findings demonstrate that stably-incorporated D label can be detected and localized using neutron diffraction in a complex tissue such as myelin; and moreover, that MS can be used to screen a broad range of deuterated lipid species to monitor differential rates of lipid turnover. In addition to helping to develop a comprehensive understanding of the de novo synthesis and turnover of specific lipids in normal and abnormal myelin, our results also suggest application to myelin proteins, as well as more broadly to the molecular constituents of other biological tissues.

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Section: Discussionmentioning

confidence: 96%

Section: Discussionmentioning

confidence: 99%

Metabolically-Incorporated Deuterium in Myelin Localized by Neutron Diffraction and Identified by Mass Spectrometry

Baumann

Denninger

Domin

et al. 2021

Preprint

View full text Add to dashboard Cite

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“…However, the equations are general. They can be used for other atom-based labeling agents, ,, such as 15 N and 12 C, or for other biomolecules such as lipids …”

Section: Introductionmentioning

confidence: 99%

“…They can be used for other atom-based labeling agents, 4,10,11 such as 15 N and 12 C, or for other biomolecules such as lipids. 12 1.1. Data Description.…”

Section: Introductionmentioning

confidence: 99%

Partial Isotope Profiles Are Sufficient for Protein Turnover Analysis Using Closed-Form Equations of Mass Isotopomer Dynamics

Sadygov

2020

Anal. Chem.

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Metabolic labeling with atom-based heavy isotopes, followed by liquid chromatography coupled with mass spectrometry (LC–MS), has been a powerful technique for studies of proteome and metabolome. In proteomics, the protein turnover of thousands of proteins can be estimated from the gradual incorporation of 2H or 15N in the diet. Software tools have been developed to automate the estimation of protein turnover. Traditionally, the turnover has been estimated using the time course of the depletion of the normalized abundance of monoisotopes. While the bioinformatic aspects of peak detection and integration, time course modeling, and uncertainty estimation have progressed, mass isotopomer dynamics during label incorporation has only been modeled from approximate approaches or numerical simulations. We derive closed-form equations that describe the dynamics of mass isotopomers during metabolic labeling with an atom-based stable isotope. The derived equations create an alternative method for estimating label incorporation. They also provide opportunities for estimation of precursor–product relationships in species or systems where they are unknown. The equations are useful in bioinformatic tools for analyzing mass spectral data from metabolic labeling.

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“…The time course of the label incorporation is modeled to extract the degradation rate constants of proteins. − Bioinformatics tools ,− have been developed for processing high-throughput datasets. A similar approach has been used to analyze lipidome dynamics as well . In the time-course models, dense sampling provides accurate rate constant estimations.…”

Section: Introductionmentioning

confidence: 99%

Timepoint Selection Strategy for In Vivo Proteome Dynamics from Heavy Water Metabolic Labeling and LC–MS

2020

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Protein homeostasis, proteostasis, is essential for healthy cell functioning and is dysregulated in many diseases. Metabolic labeling with heavy water followed by liquid chromatography coupled online to mass spectrometry (LC–MS) is a powerful high-throughput technique to study proteome dynamics in vivo. Longer labeling duration and dense timepoint sampling (TPS) of tissues provide accurate proteome dynamics estimations. However, the experiments are expensive, and they require animal housing and care, as well as labeling with stable isotopes. Often, the animals are sacrificed at selected timepoints to collect tissues. Therefore, it is necessary to optimize TPS for a given number of sampling points and labeling duration and target a specific tissue of study. Currently, such techniques are missing in proteomics. Here, we report on a formula-based stochastic simulation strategy for TPS for in vivo studies with heavy water metabolic labeling and LC–MS. We model the rate constant (lognormal), measurement error (Laplace), peptide length (gamma), relative abundance of the monoisotopic peak (beta regression), and the number of exchangeable hydrogens (gamma regression). The parameters of the distributions are determined using the corresponding empirical probability density functions from a large-scale dataset of murine heart proteome. The models are used in the simulations of the rate constant to minimize the root-mean-square error (rmse). The rmse for different TPSs shows structured patterns. They are analyzed to elucidate common features in the patterns.

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High-Throughput Measurement of Lipid Turnover Rates Using Partial Metabolic Heavy Water Labeling

Cited by 11 publications

References 44 publications

Metabolically-Incorporated Deuterium in Myelin Localized by Neutron Diffraction and Identified by Mass Spectrometry

Metabolically-Incorporated Deuterium in Myelin Localized by Neutron Diffraction and Identified by Mass Spectrometry

Partial Isotope Profiles Are Sufficient for Protein Turnover Analysis Using Closed-Form Equations of Mass Isotopomer Dynamics

Timepoint Selection Strategy for In Vivo Proteome Dynamics from Heavy Water Metabolic Labeling and LC–MS

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