Labelled D-Glucose is a simple sugar that is present in plants. A monosaccharide that may exist in open chain or cyclic conformation if in solution. It plays a crucial role in photosynthesis and energy source required for cellular respiration. D-Glucose is used in various metabolic processes including the enzymic synthesis of cyclohexyl-α and β-D-glucosides. Can also be used as a diagnostic tool in type 2 diabetes mellitus detection and potentially Huntington's disease through blood-glucose analysis in type 1 diabetes mellitus.
Reference Reading
1. Synthesis of Bradyrhizose from d-Glucose
Philemon Ngoje, David Crich. Org Lett. 2020 Jan 17;22(2):523-527. doi: 10.1021/acs.orglett.9b04279.
We describe the synthesis of the unusual bicyclic sugar bradyrhizose in 14 steps and a 6% overall yield from d-glucose. The synthesis involves the elaboration of a trans-fused carbocyclic ring onto the preexisting glucopyranose framework followed by adjustment of the oxidation levels. Key steps include radical extension of the glucopyranose side chain, ring closing metathesis, allylic oxidation, Luche reduction, hydroxy-directed epoxidation, and acid-catalyzed epoxide opening at the more substituted position.
2. Effects of D-glucose upon D-fructose metabolism in rat hepatocytes: A 13C NMR study
W J Malaisse, L Ladrière, I Verbruggen, R Willem. Mol Cell Biochem. 2002 Dec;241(1-2):103-6. doi: 10.1023/a:1020818810935.
Isolated hepatocytes from fed rats were exposed for 120 min to D-glucose (10 mM) and either D-[1-13C]fructose, D-[2-13C]fructose or D-[6-13C]fructose (also 10 mM) in the presence of D2O. The identification and quantification of 13C-enriched D-fructose and its metabolites (D-glucose, L-lactate, L-alanine) in the incubation medium and the measurement of their deuterated isotopomers indicated, by comparison with a prior study conducted in the absence of exogenous D-glucose, that the major effects of the aldohexose were to increase the recovery of 13C-enriched D-fructose, decrease the production of 13C-enriched D-glucose, restrict the deuteration of the 13C-enriched isotopomers of D-glucose to those generated by cells exposed to D-[2-13C]fructose, and to accentuate the lesser deuteration of the C, (as compared to C5) of 13C-enriched D-glucose derived from D-[2-13C]fructose. The ratio between C2-deuterated and C2-hydrogenated L-lactate, as well as the relative amounts of the CH3-, CH2D-, CHD, and CD3- isotopomers of 13C-enriched L-lactate were not significantly different, however, in the absence or presence of exogenous D-glucose. These findings indicate that exogenous D-glucose suppressed the deuteration of the C1 of D-[I-13C]glucose generated by hepatocytes exposed to D-[1-13C]fructose or D-[6-13C]fructose, as otherwise attributable, in part at least, to gluconeogenesis from fructose-derived [3-13C]pyruvate, and apparently favoured the phosphorylation of D-fructose by hexokinase isoenzymes, probably through stimulation of D-fructose phosphorylation by glucokinase.
3. D-Glucose and D-mannose-based metabolic probes. Part 3: Synthesis of specifically deuterated D-glucose, D-mannose, and 2-deoxy-D-glucose
Izabela Fokt, Stanislaw Skora, Charles Conrad, Timothy Madden, Mark Emmett, Waldemar Priebe. Carbohydr Res. 2013 Mar 7;368:111-9. doi: 10.1016/j.carres.2012.11.021.
Altered carbohydrate metabolism in cancer cells was first noted by Otto Warburg more than 80 years ago. Upregulation of genes controlling the glycolytic pathway under normoxia, known as the Warburg effect, clearly differentiates malignant from non-malignant cells. The resurgence of interest in cancer metabolism aims at a better understanding of the metabolic differences between malignant and non-malignant cells and the creation of novel therapeutic and diagnostic agents exploiting these differences. Modified d-glucose and d-mannose analogs were shown to interfere with the metabolism of their respective monosaccharide parent molecules and are potentially clinically useful anticancer and diagnostic agents. One such agent, 2-deoxy-d-glucose (2-DG), has been extensively studied in vitro and in vivo and also clinically evaluated. Studies clearly indicate that 2-DG has a pleiotropic mechanism of action. In addition to effectively inhibiting glycolysis, 2-DG has also been shown to affect protein glycosylation. In order to better understand its molecular mechanism of action, we have designed and synthesized deuterated molecular probes to study 2-DG interference with d-glucose and d-mannose metabolism using mass spectrometry. We present here the synthesis of all desired probes: 2-deutero-d-glucose, 2-deutero-d-mannose, 6-deutero-d-glucose, 6-deutero-d-mannose, and 2-deutero-2-deoxy-d-glucose as well as their complete chemical characterization.