Van Den Steen Philippe E, Wuyts Anja, Husson Steven J, Proost Paul, Van Damme Jo, Opdenakker Ghislain
Laboratory of Molecular Immunology, Rega Institute, University of Leuven, Belgium.
Eur J Biochem. 2003 Sep;270(18):3739-49. doi: 10.1046/j.1432-1033.2003.03760.x.
On chemokine stimulation, leucocytes produce and secrete proteolytic enzymes for innate immune defence mechanisms. Some of these proteases modify the biological activity of the chemokines. For instance, neutrophils secrete gelatinase B (matrix metalloproteinase-9, MMP-9) and neutrophil collagenase (MMP-8) after stimulation with interleukin-8/CXCL8 (IL-8). Gelatinase B cleaves and potentiates IL-8, generating a positive feedback. Here, we extend these findings and compare the processing of the CXC chemokines human and mouse granulocyte chemotactic protein-2/CXCL6 (GCP-2) and the closely related human epithelial-cell derived neutrophil activating peptide-78/CXCL5 (ENA-78) with that of human IL-8. Human GCP-2 and ENA-78 are cleaved by gelatinase B at similar rates to IL-8. In addition, GCP-2 is cleaved by neutrophil collagenase, but at a lower rate. The cleavage of GCP-2 is exclusively N-terminal and does not result in any change in biological activity. In contrast, ENA-78 is cleaved by gelatinase B at eight positions at various rates, finally generating inactive fragments. Physiologically, sequential cleavage of ENA-78 may result in early potentiation and later in inactivation of the chemokine. Remarkably, in the mouse, which lacks IL-8 which is replaced by GCP-2/LIX as the most potent neutrophil activating chemokine, N-terminal clipping and twofold potentiation by gelatinase B was also observed. In addition to the similarities in the potentiation of IL-8 in humans and GCP-2 in mice, the conversion of mouse GCP-2/LIX by mouse gelatinase B is the fastest for any combination of chemokines and MMPs so far reported. This rapid conversion was also performed by crude neutrophil granule secretion under physiological conditions, extending the relevance of this proteolytic cleavage to the in vivo situation.
在趋化因子刺激下,白细胞产生并分泌蛋白水解酶用于先天性免疫防御机制。其中一些蛋白酶会改变趋化因子的生物学活性。例如,中性粒细胞在受到白细胞介素-8/CXCL8(IL-8)刺激后会分泌明胶酶B(基质金属蛋白酶-9,MMP-9)和中性粒细胞胶原酶(MMP-8)。明胶酶B切割并增强IL-8的活性,形成正反馈。在此,我们扩展了这些发现,并比较了CXC趋化因子人类和小鼠粒细胞趋化蛋白-2/CXCL6(GCP-2)以及密切相关的人类上皮细胞衍生的中性粒细胞激活肽-78/CXCL5(ENA-78)与人类IL-8的加工过程。人类GCP-2和ENA-78被明胶酶B切割的速率与IL-8相似。此外,GCP-2可被中性粒细胞胶原酶切割,但速率较低。GCP-2的切割仅发生在N端,且不会导致生物学活性的任何变化。相比之下,ENA-78被明胶酶B在八个位置以不同速率切割,最终产生无活性的片段。在生理情况下,ENA-78的顺序切割可能导致趋化因子早期增强,随后失活。值得注意的是,在缺乏IL-8(被GCP-2/LIX取代为最有效的中性粒细胞激活趋化因子)的小鼠中,也观察到了明胶酶B对其N端的剪切和两倍的增强作用。除了人类IL-8和小鼠GCP-2增强作用的相似性外,小鼠明胶酶B对小鼠GCP-2/LIX的转化是迄今为止报道的任何趋化因子和基质金属蛋白酶组合中最快的。在生理条件下,粗制中性粒细胞颗粒分泌也能实现这种快速转化,将这种蛋白水解切割的相关性扩展到体内情况。
