5IN3 image
Entry Detail
PDB ID:
5IN3
Keywords:
Title:
Crystal structure of glucose-1-phosphate bound nucleotidylated human galactose-1-phosphate uridylyltransferase
Biological Source:
Source Organism:
PDB Version:
Deposition Date:
2016-03-07
Release Date:
2016-03-30
Method Details:
Experimental Method:
Resolution:
1.73 Å
R-Value Free:
0.22
R-Value Work:
0.19
R-Value Observed:
0.19
Space Group:
P 21 21 21
Macromolecular Entities
Polymer Type:polypeptide(L)
Description:Galactose-1-phosphate uridylyltransferase
Chain IDs:A (auth: B), B (auth: A)
Chain Length:401
Number of Molecules:2
Biological Source:Homo sapiens
Primary Citation
Molecular basis of classic galactosemia from the structure of human galactose 1-phosphate uridylyltransferase.
Hum.Mol.Genet. 25 2234 2244 (2016)
PMID: 27005423 DOI: 10.1093/hmg/ddw091

Abstact

Classic galactosemia is a potentially lethal disease caused by the dysfunction of galactose 1-phosphate uridylyltransferase (GALT). Over 300 disease-associated GALT mutations have been reported, with the majority being missense changes, although a better understanding of their underlying molecular effects has been hindered by the lack of structural information for the human enzyme. Here, we present the 1.9 Å resolution crystal structure of human GALT (hGALT) ternary complex, revealing a homodimer arrangement that contains a covalent uridylylated intermediate and glucose-1-phosphate in the active site, as well as a structural zinc-binding site, per monomer. hGALT reveals significant structural differences from bacterial GALT homologues in metal ligation and dimer interactions, and therefore is a zbetter model for understanding the molecular consequences of disease mutations. Both uridylylation and zinc binding influence the stability and aggregation tendency of hGALT. This has implications for disease-associated variants where p.Gln188Arg, the most commonly detected, increases the rate of aggregation in the absence of zinc likely due to its reduced ability to form the uridylylated intermediate. As such our structure serves as a template in the future design of pharmacological chaperone therapies and opens new concepts about the roles of metal binding and activity in protein misfolding by disease-associated mutants.

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Primary Citation of related structures