Donoso M Verónica, Hernández Felipe, Barra Rafael, Huidobro-Toro J Pablo
Laboratorio de Farmacología, Departamento de Biología, Facultad de Química y Biología, Universidad de Santiago de Chile, Santiago, Chile.
Centro de Investigación Biomédica y Aplicada (CIBAP), Escuela de Medicina, Facultad de Ciencias Médicas, Universidad de Santiago de Chile, Santiago, Chile.
Front Pharmacol. 2023 Jan 20;13:1031223. doi: 10.3389/fphar.2022.1031223. eCollection 2022.
The vesicular nucleotide transporter (VNUT) is critical for sympathetic co-transmission and purinergic transmission maintenance. To examine this proposal, we assessed whether the bisphosphonate clodronate, claimed as a potent VNUT blocker, modified spontaneous and/or the electrically evoked overflow of ATP/metabolites and NA from mesentery sympathetic perivascular nerve terminals. Additionally, in primary endothelial cell cultures derived from this tissue, we also evaluated whether clodronate interfered with ATP/metabolite cell outflow and metabolism of N-etheno adenosine 5'-triphosphate (eATP), N-etheno adenosine (eADO), and adenosine deaminase enzyme activity. Rat mesenteries were perfused in the absence or presence of .01-1,000 nM clodronate, 1-1,000 nM Evans blue (EB), and 1-10 µM DIDS; tissue perfusates were collected to determine ATP/metabolites and NA before, during, and after perivascular electrical nerve terminal depolarization. An amount of 1-1,000 nM clodronate did not modify the time course of ATP or NA overflow elicited by nerve terminal depolarization, and only 10 nM clodronate significantly augmented perfusate adenosine. Electrical nerve terminal stimulation increased tissue perfusion pressure that was significantly reduced only by 10 nM clodronate [90.0 ± 18.6 ( = 8) to 35.0 ± 10.4 ( = 7), = .0277]. As controls, EB, DIDS, or reserpine treatment reduced the overflow of ATP/metabolites and NA in a concentration-dependent manner elicited by nerve terminal depolarization. Moreover, mechanical stimulation of primary endothelial cell cultures from the rat mesentery added with 10 or 100 nM clodronate increased adenosine in the cell media. eATP was metabolized by endothelial cells to the same extent with and without 1-1,000 nM clodronate, suggesting the bisphosphonate did not interfere with nucleotide ectoenzyme metabolism. In contrast, extracellular eADO remained intact, indicating that this nucleoside is neither metabolized nor transported intracellularly. Furthermore, only 10 nM clodronate inhibited (15.5%) adenosine metabolism to inosine in endothelial cells as well as in a commercial crude adenosine deaminase enzyme preparation (12.7%), and both effects proved the significance ( < .05). Altogether, present data allow inferring that clodronate inhibits adenosine deaminase activity in isolated endothelial cells as in a crude extract preparation, a finding that may account for adenosine accumulation following clodronate mesentery perfusion.
囊泡核苷酸转运体(VNUT)对于交感神经共同传递和嘌呤能传递的维持至关重要。为了验证这一观点,我们评估了被认为是一种有效的VNUT阻断剂的双膦酸盐氯膦酸盐,是否会改变肠系膜交感神经血管周围神经末梢ATP/代谢产物和去甲肾上腺素(NA)的自发性和/或电诱发溢出。此外,在源自该组织的原代内皮细胞培养物中,我们还评估了氯膦酸盐是否会干扰ATP/代谢产物的细胞外流以及N-乙烯腺苷5'-三磷酸(eATP)、N-乙烯腺苷(eADO)的代谢和腺苷脱氨酶活性。在不存在或存在0.01 - 1000 nM氯膦酸盐、1 - 1000 nM伊文思蓝(EB)和1 - 10 μM二异丙基氟磷酸(DIDS)的情况下对大鼠肠系膜进行灌注;收集组织灌注液以测定血管周围神经末梢去极化之前、期间和之后的ATP/代谢产物和NA。1 - 1000 nM的氯膦酸盐并未改变神经末梢去极化引起的ATP或NA溢出的时间进程,只有10 nM氯膦酸盐显著增加了灌注液中的腺苷。电刺激神经末梢会增加组织灌注压力,只有10 nM氯膦酸盐能使其显著降低[从90.0 ± 18.6(n = 8)降至35.0 ± 10.4(n = 7),P = 0.0277]。作为对照,EB、DIDS或利血平处理会以浓度依赖的方式降低神经末梢去极化引起的ATP/代谢产物和NA的溢出。此外,对添加了10或100 nM氯膦酸盐的大鼠肠系膜原代内皮细胞培养物进行机械刺激会增加细胞培养基中的腺苷。无论有无1 - 1000 nM氯膦酸盐,内皮细胞对eATP的代谢程度相同,这表明双膦酸盐不会干扰核苷酸外切酶代谢。相反,细胞外的eADO保持不变,表明该核苷既不被代谢也不被转运到细胞内。此外,只有10 nM氯膦酸盐会抑制内皮细胞以及商业粗制腺苷脱氨酶制剂中腺苷向肌苷的代谢(分别为15.5%和12.7%),且两种作用均具有显著性(P < 0.05)。总之,目前的数据表明氯膦酸盐在分离出的内皮细胞以及粗提物制剂中均能抑制腺苷脱氨酶活性,这一发现可能解释了氯膦酸盐灌注肠系膜后腺苷的积累。
