Gross S S, Jaffe E A, Levi R, Kilbourn R G
Department of Pharmacology, Cornell University Medical College, New York, NY 10021.
Biochem Biophys Res Commun. 1991 Aug 15;178(3):823-9. doi: 10.1016/0006-291x(91)90965-a.
We have previously reported that cultured murine brain endothelial cells (MBE) produce large quantities of nitric oxide (NO) after activation with interferon-gamma in combination with any of several immunoactivators including: bacterial endotoxin, tumor necrosis factor and interleukin-1. Since endothelial cells are the first example of a cell-type which may possess both a constitutive and an inducible type of NO synthase, it was of interest to compare the requirements of these two enzyme activities. Induction of NO synthesis in MBE by cytokines was abolished by the protein synthesis inhibitor, cycloheximide, and by 2,4-diamino-6-hydroxypyridine (DAHP), a selective inhibitor of GTP cyclohydrolase I, the rate-limiting enzyme for de novo synthesis of tetrahydrobiopterin (THB). In the presence of DAHP, NO synthesis was restored by sepiapterin (SEP), a substrate for the alternative pathway of THB synthesis occurring via pterin salvage. Moreover, SEP increased NO synthesis to greater than 150% of control values, suggesting that THB availability is rate-limiting for NO synthesis by cytokine-induced MBE. Methotrexate, an inhibitor of the pterin salvage pathway of THB synthesis, completely reversed the stimulation of NO synthesis by sepiapterin. Thus, cytokine-induced MBE NO synthase appears to have an absolute requirement for THB as cofactor. In additional studies we found that NO synthesis by cytokine-activated MBE was inhibited by NG-monosubstituted arginine analogs with a rank-order of potency NH2 greater than CH3 greater than NO2, in contrast with the rank-order of NO2 greater than NH2 greater than CH3 previously described for inhibition of the constitutive endothelial cell enzyme. Using a kinetic assay for NO synthase activity, based on oxidation of myoglobin heme-iron, we have found that these rank orders of potency also apply to cytosol preparations of cytokine-induced and untreated endothelial cells, respectively. Further differences between constitutive and cytokine-induced NO synthase were observed with regard to calmodulin requirements. Whereas constitutive NO synthase was potently inhibited by the calmodulin antagonists mellitin and trifluoperazine, cytokine-induced NO synthase was unaffected. In summary, NO synthesis by cytokine-activated MBE is THB-dependent, calmodulin-independent and inhibited by NG-substituted arginine analogs with a rank-order profile distinct from that for untreated endothelial cells but identical to that for cytokine-activated macrophages.
我们之前报道过,培养的小鼠脑内皮细胞(MBE)在用干扰素-γ与几种免疫激活剂(包括细菌内毒素、肿瘤坏死因子和白细胞介素-1)中的任何一种联合激活后,会产生大量一氧化氮(NO)。由于内皮细胞是可能同时拥有组成型和诱导型一氧化氮合酶的细胞类型中的首个例子,比较这两种酶活性的需求很有意义。蛋白质合成抑制剂环己酰亚胺以及2,4-二氨基-6-羟基吡啶(DAHP,鸟苷三磷酸环水解酶I的选择性抑制剂,鸟苷三磷酸环水解酶I是四氢生物蝶呤(THB)从头合成的限速酶)可消除细胞因子对MBE中NO合成的诱导作用。在DAHP存在的情况下,通过蝶呤补救途径合成THB的替代途径的底物蝶酰三谷氨酸(SEP)可恢复NO的合成。此外,SEP使NO合成增加至对照值的150%以上,这表明THB的可用性是细胞因子诱导的MBE合成NO的限速因素。甲氨蝶呤是THB合成的蝶呤补救途径的抑制剂,它完全逆转了蝶酰三谷氨酸对NO合成的刺激作用。因此,细胞因子诱导的MBE一氧化氮合酶似乎绝对需要THB作为辅因子。在另外的研究中我们发现,细胞因子激活的MBE合成NO受到N-单取代精氨酸类似物的抑制,其效力顺序为NH2大于CH3大于NO2,这与之前描述的抑制组成型内皮细胞酶的效力顺序NO2大于NH2大于CH3相反。使用基于肌红蛋白血红素铁氧化的一氧化氮合酶活性动力学测定方法,我们发现这些效力顺序也分别适用于细胞因子诱导的和未处理的内皮细胞的胞质溶胶制剂。在钙调蛋白需求方面还观察到组成型和细胞因子诱导的一氧化氮合酶之间的进一步差异。组成型一氧化氮合酶受到钙调蛋白拮抗剂蜂毒素和三氟拉嗪的强烈抑制,而细胞因子诱导的一氧化氮合酶则不受影响。总之,细胞因子激活的MBE合成NO依赖于THB,不依赖于钙调蛋白,并且受到N-取代精氨酸类似物的抑制,其效力顺序与未处理的内皮细胞不同,但与细胞因子激活的巨噬细胞相同。
