Determination of Total
Concentration of Chemically
Labeled Metabolites as a Means of Metabolome Sample Normalization
and Sample Loading Optimization in Mass Spectrometry-Based Metabolomics
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Abstract
For mass spectrometry (MS)-based metabolomics, it is
important
to use the same amount of starting materials from each sample to compare
the metabolome changes in two or more comparative samples. Unfortunately,
for biological samples, the total amount or concentration of metabolites
is difficult to determine. In this work, we report a general approach
of determining the total concentration of metabolites based on the
use of chemical labeling to attach a UV absorbent to the metabolites
to be analyzed, followed by rapid step-gradient liquid chromatography
(LC) UV detection of the labeled metabolites. It is shown that quantification
of the total labeled analytes in a biological sample facilitates the
preparation of an appropriate amount of starting materials for MS
analysis as well as the optimization of the sample loading amount
to a mass spectrometer for achieving optimal detectability. As an
example, dansylation chemistry was used to label the amine- and phenol-containing
metabolites in human urine samples. LC-UV quantification of the labeled
metabolites could be optimally performed at the detection wavelength
of 338 nm. A calibration curve established from the analysis of a
mixture of 17 labeled amino acid standards was found to have the same
slope as that from the analysis of the labeled urinary metabolites,
suggesting that the labeled amino acid standard calibration curve
could be used to determine the total concentration of the labeled
urinary metabolites. A workflow incorporating this LC-UV metabolite
quantification strategy was then developed in which all individual
urine samples were first labeled with <sup>12</sup>C-dansylation and
the concentration of each sample was determined by LC-UV. The volumes
of urine samples taken for producing the pooled urine standard were
adjusted to ensure an equal amount of labeled urine metabolites from
each sample was used for the pooling. The pooled urine standard was
then labeled with <sup>13</sup>C-dansylation. Equal amounts of the <sup>12</sup>C-labeled individual sample and the <sup>13</sup>C-labeled
pooled urine standard were mixed for LC-MS analysis. This way of concentration
normalization among different samples with varying concentrations
of total metabolites was found to be critical for generating reliable
metabolome profiles for comparison