INSERM UMR-1100, Research Center for Respiratory Diseases, Tours, France; Université de Tours, Tours, France.
Experimental and Clinical Research Center, Charité und Max-Delbrück-Centrum für Molekulare Medizin in der Helmholtz-Gemeinschaft (MDC), Berlin, Germany.
Biochem Pharmacol. 2024 Nov;229:116114. doi: 10.1016/j.bcp.2024.116114. Epub 2024 Sep 16.
An uncontrolled activity of neutrophil serine proteases (NSPs) contributes to inflammatory diseases. Cathepsin C (CatC) is known to activate NSPs during neutrophilic differentiation and represents a promising pharmacological target in NSP-mediated diseases. In humans, Papillon-Lefèvre syndrome (PLS) patients have mutations in theirCTSC gene, resulting in the complete absence of CatC activity. Despite this, low residual NSP activities are detected in PLS neutrophils (<10% vs healthy individuals), suggesting the involvement of CatC-independent proteolytic pathway(s) in the activation of proNSPs. This prompted us to characterize CatC-independent NSP activation pathways by blocking proCatC maturation. In this study, we show that inhibition of intracellular CatS almost completely blocked CatC maturation in human promyeloid HL-60 cells. Despite this, NSP activation was not significantly reduced, confirming the presence of a CatC-independent activation pathway involving a CatC-like protease that we termed NSPs-AAP-1. Similarly, when human CD34 progenitor cells were treated with CatS inhibitors during neutrophilic differentiation in vitro, CatC activity was nearly abrogated but ∼30% NSP activities remained, further supporting the existence of NSPs-AAP-1. Our data indicate that NSPs-AAP-1 is a cysteine protease that is inhibited by reversible nitrile compounds designed for CatC inhibition. We further established a proof of concept for the indirect, although incomplete, inhibition of NSPs by pharmacological targeting of CatC maturation using CatS inhibitors. This emphasizes the potential of CatS as a therapeutic target for inflammatory diseases. Thus, preventing proNSP maturation using a CatS inhibitor, alone or in combination with a CatC/NSPs-AAP-1 inhibitor, represents a promising approach to efficiently control the extent of tissue injury in neutrophil-mediated inflammatory diseases.
中性粒细胞丝氨酸蛋白酶(NSPs)的不受控制的活性会导致炎症性疾病。已知组织蛋白酶 C(CatC)在中性粒细胞分化过程中激活 NSPs,是 NSP 介导的疾病中很有前途的药理学靶点。在人类中,Papillon-Lefèvre 综合征(PLS)患者的 CTSC 基因突变,导致 CatC 活性完全缺失。尽管如此,在 PLS 中性粒细胞中仍检测到低残留的 NSP 活性(<10%比健康个体),这表明在 proNSP 的激活中存在 CatC 非依赖性的蛋白水解途径。这促使我们通过阻断 proCatC 成熟来表征 CatC 非依赖性的 NSP 激活途径。在这项研究中,我们表明,抑制细胞内 CatS 几乎完全阻断了人早幼粒细胞 HL-60 细胞中 CatC 的成熟。尽管如此,NSP 的激活并没有显著降低,这证实了存在一种 CatC 非依赖性的激活途径,涉及一种我们称为 NSPs-AAP-1 的 CatC 样蛋白酶。同样,当人 CD34 祖细胞在体外的中性粒细胞分化过程中用 CatS 抑制剂处理时,CatC 活性几乎被消除,但仍保留约 30%的 NSP 活性,这进一步支持了 NSPs-AAP-1 的存在。我们的数据表明,NSPs-AAP-1 是一种半胱氨酸蛋白酶,可被设计用于抑制 CatC 的可逆腈化合物抑制。我们进一步通过使用 CatS 抑制剂靶向 CatC 成熟来间接(尽管不完全)抑制 NSPs,证明了这一概念。这强调了 CatS 作为治疗炎症性疾病的潜在靶点的重要性。因此,单独使用 CatS 抑制剂或与 CatC/NSPs-AAP-1 抑制剂联合使用,来阻止 proNSP 成熟,可能是一种控制中性粒细胞介导的炎症性疾病中组织损伤程度的有前途的方法。
