Download MendeleyStructural insight into the hydrolase and synthase activities of an alkaline alpha-galactosidase from Arabidopsis from complexes with substrate/product.
Chuankhayan, P., Lee, R.H., Guan, H.H., Lin, C.C., Chen, N.C., Huang, Y.C., Yoshimura, M., Nakagawa, A., Chen, C.J.(2023) Acta Crystallogr D Struct Biol 79: 154-167
- PubMed: 36762861
- DOI: https://doi.org/10.1107/S2059798323000037
- Primary Citation of Related Structures:
7EXF, 7EXG, 7EXH, 7EXJ, 7EXQ, 7EXR - PubMed Abstract:
The alkaline ¦Á-galactosidase AtAk¦ÁGal3 from Arabidopsis thaliana catalyzes the hydrolysis of ¦Á-D-galactose from galacto-oligosaccharides under alkaline conditions. A phylogenetic analysis based on sequence alignment classifies AtAk¦ÁGal3 as more closely related to the raffinose family of oligosaccharide (RFO) synthases than to the acidic ¦Á-galactosidases. Here, thin-layer chromatography is used to demonstrate that AtAk¦ÁGal3 exhibits a dual function and is capable of synthesizing stachyose using raffinose, instead of galactinol, as the galactose donor. Crystal structures of complexes of AtAk¦ÁGal3 and its D383A mutant with various substrates and products, including galactose, galactinol, raffinose, stachyose and sucrose, are reported as the first representative structures of an alkaline ¦Á-galactosidase. The structure of?AtAk¦ÁGal3 comprises three domains: an N-terminal domain with 13 antiparallel ¦Â-strands, a catalytic domain with an (¦Á/¦Â) 8 -barrel fold and a C-terminal domain composed of ¦Â-sheets that form two Greek-key motifs. The WW box of the N-terminal domain, which comprises the conserved residues FRSK 75 XW 77 W 78 in the RFO synthases, contributes Trp77 and Trp78 to the +1 subsite to contribute to the substrate-binding ability together with the (¦Á/¦Â) 8 barrel of the catalytic domain. The C-terminal domain is presumably involved in structural stability. Structures of the D383A mutant in complex with various substrates and products, especially the natural substrate/product stachyose, reveal four complete subsites (-1 to +3) at the catalytic site. A functional loop (residues 329-352) that exists in the alkaline ¦Á-galactosidase AtAk¦ÁGal3 and possibly in RFO synthases, but not in acidic ¦Á-galactosidases, stabilizes the stachyose at the +2 and +3 subsites and extends the catalytic pocket for the transferase mechanism. Considering the similarities in amino-acid sequence, catalytic domain and activity between alkaline ¦Á-galactosidases and RFO synthases, the structure of AtAk¦ÁGal3 might also serve a model for the study of RFO synthases, structures of which are lacking.
Organizational Affiliation:
Life Science Group, Scientific Research Division, National Synchrotron Radiation Research Cente, Hsinchu 30076, Taiwan.
