Abstract
Compound identification is a major bottleneck in metabolomics studies. In nuclear magnetic resonance (NMR) investigations, resonance overlap often hinders unambiguous database matching or de novo compound identification. In liquid chromatography-mass spectrometry (LC-MS), discriminating between biological signals and background artifacts and reliable determination of molecular formulae are not always straightforward. We have designed and implemented several NMR and LC-MS approaches that utilize 13C, either enriched or at natural abundance, in metabolomics applications. For LC-MS applications, we describe a technique called isotopic ratio outlier analysis (IROA), which utilizes samples that are isotopically labeled with 5% (test) and 95% (control) 13C. This labeling strategy leads to characteristic isotopic patterns that allow the differentiation of biological signals from artifacts and yield the exact number of carbons, significantly reducing possible molecular formulae. The relative abundance between the test and control samples for every IROA feature can be determined simply by integrating the peaks that arise from the 5 and 95% channels. For NMR applications, we describe two 13C-based approaches. For samples at natural abundance, we have developed a workflow to obtain 13C–13C and 13C–1H statistical correlations using 1D 13C and 1H NMR spectra. For samples that can be isotopically labeled, we describe another NMR approach to obtain direct 13C–13C spectroscopic correlations. These methods both provide extensive information about the carbon framework of compounds in the mixture for either database matching or de novo compound identification. We also discuss strategies in which 13C NMR can be used to identify unknown compounds from IROA experiments. By combining technologies with the same samples, we can identify important biomarkers and corresponding metabolites of interest.
Highlights
Metabolomics and natural product studies share many common goals
We found that using 13C nuclear magnetic resonance (NMR) at natural abundance led to improved performance in both principal component analysis (PCA) and PLS-DA
In (A) we show 2D statistical total correlation spectroscopy (STOCSY) and SHY correlation maps that were produced from the same mixture of 20 common metabolites that are shown in data
Summary
Metabolomics and natural product studies share many common goals. we and others have argued that the two fields are essentially the same (Robinette et al, 2012). NMR and MS, commonly used in natural products studies, can be efficiently applied to complex metabolic mixtures through the simplification of spectra by 13C filtering. Direct 13C correlations that can be obtained from NMR studies are an extremely effective way to determine the identity of unknown metabolites or ones that are not in databases With all of these advantages of 13C, why is it not more commonly used in NMR? We will show how 13C can be used at natural abundance in NMR metabolomics studies (Clendinen et al, 2014) This relatively simple approach can provide much more robust compound identification through database matching than by using 1H NMR alone. Some interesting recent applications of whole plant labeling include: (1) the examination of carbon flux in isoprenoid pathways in poplar grown with 13CO2 (Ghirardo et al, 2014), (2) the identification of sulfur-containing metabolites from onions using high-resolution FT-ICR MS (Nakabayashi et al, 2013), (3) the 13C isotopic labeling of tomatoes (Moran et al, 2013) and parsley, spinach, and peppermint (Gleichenhagen et al, 2013) to obtain biologically active phytochemicals for human metabolic studies, and (4) the 13CO2 labeling of potato plants to identify metabolites that are released by their roots and are subsequently incorporated into fungi in the rhizosphere (Hannula et al, 2012)
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