A dynamic interplay between chitin synthase and the proteins Expansion/Rebuf reveals that chitin polymerisation and translocation are uncoupled in Drosophila

Chitin is a highly abundant polymer in nature and a principal component of apical extracellular matrices in insects. In addition, chitin has proved to be an excellent biomaterial with multiple applications. In spite of its importance, the molecular mechanisms of chitin biosynthesis and chitin struct...

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Veröffentlicht in:	PLoS biology 2023-01, Vol.21 (1), p.e3001978-e3001978
Hauptverfasser:	De Giorgio, Ettore, Giannios, Panagiotis, Espinàs, M Lluisa, Llimargas, Marta
Format:	Artikel
Sprache:	eng
Schlagworte:	Analysis Animals Biology and Life Sciences Biomaterials Biomedical materials Biosynthesis Chemical synthesis Chitin Chitin - chemistry Chitin - metabolism Chitin synthase Chitin Synthase - genetics Chitin Synthase - metabolism Deposition Domains Drosophila Drosophila - metabolism Drosophila Proteins - genetics Drosophila Proteins - metabolism Energy consumption Exocrine glands Fruit flies Identification and classification Insects Localization Medicine and Health Sciences Membranes Methods Molecular modelling Mutation Physical Sciences Polymerization Polymers Properties Proteins Research and Analysis Methods Smad Proteins - metabolism Translocation
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description	Chitin is a highly abundant polymer in nature and a principal component of apical extracellular matrices in insects. In addition, chitin has proved to be an excellent biomaterial with multiple applications. In spite of its importance, the molecular mechanisms of chitin biosynthesis and chitin structural diversity are not fully elucidated yet. To investigate these issues, we use Drosophila as a model. We previously showed that chitin deposition in ectodermal tissues requires the concomitant activities of the chitin synthase enzyme Kkv and the functionally interchangeable proteins Exp and Reb. Exp/Reb are conserved proteins, but their mechanism of activity during chitin deposition has not been elucidated yet. Here, we carry out a cellular and molecular analysis of chitin deposition, and we show that chitin polymerisation and chitin translocation to the extracellular space are uncoupled. We find that Kkv activity in chitin translocation, but not in polymerisation, requires the activity of Exp/Reb, and in particular of its conserved Nα-MH2 domain. The activity of Kkv in chitin polymerisation and translocation correlate with Kkv subcellular localisation, and in absence of Kkv-mediated extracellular chitin deposition, chitin accumulates intracellularly as membrane-less punctae. Unexpectedly, we find that although Kkv and Exp/Reb display largely complementary patterns at the apical domain, Exp/Reb activity nonetheless regulates the topological distribution of Kkv at the apical membrane. We propose a model in which Exp/Reb regulate the organisation of Kkv complexes at the apical membrane, which, in turn, regulates the function of Kkv in extracellular chitin translocation.
doi_str_mv	10.1371/journal.pbio.3001978
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In addition, chitin has proved to be an excellent biomaterial with multiple applications. In spite of its importance, the molecular mechanisms of chitin biosynthesis and chitin structural diversity are not fully elucidated yet. To investigate these issues, we use Drosophila as a model. We previously showed that chitin deposition in ectodermal tissues requires the concomitant activities of the chitin synthase enzyme Kkv and the functionally interchangeable proteins Exp and Reb. Exp/Reb are conserved proteins, but their mechanism of activity during chitin deposition has not been elucidated yet. Here, we carry out a cellular and molecular analysis of chitin deposition, and we show that chitin polymerisation and chitin translocation to the extracellular space are uncoupled. We find that Kkv activity in chitin translocation, but not in polymerisation, requires the activity of Exp/Reb, and in particular of its conserved Nα-MH2 domain. 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subjects	Analysis Animals Biology and Life Sciences Biomaterials Biomedical materials Biosynthesis Chemical synthesis Chitin Chitin - chemistry Chitin - metabolism Chitin synthase Chitin Synthase - genetics Chitin Synthase - metabolism Deposition Domains Drosophila Drosophila - metabolism Drosophila Proteins - genetics Drosophila Proteins - metabolism Energy consumption Exocrine glands Fruit flies Identification and classification Insects Localization Medicine and Health Sciences Membranes Methods Molecular modelling Mutation Physical Sciences Polymerization Polymers Properties Proteins Research and Analysis Methods Smad Proteins - metabolism Translocation
title	A dynamic interplay between chitin synthase and the proteins Expansion/Rebuf reveals that chitin polymerisation and translocation are uncoupled in Drosophila
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