Protein structural features predict responsiveness to pharmacological chaperone treatment for three lysosomal storage disorders

Abstract: Three-dimensional structures of proteins can provide important clues into the efficacy of personalized treatment. We perform a structural analysis of variants within three inherited lysosomal storage disorders, comparing variants responsive to pharmacological chaperone treatment to those unresponsive to such treatment. We find that predicted ΔΔG of mutation is higher on average for variants unresponsive to treatment, in the case of datasets for both Fabry disease and Pompe disease, in line with previous findin… Show more

“…In this study, a large number of inverse parallel relations was predictive of nonresponsiveness to pharmacological chaperone treatment. For a triosephosphate isomerase (TIM) barrel protein, the structure of which is contained in three lysosomal storage disorder proteins studied, residues with many inverse parallel relations were in fact early to fold, according to hydrogen‐deuterium exchange experiments, consistent with a model where late to fold residues are more likely to be rescued 49,51 . It was found that the dependence on the inverse parallel relation according to a simple decision tree is consistent with a simple kinetic model of folding, binding, and export.…”

“…This work relates to a recent study evaluating the importance of structural features in predicting and explaining drug responsiveness in lysosomal storage disorders. 49 In this study, a large number of inverse parallel relations was predictive of nonresponsiveness to pharmacological chaperone treatment. For a triosephosphate isomerase (TIM) barrel protein, the structure of which is contained in three lysosomal storage disorder proteins studied, residues with many inverse parallel relations were in fact early to fold, according to hydrogen-deuterium exchange experiments, consistent with a model where late to fold residues are more likely to be rescued.…”

“…This work relates to a recent study evaluating the importance of structural features in predicting and explaining drug responsiveness in lysosomal storage disorders 49 . In this study, a large number of inverse parallel relations was predictive of nonresponsiveness to pharmacological chaperone treatment.…”

“…The inverse parallel relation also shows substantial contribution to pathogenicity. According to models of folding, 30,49 residues with many inverse parallel relations are likely to be early to fold, indicating that they would be expected to disrupt rate of folding. The hypothesis that the relative importance of the inverse parallel and cross relations indicate an importance of folding kinetics and non‐native interactions in determining pathogenicity can be validated in the future using newly developed all‐atom models of (un)folding and misfolding 50 …”

“…The inverse parallel relation also shows substantial contribution to pathogenicity. According to models of folding, 30,49 residues with many inverse parallel relations are likely to be early to fold, indicating that they would be expected to disrupt rate of folding.…”

Circuit topology predicts pathogenicity of missense mutations

“…In this study, a large number of inverse parallel relations was predictive of nonresponsiveness to pharmacological chaperone treatment. For a triosephosphate isomerase (TIM) barrel protein, the structure of which is contained in three lysosomal storage disorder proteins studied, residues with many inverse parallel relations were in fact early to fold, according to hydrogen‐deuterium exchange experiments, consistent with a model where late to fold residues are more likely to be rescued 49,51 . It was found that the dependence on the inverse parallel relation according to a simple decision tree is consistent with a simple kinetic model of folding, binding, and export.…”

“…This work relates to a recent study evaluating the importance of structural features in predicting and explaining drug responsiveness in lysosomal storage disorders. 49 In this study, a large number of inverse parallel relations was predictive of nonresponsiveness to pharmacological chaperone treatment. For a triosephosphate isomerase (TIM) barrel protein, the structure of which is contained in three lysosomal storage disorder proteins studied, residues with many inverse parallel relations were in fact early to fold, according to hydrogen-deuterium exchange experiments, consistent with a model where late to fold residues are more likely to be rescued.…”

“…This work relates to a recent study evaluating the importance of structural features in predicting and explaining drug responsiveness in lysosomal storage disorders 49 . In this study, a large number of inverse parallel relations was predictive of nonresponsiveness to pharmacological chaperone treatment.…”

“…The inverse parallel relation also shows substantial contribution to pathogenicity. According to models of folding, 30,49 residues with many inverse parallel relations are likely to be early to fold, indicating that they would be expected to disrupt rate of folding. The hypothesis that the relative importance of the inverse parallel and cross relations indicate an importance of folding kinetics and non‐native interactions in determining pathogenicity can be validated in the future using newly developed all‐atom models of (un)folding and misfolding 50 …”

“…The inverse parallel relation also shows substantial contribution to pathogenicity. According to models of folding, 30,49 residues with many inverse parallel relations are likely to be early to fold, indicating that they would be expected to disrupt rate of folding.…”

Circuit topology predicts pathogenicity of missense mutations