1 research outputs found
Stable Isotope-Assisted Lipidomics Combined with Nontargeted Isotopomer Filtering, a Tool to Unravel the Complex Dynamics of Lipid Metabolism
Investigations
of complex metabolic mechanisms and networks have
become a focus of research in the postgenomic area, thereby creating
an increasing demand for sophisticated analytical approaches. One
such tool is lipidomics analysis that provides, a detailed picture
of the lipid composition of a system at a given time. Introducing
stable isotopes into the studied system can additionally provide information
on the synthesis, transformation and degradation of individual lipid
species. However, capturing the entire dynamics of lipid networks
is still a challenge. We developed and evaluated a novel strategy
for the in-depth analysis of the dynamics of lipid metabolism with
the capacity for high molecular specificity and network coverage.
The general workflow consists of stable isotope-labeling experiments,
ultrahigh-performance liquid chromatography (UHPLC)/high-resolution
Orbitrap-mass spectrometry (MS) lipid profiling and data processing
by a software tool for global isotopomer filtering and matching. As
a proof of concept, this approach was applied to the network-wide
mapping of dynamic lipid metabolism in primary human skeletal muscle
cells cultured for 4, 12, and 24 h with [U–<sup>13</sup>C]-palmitate.
In the myocellular lipid extracts, 692 isotopomers were detected that
could be assigned to 203 labeled lipid species spanning 12 lipid (sub)Âclasses.
Interestingly, some lipid classes showed high turnover rates but stable
total amounts while the amount of others increased in the course of
palmitate treatment. The novel strategy presented here has the potential
to open new detailed insights into the dynamics of lipid metabolism
that may lead to a better understanding of physiological mechanisms
and metabolic perturbations