Institute of Pharmacology and Toxicology, University of Bonn, Biomedical Center 2G028, Sigmund-Freud-Str. 25, 53105 Bonn, Germany.
Naunyn Schmiedebergs Arch Pharmacol. 2010 Apr;381(4):297-304. doi: 10.1007/s00210-009-0489-6. Epub 2010 Jan 28.
Arginase was shown to be up-regulated in different animal models of inflammatory and fibrotic airway diseases. Since arginase provides L-ornithine, one precursor for L-proline, an essential substrate for collagen synthesis, it has been suggested that arginase might be a key enzyme in airway remodelling. The present study aimed to characterize expression of arginase isoenzymes in rat and human pulmonary fibroblasts, and to test whether arginase inhibition affects collagen synthesis. In primary rat tracheal and lung fibroblasts, mRNA for arginase I and II could be detected, with arginase I as predominant isoenzyme. In contrast, in human lung fibroblasts (primary cells and different cells lines) mRNA levels for arginase I were at or below detection limit whereas arginase II mRNA was markedly higher than in rat pulmonary fibroblasts. Arginase activity in rat tracheal and lung fibroblasts was between 20 and 30 mU/mg protein, but was below detection limit (2.5 mU/mg) in human lung fibroblasts. In rat tracheal and lung fibroblasts cultured in proline-free medium, arginase inhibition by N(omega)-hydroxy-nor-L-arginine caused a reduction by about one-third of basal collagen I accumulation (determined by western blot analysis) and largely attenuated transforming growth factor beta 1 (TGF-beta(1))-induced increase in collagen accumulation, whereas basal and TGF-beta(1)-induced collagen accumulation by human lung fibroblasts was not affected by arginase inhibition. In conclusion, arginase isoenzymes reveal a species specific expression pattern. Arginase contributes significantly to L-proline supply for collagen synthesis in rat fibroblasts, in which arginase I is the predominant isoenzyme, but not in human fibroblasts, in which arginase II is the only isoenzyme expressed.
精氨酸酶在不同的炎症和纤维化气道疾病的动物模型中被证明上调。由于精氨酸酶提供 L-鸟氨酸,脯氨酸的一种前体,胶原合成的必需底物,因此有人认为精氨酸酶可能是气道重塑的关键酶。本研究旨在表征大鼠和人肺成纤维细胞中精氨酸酶同工酶的表达,并测试精氨酸酶抑制是否影响胶原合成。在原代大鼠气管和肺成纤维细胞中,可以检测到精氨酸酶 I 和 II 的 mRNA,精氨酸酶 I 是主要的同工酶。相比之下,在人肺成纤维细胞(原代细胞和不同的细胞系)中,精氨酸酶 I 的 mRNA 水平低于检测限,而精氨酸酶 II 的 mRNA 水平明显高于大鼠肺成纤维细胞。大鼠气管和肺成纤维细胞的精氨酸酶活性在 20 到 30 mU/mg 蛋白之间,但在人肺成纤维细胞中低于检测限(2.5 mU/mg)。在脯氨酸缺乏培养基中培养的大鼠气管和肺成纤维细胞中,N(ω)-羟基-N-精氨酸抑制精氨酸酶导致基础胶原 I 积累减少约三分之一(通过 Western blot 分析确定),并在很大程度上减弱转化生长因子β 1(TGF-β1)诱导的胶原积累增加,而人肺成纤维细胞的基础和 TGF-β1 诱导的胶原积累不受精氨酸酶抑制的影响。总之,精氨酸酶同工酶表现出种特异性表达模式。精氨酸酶显著促进大鼠成纤维细胞中胶原合成的 L-脯氨酸供应,其中精氨酸酶 I 是主要的同工酶,但在人成纤维细胞中没有,其中精氨酸酶 II 是唯一表达的同工酶。
