Department of Radiology, Hadassah Medical Organization and Faculty of Medicine, Hebrew University of Jerusalem, Jerusalem, Israel.
The Wohl Institute for Translational Medicine, Hadassah Medical Organization, Jerusalem, Israel.
NMR Biomed. 2023 Oct;36(10):e4993. doi: 10.1002/nbm.4993. Epub 2023 Jul 10.
Disruption of acid-base balance is linked to various diseases and conditions. In the heart, intracellular acidification is associated with heart failure, maladaptive cardiac hypertrophy, and myocardial ischemia. Previously, we have reported that the ratio of the in-cell lactate dehydrogenase (LDH) to pyruvate dehydrogenase (PDH) activities is correlated with cardiac pH. To further characterize the basis for this correlation, these in-cell activities were investigated under induced intracellular acidification without and with Na /H exchanger (NHE1) inhibition by zoniporide. Male mouse hearts (n = 30) were isolated and perfused retrogradely. Intracellular acidification was performed in two ways: (1) with the NH Cl prepulse methodology; and (2) by combining the NH Cl prepulse with zoniporide. P NMR spectroscopy was used to determine the intracellular cardiac pH and to quantify the adenosine triphosphate and phosphocreatine content. Hyperpolarized [1- C]pyruvate was obtained using dissolution dynamic nuclear polarization. C NMR spectroscopy was used to monitor hyperpolarized [1- C]pyruvate metabolism and determine enzyme activities in real time at a temporal resolution of a few seconds using the product-selective saturating excitation approach. The intracellular acidification induced by the NH Cl prepulse led to reduced LDH and PDH activities (-16% and -39%, respectively). This finding is in line with previous evidence of reduced myocardial contraction and therefore reduced metabolic activity upon intracellular acidification. Concomitantly, the LDH/PDH activity ratio increased with the reduction in pH, as previously reported. Combining the NH Cl prepulse with zoniporide led to a greater reduction in LDH activity (-29%) and to increased PDH activity (+40%). These changes resulted in a surprising decrease in the LDH/PDH ratio, as opposed to previous predictions. Zoniporide alone (without intracellular acidification) did not change these enzyme activities. A possible explanation for the enzymatic changes observed during the combination of the NH Cl prepulse and NHE1 inhibition may be related to mitochondrial NHE1 inhibition, which likely negates the mitochondrial matrix acidification. This effect, combined with the increased acidity in the cytosol, would result in an enhanced H gradient across the mitochondrial membrane and a temporarily higher pyruvate transport into the mitochondria, thereby increasing the PDH activity at the expense of the cytosolic LDH activity. These findings demonstrate the complexity of in-cell cardiac metabolism and its dependence on intracellular acidification. This study demonstrates the capabilities and limitations of hyperpolarized [1- C]pyruvate in the characterization of intracellular acidification as regards cardiac pathologies.
酸碱平衡紊乱与各种疾病和病症有关。在心脏中,细胞内酸化与心力衰竭、适应性心肌肥大和心肌缺血有关。此前,我们已经报道过细胞内乳酸脱氢酶 (LDH) 与丙酮酸脱氢酶 (PDH) 活性的比值与心脏 pH 值有关。为了进一步描述这种相关性的基础,在没有 Na+/H 交换器 (NHE1) 抑制的情况下,通过 zoniporide 诱导细胞内酸化,并研究了这些细胞内活性。雄性小鼠心脏 (n=30) 被分离并逆行灌注。通过两种方式进行细胞内酸化:(1) 使用 NH4Cl 预脉冲方法;(2) 通过 NH4Cl 预脉冲与 zoniporide 相结合。 31P NMR 光谱用于确定细胞内心脏 pH 值,并定量测定三磷酸腺苷和磷酸肌酸含量。使用溶解动态核极化获得 hyperpolarized [1-13C] 丙酮酸。 13C NMR 光谱用于实时监测 hyperpolarized [1-13C] 丙酮酸代谢,并使用产物选择性饱和激发方法以几秒钟的时间分辨率确定酶活性。NH4Cl 预脉冲诱导的细胞内酸化导致 LDH 和 PDH 活性降低 (-16%和-39%,分别)。这一发现与先前关于细胞内酸化时心肌收缩力降低以及因此代谢活性降低的证据一致。同时,正如之前报道的,LDH/PDH 活性比随着 pH 值的降低而增加。将 NH4Cl 预脉冲与 zoniporide 结合使用导致 LDH 活性 (-29%) 进一步降低和 PDH 活性 (+40%) 增加。这些变化导致 LDH/PDH 比值出人意料地降低,与之前的预测相反。zoniporide 单独使用 (没有细胞内酸化) 不会改变这些酶活性。在 NH4Cl 预脉冲和 NHE1 抑制结合期间观察到的酶变化的可能解释可能与线粒体 NHE1 抑制有关,这可能否定了线粒体基质酸化。这种效应,加上细胞质中酸度的增加,会导致跨线粒体膜的 H 梯度增强,并且暂时增加丙酮酸向线粒体的转运,从而增加 PDH 活性,牺牲细胞质 LDH 活性。这些发现表明细胞内心脏代谢的复杂性及其对细胞内酸化的依赖性。本研究表明了 hyperpolarized [1-13C] 丙酮酸在心脏病理学方面表征细胞内酸化的能力和局限性。
