Simonaro Calogera M, D'Angelo Marina, Haskins Mark E, Schuchman Edward H
Department of Human Genetics, Mount Sainai School of Medicine, New York, NY 10029, USA.
Pediatr Res. 2005 May;57(5 Pt 1):701-7. doi: 10.1203/01.PDR.0000156510.96253.5A. Epub 2005 Mar 3.
The mucopolysaccharidoses (MPS) are inherited metabolic disorders resulting from the defective catabolism of glycosaminoglycans. In this report, we find that the stimulation of MPS connective tissue cells by the inflammatory cytokines causes enhanced secretion of several matrix-degrading metalloproteinases (MMPs). In addition, expression of tissue inhibitor of metalloproteinase-1 was elevated, consistent with the enhanced MMP activity. These findings were not restricted to one particular MPS disorder or species, and are consistent with previous observations in animal models with chemically induced arthritis. Bromodeoxyuridine incorporation studies also revealed that MPS chondrocytes proliferated up to 5-fold faster than normal chondrocytes, and released elevated levels of transforming growth factor-beta, presumably to counteract the marked chondrocyte apoptosis and matrix degradation associated with MMP expression. Despite this compensatory mechanism, studies of endochondral ossification revealed a reduction in chondro-differentiation in the growth plates. Thus, although MPS chondrocytes grew faster, most of the newly formed cells were immature and could not mineralize into bone. Our studies suggest that altered MMP expression, most likely stimulated by inflammatory cytokines and nitric oxide, is an important feature of the MPS disorders. These data also identify several proinflammatory cytokines, nitric oxide, and MMPs as novel therapeutic targets and/or biomarkers of MPS joint and bone disease. This information should aid in the evaluation of existing therapies for these disorders, such as enzyme replacement therapy and bone marrow transplantation, and may lead to the development of new therapeutic approaches.
黏多糖贮积症(MPS)是由糖胺聚糖分解代谢缺陷导致的遗传性代谢紊乱疾病。在本报告中,我们发现炎性细胞因子对MPS结缔组织细胞的刺激会导致几种基质降解金属蛋白酶(MMPs)的分泌增加。此外,金属蛋白酶组织抑制剂-1的表达升高,这与MMP活性增强相一致。这些发现并不局限于某一种特定的MPS疾病或物种,并且与先前在化学诱导性关节炎动物模型中的观察结果一致。溴脱氧尿苷掺入研究还显示,MPS软骨细胞的增殖速度比正常软骨细胞快5倍,并释放出升高水平的转化生长因子-β,推测这是为了抵消与MMP表达相关的显著软骨细胞凋亡和基质降解。尽管有这种代偿机制,但对软骨内骨化的研究显示生长板中的软骨分化减少。因此,尽管MPS软骨细胞生长更快,但大多数新形成的细胞不成熟,无法矿化形成骨骼。我们的研究表明,MMP表达改变很可能是由炎性细胞因子和一氧化氮刺激引起的,这是MPS疾病的一个重要特征。这些数据还确定了几种促炎细胞因子、一氧化氮和MMPs作为MPS关节和骨骼疾病的新型治疗靶点和/或生物标志物。这些信息应有助于评估针对这些疾病的现有疗法,如酶替代疗法和骨髓移植,并可能导致新治疗方法的开发。