Abstract
Background: Stable isotope tracing is a powerful technique for following the fate of individual atoms through metabolic pathways. Measuring isotopic enrichment in metabolites provides quantitative insights into the biosynthetic network and enables flux analysis as a function of external perturbations. NMR and mass spectrometry are the techniques of choice for global profiling of stable isotope labeling patterns in cellular metabolites. However, meaningful biochemical interpretation of the labeling data requires both quantitative analysis and complex modeling. Here, we demonstrate a novel approach that involved acquiring and modeling the timecourses of 13C isotopologue data for UDP-N-acetyl-D-glucosamine (UDP-GlcNAc) synthesized from [U-13C]-glucose in human prostate cancer LnCaP-LN3 cells. UDP-GlcNAc is an activated building block for protein glycosylation, which is an important regulatory mechanism in the development of many prominent human diseases including cancer and diabetes.Results: We utilized a stable isotope resolved metabolomics (SIRM) approach to determine the timecourse of 13C incorporation from [U-13C]-glucose into UDP-GlcNAc in LnCaP-LN3 cells. 13C Positional isotopomers and isotopologues of UDP-GlcNAc were determined by high resolution NMR and Fourier transform-ion cyclotron resonance-mass spectrometry. A novel simulated annealing/genetic algorithm, called 'Genetic Algorithm for Isotopologues in Metabolic Systems' (GAIMS) was developed to find the optimal solutions to a set of simultaneous equations that represent the isotopologue compositions, which is a mixture of isotopomer species. The best model was selected based on information theory. The output comprises the timecourse of the individual labeled species, which was deconvoluted into labeled metabolic units, namely glucose, ribose, acetyl and uracil. The performance of the algorithm was demonstrated by validating the computed fractional 13C enrichment in these subunits against experimental data. The reproducibility and robustness of the deconvolution were verified by replicate experiments, extensive statistical analyses, and cross-validation against NMR data.Conclusions: This computational approach revealed the relative fluxes through the different biosynthetic pathways of UDP-GlcNAc, which comprises simultaneous sequential and parallel reactions, providing new insight into the regulation of UDP-GlcNAc levels and O-linked protein glycosylation. This is the first such analysis of UDP-GlcNAc dynamics, and the approach is generally applicable to other complex metabolites comprising distinct metabolic subunits, where sufficient numbers of isotopologues can be unambiguously resolved and accurately measured. © 2011 Moseley et al; licensee BioMed Central Ltd.
Figures
![Figure 1 Biosynthesis of UDP-N-acetyl-D-glucosamine (UDP-GlcNAc). The pathways from [U-13C]-glucose to the four biochemical subunits are outlined. The glucose moiety (red) is directly incorporated into UDP-GlcNAc. The acetyl moiety (blue) is incorporated via glycolysis. The ribose moiety (yellow) is incorporated via the pentose phosphate pathway and pyrimidine biosynthesis. The uracil moiety is derived from acetylCoA through the Krebs cycle to form aspartate where it is combined with carbamoyl phosphate leading to pyrimidine synthesis (green).](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/881c388c-7236-3463-91f1-5e5405096b57/thumbnail-9b74fc0e-25a7-4c16-8cf6-151f933fd69e-0.png)
![Figure 3 13C Labeling in metabolites that report on glycolysis, Krebs cycle and uracil biosynthesis. The two-dimensional 1H total correlation spectroscopy (TOCSY) spectrum was recorded at 18.8 T using an isotropic mixing time of 50 ms at a B1 field strength of 8 kHz. The 13C satellites of glutamate and glutamate in reduced glutathione C2H-C4H are shown in cyan. This pattern corresponds to a mixture of species, namely where both 13C atoms are labeled in the same molecule plus 13C212C4 and 12C213C4. In contrast, the patterns for Ala (red) and Lac (green) shows only the 13C313C2 plus 12C312C2 pattern. Aspartate (red) shows a similar pattern as glutamate, reflecting scrambling through the Krebs cycle [8,10,11], and is the same as in U in UTP.](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/881c388c-7236-3463-91f1-5e5405096b57/thumbnail-b098c48c-449d-4ed6-8f94-3a84fcc09639-2.png)
![Figure 5 NMR identification of UDP-hexoses. LN3 cells were grown in unlabeled glucose and extracted as described in the Methods section. One-dimensional 1H NMR spectra were recorded at 20°C, 800 MHz. Two-dimensional 1H total correlation spectroscopy (TOCSY) spectra were recorded at 600 MHz using a mixing time of 50 ms with a spin lock field strength of 8 kHz. (a) One-dimensional NMR spectrum. The sugar anomeric region shows several resonances that are double doublets, that is, a single proton scalar coupled to two different spin 1/2 nuclei. By comparison with standard spectra, these have been assigned to the glucose H1 of UDP-glucose, UDP-galactose (UDP-Gal), UDP-GalNAc and UDP-GlcNAc by 1H and 13C chemical shifts, splitting patterns, 13C labeling and two-dimensional TOCSY crosspeak patterns as described in the text. (b) Anomeric region of example TOCSY spectrum showing 13C satellites of glucose H1-H3 of UDP-GlcNAc due to incorporation of [U-13C]glucose. The satellite crosspeaks (denoted by red rectangles) represent the covalent linkages of H1 to H2 and H3 of the glucose moiety (labeled respectively as G1, G2 and G3), which were essentially completely labeled at 48 h. Crosses denote the crosspeaks of protons attached to 12C.](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/881c388c-7236-3463-91f1-5e5405096b57/thumbnail-4f399752-74a9-45a3-b924-6d0a32f0ef66-5.png)
![Figure 6 Timecourse changes of UDP-N-acetyl-D-glucosamine (UDP-GlcNAc) isotopologues in LN3 extracts as determined by Fourier transform-ion cyclotron resonance-mass spectrometry (FT-ICR-MS). (a) FT-ICR-MS spectra at 6, 34 and 48 h post [U-13C]-glucose labeling. The spectra are plotted by normalization to cellular concentrations for direct comparison. For clarity, only the isotopologues visible at this scale are tagged; it should be noted that by 34 h the monoisotopic UDP-GlcNAc (m0) was barely detectable (data not shown). As is evident from this figure, different isotopologues increased in intensity at different rates, resulting in changing isotopologue distributions. M0+5, 7-16 correspond to the UDP-GlcNAc isotopologues with 5 and 7 to 16 13C atoms, respectively. (b) Timecourses of intensity of selected mass isotopologues. The normalized intensities were obtained as described in the Methods section. Only mass isotopologues that reached a significant level are plotted. Symbols are defined in the figure. The lines only serve to connect the data points. M0, 5,6, 11-16 represent monoisotopic UDP-GlcNAc and isotopologues with 5, 6 and 11 to 16 13C atoms, respectively.](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/881c388c-7236-3463-91f1-5e5405096b57/thumbnail-6d3a32ab-bc30-44bd-b86e-c60119556ba1-6.png)
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Moseley, H. N. B., Lane, A. N., Belshoff, A. C., Higashi, R. M., & Fan, T. W. M. (2011). A novel deconvolution method for modeling UDP-N-acetyl-D-glucosamine biosynthetic pathways based on 13C mass isotopologue profiles under non-steady-state conditions. BMC Biology, 9. https://doi.org/10.1186/1741-7007-9-37
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