Gensburger Olivier, Picard Nicolas, Marquet Pierre
INSERM UMR-S850, Limoges, France.
Clin Chem. 2009 May;55(5):986-93. doi: 10.1373/clinchem.2008.113936. Epub 2009 Mar 19.
The immunosuppressive effect of mycophenolic acid (MPA) is essentially attributed to IMPDH II inhibition, which leads to a reduction of lymphocyte proliferation. We investigated the action of the MPA metabolites MPA-phenyl-glucuronide (MPAG) and MPA-acyl-glucuronide (AcMPAG) on recombinant human IMPDH II (rhIMPDH II), as well as their passage into lymphocytes in vitro.
We measured rhIMPDH II activity spectrophotometrically through the initial velocity of NADH formation, leading to the computation of the kinetic parameters K(m), IC(50), and K(i) (Michaelis constant, half-maximal inhibition concentration, and inhibition constant). We measured intracellular and extracellular concentrations of MPA, MPAG, and AcMPAG after incubation of Jurkat lymphoma cells with each compound separately, using liquid chromatography-tandem mass spectrometry.
MPA and AcMPAG showed an inhibition of rhIMPDH II (IC(50) 25.6 microg/L and 301.7 microg/L, respectively; the K(i) of MPA for NAD and IMP was 50.8 and 57.7 nmol/L, respectively; and that of AcMPAG for NAD and IMP was 382.0 and 511.0 nmol/L. MPAG had no significant effect on the enzyme. AcMPAG apparently acts by the same uncompetitive inhibition mechanism as MPA, with a 12-fold higher IC(50) and an 8-10 times higher K(i). When coincubated with MPA, AcMPAG activity was negligible at pharmacological concentrations. Furthermore, after 6-h incubation at their respective maximum concentration (C(max)), MPA was 10 times more concentrated in Jurkat cells than AcMPAG.
AcMPAG is a weaker inhibitor of rhIMPDH II than MPA and is less concentrated in lymphocytes in vitro, suggesting that it would not be pharmacologically active in vivo and might not need to be monitored in MPA-treated patients.
霉酚酸(MPA)的免疫抑制作用主要归因于对肌苷-5'-单磷酸脱氢酶II(IMPDH II)的抑制,这会导致淋巴细胞增殖减少。我们研究了MPA代谢产物MPA-苯基-葡萄糖醛酸苷(MPAG)和MPA-酰基-葡萄糖醛酸苷(AcMPAG)对重组人IMPDH II(rhIMPDH II)的作用,以及它们在体外进入淋巴细胞的情况。
我们通过NADH形成的初始速度用分光光度法测量rhIMPDH II活性,从而计算动力学参数K(m)、IC(50)和K(i)(米氏常数、半数最大抑制浓度和抑制常数)。在用每种化合物分别孵育Jurkat淋巴瘤细胞后,我们使用液相色谱-串联质谱法测量MPA、MPAG和AcMPAG的细胞内和细胞外浓度。
MPA和AcMPAG对rhIMPDH II有抑制作用(IC(50)分别为25.6μg/L和301.7μg/L;MPA对NAD和IMP的K(i)分别为50.8和57.7nmol/L;AcMPAG对NAD和IMP的K(i)分别为382.0和511.0nmol/L。MPAG对该酶无显著影响。AcMPAG显然与MPA通过相同的非竞争性抑制机制起作用,但IC(50)高12倍,K(i)高8 - 10倍。当与MPA共同孵育时,在药理浓度下AcMPAG的活性可忽略不计。此外,在各自的最大浓度(C(max))下孵育6小时后,MPA在Jurkat细胞中的浓度比AcMPAG高10倍。
AcMPAG作为rhIMPDH II的抑制剂比MPA弱,且在体外淋巴细胞中的浓度较低,这表明它在体内可能没有药理活性,在接受MPA治疗的患者中可能无需进行监测。
