放大器通过 PCBP1 介导的 CFTR mRNA 调控共翻译增强 CFTR 的生物合成。

Amplifiers co-translationally enhance CFTR biosynthesis via PCBP1-mediated regulation of CFTR mRNA.

机构信息

Proteostasis Therapeutics, Inc., 80 Guest St, Suite 500, Boston, MA 02135, United States.

Department of Cell Biology, Harvard Medical School, Boston, MA 02115, United States.

出版信息

J Cyst Fibros. 2020 Sep;19(5):733-741. doi: 10.1016/j.jcf.2020.02.006. Epub 2020 Feb 15.

DOI:10.1016/j.jcf.2020.02.006

PMID:32067958

Abstract

BACKGROUND

Cystic fibrosis (CF) is a recessive disorder caused by mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) gene. We previously described a first-in-class CFTR modulator that functions as an amplifier to selectively increase CFTR expression and function. The amplifier mechanism is distinct from and complementary to corrector and potentiator classes of CFTR modulators. Here we characterize the mechanism by which amplifiers increase CFTR mRNA, protein, and activity.

METHODS

Biochemical studies elucidated the action of amplifiers on CFTR mRNA abundance and translation and defined the role of an amplifier-binding protein that was identified using chemical proteomics.

RESULTS

Amplifiers stabilize CFTR mRNA through a process that requires only the translated sequence of CFTR and involves translational elongation. Amplifiers enrich ER-associated CFTR mRNA and increase its translational efficiency through increasing the fraction of CFTR mRNA associated with polysomes. Pulldowns identified the poly(rC)-binding protein 1 (PCBP1) as directly binding to amplifier. A PCBP1 consensus element was identified within the CFTR open reading frame that binds PCBP1. This sequence proved necessary for amplifier responsiveness.

CONCLUSIONS

Small molecule amplifiers co-translationally increase CFTR mRNA stability. They enhance translation through addressing the inherently inefficient membrane targeting of CFTR mRNA. Amplifiers bind directly to PCBP1, show enhanced affinity in the presence of bound RNA, and require a PCBP1 consensus element within CFTR mRNA to elicit translational effects. These modulators represent a promising new and mechanistically novel class of CFTR therapeutic. They may be useful as a monotherapy or in combination with other CFTR modulators.

摘要

背景

囊性纤维化（CF）是一种由囊性纤维化跨膜电导调节因子（CFTR）基因突变引起的隐性疾病。我们之前描述了一种首创的 CFTR 调节剂，它作为一种放大器，选择性地增加 CFTR 的表达和功能。放大器机制与 CFTR 调节剂的校正器和增强剂类不同，是互补的。在这里，我们描述了放大器增加 CFTR mRNA、蛋白和活性的机制。

方法

生化研究阐明了放大器对 CFTR mRNA 丰度和翻译的作用，并定义了使用化学蛋白质组学鉴定的放大器结合蛋白的作用。

结果

放大器通过仅需要 CFTR 翻译序列的过程稳定 CFTR mRNA，该过程涉及翻译延伸。放大器富集 ER 相关的 CFTR mRNA，并通过增加与多核糖体相关的 CFTR mRNA 比例来提高其翻译效率。下拉实验鉴定了多聚（rC）结合蛋白 1（PCBP1）作为直接与放大器结合的蛋白。在 CFTR 开放阅读框内鉴定了一个 PCBP1 共有序列元件，该元件与 PCBP1 结合。该序列被证明是对放大器响应所必需的。

结论

小分子放大器共翻译增加 CFTR mRNA 的稳定性。它们通过解决 CFTR mRNA 固有低效的膜靶向来增强翻译。放大器直接与 PCBP1 结合，在存在结合 RNA 时显示出增强的亲和力，并在 CFTR mRNA 内需要 PCBP1 共有序列元件来发挥翻译作用。这些调节剂代表了一种有前途的新型且机制新颖的 CFTR 治疗药物类别。它们可以作为单一疗法或与其他 CFTR 调节剂联合使用。

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放大器通过 PCBP1 介导的 CFTR mRNA 调控共翻译增强 CFTR 的生物合成。

Amplifiers co-translationally enhance CFTR biosynthesis via PCBP1-mediated regulation of CFTR mRNA.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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