Characterization of the complex formed by ß-glucocerebrosidase and the lysosomal integral membrane protein type-2.

The lysosomal integral membrane protein type-2 (LIMP-2) plays a pivotal role in the delivery of ß-glucocerebrosidase (GC) to lysosomes. Mutations in GC result in Gaucher's disease (GD) and are the major genetic risk factor for the development of Parkinson's disease (PD). Variants in the LIMP-2 gene cause action myoclonus-renal failure syndrome and also have been linked to PD. Given the importance of GC and LIMP-2 in disease pathogenesis, we studied their interaction sites in more detail. Our previous data demonstrated that the crystal structure of LIMP-2 displays a hydrophobic three-helix bundle composed of helices 4, 5, and 7, of which helix 5 and 7 are important for ligand binding. Here, we identified a similar helical motif in GC through surface potential analysis. Coimmunoprecipitation and immunofluorescence studies revealed a triple-helical interface region within GC as critical for LIMP-2 binding and lysosomal transport. Based on these findings, we generated a LIMP-2 helix 5-derived peptide that precipitated and activated recombinant wild-type and GD-associated N370S mutant GC in vitro. The helix 5 peptide fused to a cell-penetrating peptide also activated endogenous lysosomal GC and reduced α-synuclein levels, suggesting that LIMP-2-derived peptides can be used to activate endogenous as well as recombinant wild-type or mutant GC efficiently. Our data also provide a structural model of the LIMP-2/GC complex that will facilitate the development of GC chaperones and activators as potential therapeutics for GD, PD, and related synucleinopathies.

Disease-causing mutations within the lysosomal integral membrane protein type 2 (LIMP-2) reveal the nature of binding to its ligand beta-glucocerebrosidase.

Action myoclonus-renal failure syndrome (AMRF) is caused by mutations in the lysosomal integral membrane protein type 2 (LIMP-2/SCARB2). LIMP-2 was identified as a sorting receptor for beta-glucocerebrosidase (beta-GC), which is defective in Gaucher disease. To date, six AMRF-causing mutations have been described, including splice site, missense and nonsense mutations. All mutations investigated in this study lead to a retention of LIMP-2 in the endoplasmic reticulum (ER) but affect the binding to beta-GC differentially. From the three nonsense mutations, only the Q288X mutation was still able to bind to beta-GC as efficiently as compared with wild-type LIMP-2, whereas the W146SfsX16 and W178X mutations lost their beta-GC-binding capacity almost completely. The LIMP-2 segment 145-288, comprising the nonsense mutations, contains a highly conserved coiled-coil domain, which we suggest determines beta-GC binding. In fact, disruption of the helical arrangement and amphiphatic nature of the coiled-coil domain abolishes beta-GC binding, and a synthetic peptide comprising the coiled-coil domain of LIMP-2 displays pH-selective multimerization properties. In contrast to the reduced binding properties of the nonsense mutations, the only missense mutation (H363N) found in AMRF leads to increased binding of beta-GC to LIMP-2, indicating that this highly conserved histidine modifies the affinity of LIMP-2 to its ligand. With the present study, we demonstrate that disruption of the coiled-coil structure or AMRF disease-causing mutations abolish beta-GC binding, indicating the importance of an intact coiled-coil structure for the interaction of LIMP-2 and beta-GC.