Mass isotopomer distribution analysis at eight years: theoretical, analytic, and experimental considerations

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Mass isotopomer distribution analysis at eight years: theoretical, analytic, and experimental considerations

Marc K. Hellerstein¹^,² and Richard A. Neese¹^,²

¹ Department of Nutritional Sciences, University of California at Berkeley, Berkeley 94720; and ² Division of Endocrinology and Metabolism, Department of Medicine, University of California, San Francisco, California 94110

Mass isotopomer distribution analysis (MIDA) is a technique for measuring the synthesis of biological polymers. First developedapproximately eight years ago, MIDA has been used for measuringthe synthesis of lipids, carbohydrates, and proteins. The techniqueinvolves quantifying by mass spectrometry the relative abundancesof molecular species of a polymer differing only in mass (massisotopomers), after introduction of a stable isotope-labeled precursor.The mass isotopomer pattern, or distribution, is analyzed accordingto a combinatorial probability model by comparing measured abundancesto theoretical distributions predicted from the binomial or multinomialexpansion. For combinatorial probabilities to be applicable, alabeled precursor must therefore combine with itself in the formof two or more repeating subunits. MIDA allows dilution in themonomeric (precursor) and polymeric (product) pools to be determined.Kinetic parameters can then be calculated (e.g., replacement rateof the polymer, fractional contribution from the endogenous biosyntheticpathway, absolute rate of biosynthesis). Several issues remainunresolved, however. We consider here the impact of various deviationsfrom the simple combinatorial probability model of biosynthesisand describe the analytic requirements for successful use of MIDA.A formal mathematical algorithm is presented for generating tablesand equations (Appendix), on the basis of which effects of variousconfounding factors are simulated. These include variations innatural isotope abundances, isotopic disequilibrium in the precursorpool, more than one biosynthetic precursor pool, incorrect valuesfor number of subunits present, and concurrent measurement ofturnover from exogenously labeled polymers. We describe a strategyfor testing whether isotopic inhomogeneity (e.g., an isotopicgradient or separate biosynthetic sites) is present in the precursorpool by comparing higher-mass (multiply labeled) to lower-mass(single- and double-labeled) isotopomer patterns. Also, an algebraiccorrection is presented for calculating fractional synthesis whenan incomplete ion spectrum is monitored, and an approach for assessingthe sensitivity of biosynthetic parameters to measurement erroris described. The different calculation algorithms published forMIDA are compared; all share a common model, use overlapping solutionsto computational problems, and generate identical results. Finally,we discuss the major practical issue for using MIDA at present:quantitative inaccuracy of instruments. The nature and causesof analytic inaccuracy, strategies for evaluating instrument performance,and guidelines for optimizing accuracy and reducing impact onbiosynthetic parameters are suggested. Adherence to certain analyticguidelines, particularly attention to concentration effects onmass isotopomer ratios and maximizing enrichments in the isotopomersof interest, reduces error. Improving instrument accuracy forquantification of isotopomer ratios is perhaps the highest priorityfor this field. In conclusion, MIDA remains the "equation forbiosynthesis," but attention to potentially confounding factorsand analytic performance is required for optimalapplication.

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