posted on 2015-12-17, 00:24authored byDoug K. Allen, Joshua Goldford, James K. Gierse, Dominic Mandy, Christine Diepenbrock, Igor G. L. Libourel
Isotopic labeling studies of primary
metabolism frequently utilize
GC/MS to quantify 13C in protein-hydrolyzed amino acids.
During processing some amino acids are degraded, which reduces the
size of the measurement set. The advent of high-resolution mass spectrometers
provides a tool to assess molecular masses of peptides with great
precision and accuracy and computationally infer information about
labeling in amino acids. Amino acids that are isotopically labeled
during metabolism result in labeled peptides that contain spatial
and temporal information that is associated with the biosynthetic
origin of the protein. The quantification of isotopic labeling in
peptides can therefore provide an assessment of amino acid metabolism
that is specific to subcellular, cellular, or temporal conditions.
A high-resolution orbital trap was used to quantify isotope labeling
in peptides that were obtained from unlabeled and isotopically labeled
soybean embryos and Escherichia coli cultures. Standard deviations were determined by estimating the
multinomial variance associated with each element of the m/z distribution. Using the estimated variance, quantification
of the m/z distribution across multiple
scans was achieved by a nonlinear fitting approach. Observed m/z distributions of uniformly labeled E. coli peptides indicated no significant differences
between observed and simulated m/z distributions. Alternatively, amino acid m/z distributions obtained from GC/MS were convolved to simulate
peptide m/z distributions but resulted
in distinct profiles due to the production of protein prior to isotopic
labeling. The results indicate that peptide mass isotopologue measurements
faithfully represent mass distributions, are suitable for quantification
of isotope-labeling-based studies, and provide additional information
over existing methods.