γ-分泌酶切割醇脱氢酶的跨膜裂解机制。

Mechanism of intramembrane cleavage of alcadeins by γ-secretase.

机构信息

Laboratory of Neuroscience, Graduate School of Pharmaceutical Sciences, Hokkaido University, Sapporo, Japan.

出版信息

PLoS One. 2013 Apr 26;8(4):e62431. doi: 10.1371/journal.pone.0062431. Print 2013.

BACKGROUND

Alcadein proteins (Alcs; Alcα, Alcβand Alcγ) are predominantly expressed in neurons, as is Alzheimer's β-amyloid (Aβ) precursor protein (APP). Both Alcs and APP are cleaved by primary α- or β-secretase to generate membrane-associated C-terminal fragments (CTFs). Alc CTFs are further cleaved by γ-secretase to secrete p3-Alc peptide along with the release of intracellular domain fragment (Alc ICD) from the membrane. In the case of APP, APP CTFβ is initially cleaved at the ε-site to release the intracellular domain fragment (AICD) and consequently the γ-site is determined, by which Aβ generates. The initial ε-site is thought to define the final γ-site position, which determines whether Aβ40/43 or Aβ42 is generated. However, initial intracellular ε-cleavage sites of Alc CTF to generate Alc ICD and the molecular mechanism that final γ-site position is determined remains unclear in Alcs.

METHODOLOGY

Using HEK293 cells expressing Alcs plus presenilin 1 (PS1, a catalytic unit of γ-secretase) and the membrane fractions of these cells, the generation of p3-Alc possessing C-terminal γ-cleavage site and Alc ICD possessing N-terminal ε-cleavage site were analysed with MALDI-TOF/MS. We determined the initial ε-site position of all Alcα, Alcβ and Alcγ, and analyzed the relationship between the initially determined ε-site position and the final γ-cleavage position.

CONCLUSIONS

The initial ε-site position does not always determine the final γ-cleavage position in Alcs, which differed from APP. No additional γ-cleavage sites are generated from artificial/non-physiological positions of ε-cleavage for Alcs, while the artificial ε-cleavage positions can influence in selection of physiological γ-site positions. Because alteration of γ-secretase activity is thought to be a pathogenesis of sporadic Alzheimer's disease, Alcs are useful and sensitive substrate to detect the altered cleavage of substrates by γ-secretase, which may be induced by malfunction of γ-secretase itself or changes of membrane environment for enzymatic reaction.

背景

Alcadein 蛋白（Alcs；Alcα、Alcβ 和 Alcγ）主要在神经元中表达，就像阿尔茨海默病 β-淀粉样前体蛋白 (APP) 一样。Alcs 和 APP 都被主要的 α-或 β-分泌酶切割，产生膜相关的 C 端片段（CTFs）。Alc CTFs 进一步被 γ-分泌酶切割，从膜上释放出 p3-Alc 肽和细胞内域片段（Alc ICD）。对于 APP，APP CTFβ 最初在 ε 位被切割，释放细胞内域片段（AICD），随后 γ 位被确定，由此产生 Aβ。最初的 ε 位被认为定义了最终 γ 位的位置，从而决定了生成的是 Aβ40/43 还是 Aβ42。然而，Alc CTF 生成 Alc ICD 的初始细胞内 ε 切割位点以及最终 γ 位确定的分子机制在 Alcs 中仍不清楚。

方法

使用表达 Alcs 加早老素 1（PS1，γ-分泌酶的催化单元）的 HEK293 细胞和这些细胞的膜部分，用 MALDI-TOF/MS 分析具有 C 端 γ 切割位点的 p3-Alc 和具有 N 端 ε 切割位点的 Alc ICD 的产生。我们确定了所有 Alcα、Alcβ 和 Alcγ 的初始 ε 位，并分析了初始 ε 位与最终 γ 切割位之间的关系。

结论

在 Alcs 中，初始 ε 位并不总是决定最终的 γ 切割位，这与 APP 不同。Alcs 不会从 ε 切割的人为/非生理位置产生额外的 γ 切割位点，而人工 ε 切割位置可以影响生理 γ 位的选择。由于 γ-分泌酶活性的改变被认为是散发性阿尔茨海默病的发病机制，因此 Alcs 是一种有用且敏感的底物，可以检测 γ-分泌酶对底物切割的改变，这可能是由 γ-分泌酶本身的功能障碍或酶反应的膜环境变化引起的。