Sala-Rabanal Monica, Loo Donald D F, Hirayama Bruce A, Wright Ernest M
Dept. of Physiology, David Geffen School of Medicine at UCLA, 10833 Le Conte Ave., 53-330 CHS, Los Angeles, CA 90095-1751, USA.
Am J Physiol Renal Physiol. 2008 Jun;294(6):F1422-32. doi: 10.1152/ajprenal.00030.2008. Epub 2008 Mar 26.
The human proton/oligopeptide cotransporters hPEPT1 and hPEPT2 have been targeted to enhance the bioavailability of drugs and prodrugs. Previously, we established the mechanisms of drug transport by hPEPT1. Here, we extend these studies to hPEPT2. Major variants hPEPT21 and hPEPT22 were expressed in Xenopus oocytes, and each was examined using radiotracer uptake and electrophysiological methods. Glycylsarcosine (Gly-Sar); the beta-lactam antibiotics ampicillin, amoxicillin, cephalexin, and cefadroxil; and the anti-neoplastics delta-aminolevulinic acid (delta-ALA) and bestatin induced inward currents, indicating that they are transported. Variations in transport rate were due to differences in affinity and in turnover rate: for example, cefadroxil was transported with higher apparent affinity but at a lower maximum velocity than Gly-Sar. Transport rates were highest at pH 5 and decreased significantly as the external pH was increased. Our results strongly suggest that the protein does not operate as a cotransporter in tissues where there is little or no pH gradient, such as choroid plexus, lung, or mammary gland. In the absence of substrates, rapid voltage jumps produced hPEPT2 capacitive currents at pH 7. These transients were significantly reduced at pH 5 but recovered on addition of substrates. The seven-state ordered kinetic model previously proposed for hPEPT1 accounts for the steady-state kinetics of neutral drug and dipeptide transport by hPEPT2. The model also explains the capacitive transients, the striking difference in pre-steady-state behavior between hPEPT2 and hPEPT1, and differences in turnover numbers for Gly-Sar and cefadroxil. No functional differences were found between the common variants hPEPT21 and hPEPT22.
人类质子/寡肽共转运体hPEPT1和hPEPT2已成为提高药物和前体药物生物利用度的靶点。此前,我们已确定hPEPT1的药物转运机制。在此,我们将这些研究扩展至hPEPT2。主要变体hPEPT21和hPEPT22在非洲爪蟾卵母细胞中表达,并分别采用放射性示踪剂摄取和电生理方法进行检测。甘氨酰肌氨酸(Gly-Sar)、β-内酰胺类抗生素氨苄西林、阿莫西林、头孢氨苄和头孢羟氨苄,以及抗肿瘤药δ-氨基乙酰丙酸(δ-ALA)和苯丁抑制素均可诱导内向电流,表明它们可被转运。转运速率的差异源于亲和力和周转速率的不同:例如,头孢羟氨苄的转运表观亲和力较高,但最大速度低于Gly-Sar。转运速率在pH 5时最高,随着外部pH升高而显著降低。我们的结果有力地表明,在脉络丛、肺或乳腺等几乎没有或不存在pH梯度的组织中,该蛋白不作为共转运体发挥作用。在无底物的情况下,快速电压阶跃在pH 7时产生hPEPT2电容性电流。这些瞬变在pH 5时显著降低,但在添加底物后恢复。先前为hPEPT1提出的七态有序动力学模型解释了hPEPT2对中性药物和二肽转运的稳态动力学。该模型还解释了电容性瞬变、hPEPT2和hPEPT1在稳态前行为上的显著差异,以及Gly-Sar和头孢羟氨苄周转数的差异。常见变体hPEPT21和hPEPT22之间未发现功能差异。
