Therapeutic targeting of full-length interleukin-33 protein levels with cell-permeable decoy peptides attenuates fibrosis in the bleomycin model in vivo.

IF 3.1 3区 医学 Q2 PHARMACOLOGY & PHARMACY
Sergei P Atamas, Virginia K Lockatell, Nevins W Todd, John C Papadimitriou, Violeta Rus, Katerina N Lugkey, Stefanie N Vogel, Vladimir Y Toshchakov, Irina G Luzina
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引用次数: 0

Abstract

Interleukin (IL)-33 has been shown to centrally regulate, among other processes, inflammation and fibrosis. Both intracellular full-length (FLIL33) precursor and extracellular mature cytokine (MIL33) forms exert such regulation, albeit differentially. Drug development efforts to target the IL-33 pathway have focused mostly on MIL33 and its specific cell-surface receptor, ST2, with limited attempts to negotiate the pathophysiological contributions from FLIL33. Furthermore, even a successful strategy for targeting MIL33 effects would arguably benefit from a simultaneous attenuation of the levels of FLIL33, which remains the continuous source of MIL33 supply. We therefore sought to develop an approach to depleting FLIL33 protein levels. We previously reported that the steady-state levels of FLIL33 are controlled in part through its proteasomal degradation and that such regulation can be mapped to a segment in the N-terminal portion of FLIL33. We hypothesized that disruption of this regulation would lead to a decrease in FLIL33 levels, thus inducing a beneficial therapeutic effect in an IL-33-dependent pathology. To test this hypothesis, we designed and tested cell-permeable decoy peptides (CPDPs) which mimic the target N-terminal FLIL33 region. We argued that such mimic peptides would compete with FLIL33 for the components of the native FLIL33 production and maintenance molecular machinery. Administered in the therapeutic regimen to bleomycin-challenged mice, the tested CPDPs alleviated the overall severity of the disease by restoring body weight loss and attenuating accumulation of collagen in the lungs. This proof-of-principle study lays the foundation for future work towards the development of this prospective therapeutic approach. Significance Statement An antifibrotic therapeutic approach is proposed and preclinically tested in mice in vivo based on targeting the full-length IL-33 precursor protein. Peptide fusion constructs consisted of a cell-permeable sequence fused with a sequence mimicking an N-terminal segment of IL-33 precursor that is responsible for this protein's stability. Systemic administration of such peptides to mice in either the acute intratracheal or chronic systemic bleomycin challenge models leads to a decrease in the bleomycin-induced elevations of pulmonary IL-33 and collagen.

利用细胞渗透性诱饵肽对全长白细胞介素-33蛋白水平进行靶向治疗,可减轻博莱霉素模型体内的纤维化。
白细胞介素(IL)-33 被证明能集中调节炎症和纤维化等过程。细胞内的全长(FLIL33)前体和细胞外的成熟细胞因子(MIL33)形式都能发挥这种调节作用,只是作用方式不同。针对 IL-33 通路的药物开发工作主要集中在 MIL33 及其特定的细胞表面受体 ST2 上,而对 FLIL33 在病理生理方面的贡献进行研究的尝试却很有限。此外,即使是针对 MIL33 作用的成功策略,也需要同时降低 FLIL33 的水平,因为 FLIL33 仍是 MIL33 的持续供应来源。因此,我们试图开发一种消耗 FLIL33 蛋白水平的方法。我们以前报道过,FLIL33 的稳态水平部分是通过其蛋白酶体降解来控制的,这种调控可以映射到 FLIL33 N 端部分的一个片段。我们假设,破坏这种调控会导致 FLIL33 水平下降,从而对依赖 IL-33 的病症产生有益的治疗效果。为了验证这一假设,我们设计并测试了模拟目标 N 端 FLIL33 区域的细胞渗透性诱饵肽(CPDPs)。我们认为,这种模拟肽会与 FLIL33 竞争本地 FLIL33 生产和维护分子机制的成分。在博莱霉素感染小鼠的治疗方案中,测试的 CPDPs 通过恢复体重下降和减少肺部胶原蛋白的积累,减轻了疾病的整体严重程度。这项原理验证研究为今后开发这种前瞻性治疗方法奠定了基础。意义声明 本研究提出了一种抗纤维化治疗方法,并以全长 IL-33 前体蛋白为靶点在小鼠体内进行了临床前测试。多肽融合构建物由一个细胞渗透序列与一个模仿 IL-33 前体 N 端片段的序列融合而成,后者负责该蛋白的稳定性。在急性气管内或慢性全身性博莱霉素挑战模型中,给小鼠全身注射这种多肽可降低博莱霉素诱导的肺IL-33和胶原蛋白的升高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
6.90
自引率
0.00%
发文量
115
审稿时长
1 months
期刊介绍: A leading research journal in the field of pharmacology published since 1909, JPET provides broad coverage of all aspects of the interactions of chemicals with biological systems, including autonomic, behavioral, cardiovascular, cellular, clinical, developmental, gastrointestinal, immuno-, neuro-, pulmonary, and renal pharmacology, as well as analgesics, drug abuse, metabolism and disposition, chemotherapy, and toxicology.
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