Sulfation affects apical extracellular matrix organization during development of the Drosophila embryonic salivary gland tube.

IF 6.4 1区生物学 Q1 BIOLOGY

eLife Pub Date : 2025-09-23 DOI:10.7554/eLife.108292

J Luke Woodward, Jeffrey Matthew, Rutuparna Joshi, Vishakha Vishwakarma, Ying Xiao, SeYeon Chung

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引用次数: 0

Abstract

The apical extracellular matrix (aECM) plays a critical role in epithelial tube morphogenesis during organ formation, but its composition and organization remain poorly understood. Using the Drosophila embryonic salivary gland (SG) as a model, we identify Papss, an enzyme that synthesizes the universal sulfate donor PAPS, as a critical regulator of tube lumen expansion. Papss mutants show a disorganized apical membrane, condensed aECM, and disruptions in Golgi structures and intracellular trafficking. SG-specific expression of wild-type Papss, but not the catalytically inactive form, rescues the defects in Papss mutants, suggesting that defects in sulfation are the underlying cause of the phenotypes. Additionally, we identify two zona pellucida (ZP) domain proteins, Piopio (Pio), and Dumpy (Dpy), as key components of the SG aECM. In the absence of Papss, Pio is gradually lost in the aECM, while the Dpy-positive aECM structure is condensed and dissociates from the apical membrane, leading to a thin lumen. Mutations in dpy or pio, or in Notopleural, which encodes a matriptase that cleaves Pio to form the luminal Pio pool, result in a SG lumen with alternating bulges and constrictions, with the loss of pio leading to the loss of Dpy in the lumen. Our findings underscore the essential role of sulfation in organizing the aECM during tubular organ formation and highlight the mechanical support provided by ZP domain proteins in maintaining luminal diameter.

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硫酸化对果蝇胚胎唾液腺管发育过程中细胞外基质组织的影响。

在器官形成过程中，根尖细胞外基质（apical extracellular matrix, aECM）在上皮管的形态发生中起着至关重要的作用，但其组成和组织结构尚不清楚。以果蝇胚胎唾液腺（SG）为模型，我们鉴定了一种合成通用硫酸供体PAPS的酶Papss，它是管腔扩张的关键调节剂。Papss突变体显示顶端膜组织紊乱，aECM浓缩，高尔基结构和细胞内运输中断。sg特异性表达野生型Papss，而不是催化失活的形式，挽救了Papss突变体的缺陷，这表明硫酸化缺陷是这些表型的潜在原因。此外，我们鉴定了两个透明带（ZP）结构域蛋白Piopio （Pio）和Dumpy (Dpy)，作为SG aECM的关键成分。在没有Papss的情况下，Pio在aECM中逐渐消失，而dpy阳性的aECM结构被凝聚并与顶膜分离，导致管腔变薄。dpy或pio或Notopleural（编码一种基质酶，可裂解pio形成管腔pio池）的突变，导致SG管腔交替隆起和收缩，pio的缺失导致管腔内dpy的缺失。我们的发现强调了硫酸化在管状器官形成过程中组织aECM的重要作用，并强调了ZP结构域蛋白在维持管腔直径方面提供的机械支持。

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

eLife BIOLOGY-

CiteScore

12.90

自引率

3.90%

发文量

3122

审稿时长

17 weeks

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