Funk Alexander M, Anderson Brian L, Wen Xiaodong, Hever Thomas, Khemtong Chalermchai, Kovacs Zoltan, Sherry A Dean, Malloy Craig R
Advanced Imaging Research Center, University of Texas Southwestern Medical Center, Dallas, TX, United States.
Advanced Imaging Research Center, University of Texas Southwestern Medical Center, Dallas, TX, United States; Department of Radiology, University of Texas Southwestern Medical Center, Dallas, TX, United States.
J Magn Reson. 2017 Nov;284:86-93. doi: 10.1016/j.jmr.2017.09.007. Epub 2017 Sep 18.
This study was designed to determine whether perdeuterated glucose experiences a kinetic isotope effect (KIE) as glucose passes through glycolysis and is further oxidized in the tricarboxylic acid (TCA) cycle. Metabolism of deuterated glucose was investigated in two groups of perfused rat hearts. The control group was supplied with a 1:1 mixture of [U-C]glucose and [1,6-C]glucose, while the experimental group received [U-C,U-H]glucose and [1,6-C]glucose. Tissue extracts were analyzed by H, H and proton-decoupled C NMR spectroscopy. Extensive H-C scalar coupling plus chemical shift isotope effects were observed in the proton-decoupled C NMR spectra of lactate, alanine and glutamate. A small but measureable (∼8%) difference in the rate of conversion of [U-C]glucose vs. [1,6-C]glucose to lactate, likely reflecting rates of CC bond breakage in the aldolase reaction, but conversion of [U-C]glucose versus [U-C,U-H]glucose to lactate did not differ. This shows that the presence of deuterium in glucose does not alter glycolytic flux. However, there were two distinct effects of deuteration on metabolism of glucose to alanine and oxidation of glucose in the TCA. First, alanine undergoes extensive exchange of methyl deuterons with solvent protons in the alanine amino transferase reaction. Second, there is a substantial kinetic isotope effect in metabolism of [U-C,U-H]glucose to alanine and glutamate. In the presence of [U-C,U-H]glucose, alanine and lactate are not in rapid exchange with the same pool of pyruvate. These studies indicate that the appearance of hyperpolarized C-lactate from hyperpolarized [U-C,U-H]glucose is not substantially influenced by a deuterium kinetic isotope effect.
本研究旨在确定全氘代葡萄糖在葡萄糖经糖酵解并在三羧酸(TCA)循环中进一步氧化时是否会经历动力学同位素效应(KIE)。在两组灌注大鼠心脏中研究了氘代葡萄糖的代谢。对照组供应[U-C]葡萄糖和[1,6-C]葡萄糖的1:1混合物,而实验组接受[U-C,U-H]葡萄糖和[1,6-C]葡萄糖。通过H、H和质子去耦C NMR光谱分析组织提取物。在乳酸、丙氨酸和谷氨酸的质子去耦C NMR光谱中观察到广泛的H-C标量耦合以及化学位移同位素效应。[U-C]葡萄糖与[1,6-C]葡萄糖转化为乳酸的速率存在微小但可测量(约8%)的差异,这可能反映了醛缩酶反应中C-C键断裂的速率,但[U-C]葡萄糖与[U-C,U-H]葡萄糖转化为乳酸的情况并无差异。这表明葡萄糖中氘的存在不会改变糖酵解通量。然而,氘代对葡萄糖代谢为丙氨酸以及葡萄糖在TCA中的氧化有两种不同的影响。首先,在丙氨酸氨基转移酶反应中,丙氨酸的甲基氘核与溶剂质子发生广泛交换。其次,[U-C,U-H]葡萄糖代谢为丙氨酸和谷氨酸存在显著的动力学同位素效应。在存在[U-C,U-H]葡萄糖的情况下,丙氨酸和乳酸与同一丙酮酸池并非快速交换。这些研究表明,超极化[U-C,U-H]葡萄糖产生的超极化C-乳酸的出现基本上不受氘动力学同位素效应的影响。
