B3GALT6 mutations lead to compromised connective tissue biomechanics in Ehlers-Danlos syndrome
Roméo Milan Diana, Benjamin Jolivet, Jean-Baptiste Vincourt, Sébastien Hergalant, Grégory Francius, Yasaman Karami, Hamed Khakzad, Rebekka Wild, Marie Bourgeais, Anne Robert, Alison Wurtz, Guillermo Barreto, Nick Ramalanjaona, Déborah Helle, Rachel Onifarasoaniaina, Sophie Front, Chrystel Lopin-Bon, Delfien Syx, Fransiska Malfait, Sylvie Fournel-Gigleux, Sandrine Gulberti, Catherine Bui
Roméo Milan Diana, Benjamin Jolivet, Jean-Baptiste Vincourt, Sébastien Hergalant, Grégory Francius, Yasaman Karami, Hamed Khakzad, Rebekka Wild, Marie Bourgeais, Anne Robert, Alison Wurtz, Guillermo Barreto, Nick Ramalanjaona, Déborah Helle, Rachel Onifarasoaniaina, Sophie Front, Chrystel Lopin-Bon, Delfien Syx, Fransiska Malfait, Sylvie Fournel-Gigleux, Sandrine Gulberti, Catherine Bui
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Research Article Cell biology Genetics

B3GALT6 mutations lead to compromised connective tissue biomechanics in Ehlers-Danlos syndrome

Abstract

Ehlers-Danlos syndromes (EDS) comprise a genetically and clinically heterogenous group of rare diseases that cause severe, often fatal, damage to connective tissue. The molecular basis of EDS implicates defects in extracellular matrix components, including various fibrillar collagens and glycosaminoglycans (GAGs). However, the precise pathogenic mechanisms behind EDS remain elusive. Here, we have implemented a multi-tiered approach to demonstrate the functional impact of B3GALT6 mutations on biochemical and developmental processes, ultimately leading to the spondylodysplastic subtype of EDS (spEDS), characterized by severe musculoskeletal symptoms. We show that the loss of function of β1,3-galactosyltransferase 6 (β3GalT6) is partially compensated by β1,3-glucuronosyltransferase 3 (GlcAT-I), the next enzyme in the GAG biosynthetic pathway. In addition, results from transcriptomics, collagen analysis, and biophysical experiments revealed that impaired collagen maturation, including defective glycosylation of collagen XII, contributes to altered tissue structure and biomechanics, the hallmarks of spEDS. Our findings unravel a new pathogenic mechanism of spEDS and bring us one step closer to therapeutic strategies, including cell and tissue engineering.

Authors

Roméo Milan Diana, Benjamin Jolivet, Jean-Baptiste Vincourt, Sébastien Hergalant, Grégory Francius, Yasaman Karami, Hamed Khakzad, Rebekka Wild, Marie Bourgeais, Anne Robert, Alison Wurtz, Guillermo Barreto, Nick Ramalanjaona, Déborah Helle, Rachel Onifarasoaniaina, Sophie Front, Chrystel Lopin-Bon, Delfien Syx, Fransiska Malfait, Sylvie Fournel-Gigleux, Sandrine Gulberti, Catherine Bui

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Figure 1

Mutant β3GalT6 proteins were purified at similar yields as the WT and display a loss of enzymatic activity without large structural protein alterations.

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Mutant β3GalT6 proteins were purified at similar yields as the WT and di...
(A) Schematic representation of the WT and mutant b3GalT6 proteins. The maltose-binding protein (MBP) is in purple. (B) Expression of WT and mutant MBP-ΔNter29-b3GalT proteins in E. coli. From left to right, cell lysates (L) before and after induction with IPTG, supernatant (S), and purified protein fraction (P). (C) Chemical structure of the synthetic phosphorylated acceptor substrate Gal-Xyl(2P)-OMN used in GT assays. (D) Michaelis-Menten kinetics of MBP-b3GalT6ΔNter29-WT toward the donor substrate UDP-Gal and the acceptor substrate Gal-Xyl(2P)-OMN. Data are expressed as mean ± SD (n = 3 protein batches in duplicate). (E) Multiple sequence alignment of the catalytic domain of WT β3GalT6 from different species. Protein sequences are from Homo sapiens (UniProtKB:Q96L58), Pan troglodytes (UniProtKB:H2PXT4), Macaca mulatta (UniProtKB:F7CX70), Canis familiaris (UniProtKB:Q257A0), Bos taurus (UniProtKB:F1MVH6), Mus musculus (UniProtKB:Q91Z92), Rattus norvegicus (UniProtKB:D3ZQC1), Gallus gallus (UniProtKB:A0A8V0ZK44), Danio rerio (UniProtKB:Q256Z7), Anopheles gambiae (NCBI:XP_319940.4), Caenorhabditis elegans (UniProtKB:Q9N491), Xenopus tropicalis (UniProtKB:Q5BL85), Drosophilia melanogaster (UniProtKB:A1Z7G9). Residues are coloured according to their physicochemical properties by the Clustal Omega software (68). The mutated residues are framed. (F) Far-UV CD spectra of MBP-b3GalT6ΔNter29-WT (black), MBP-b3GalT6ΔNter29-Y182C (blue), MBP-b3GalT6ΔNter29-D207H (green) and MBP-b3GalT6ΔNter29-G217S (red). Data are mean of 3 measurements per protein.