AI Article Synopsis
- Mucins are essential proteins that protect epithelial surfaces, but their biosynthesis and packaging are not well understood.
- Research reveals that mucins undergo significant restructuring within secretory granules, allowing for unique, organized arrangements during maturation, influenced by specific genes regulating ions and pH.
- This study highlights the importance of mucin restructuring in granule morphology and suggests that understanding these processes may help address diseases related to mucin secretion defects.
Article Abstract
Mucins are large, highly glycosylated transmembrane and secreted proteins that line and protect epithelial surfaces. However, the details of mucin biosynthesis and packaging in vivo are largely unknown. Here, we demonstrate that multiple distinct mucins undergo intragranular restructuring during secretory granule maturation in vivo, forming unique structures that are spatially segregated within the same granule. We further identify temporally-regulated genes that influence mucin restructuring, including those controlling pH (), Ca ions () and Cl ions ( and ). Finally, we show that altered mucin glycosylation influences the dimensions of these structures, thereby affecting secretory granule morphology. This study elucidates key steps and factors involved in intragranular, rather than intergranular segregation of mucins through regulated restructuring events during secretory granule maturation. Understanding how multiple distinct mucins are efficiently packaged into and secreted from secretory granules may provide insight into diseases resulting from defects in mucin secretion.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9618048 | PMC |
| http://dx.doi.org/10.1073/pnas.2209750119 | DOI Listing |
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