UNLABELLED: Sapropterin dihydrochloride, a synthetic tetrahydrobiopterin (BH4), works as a chaperone of phenylalanine hydroxylase (PAH) in phenylketonuria (PKU) to facilitate and stabilize folding of PAH into its most active conformation. No standard pharmacogenetic tests exist to identify responsive genotypes. Previous studies have failed to identify genotypes that consistently predict response; they are weakened by varied: 1) doses; 2) response definitions; 3) duration; 4) phenylalanine (PHE) test times during different protein catabolic states; 5) control of dietary PHE. START (sapropterin therapy actual response test) protocol is a double blind, placebo-controlled, 4-week clinical test that obviates the confounders aforementioned. START results were evaluated for response-genotype correlates and trends in molecular characteristics. RESULTS: Seventy-four patients completed START. Thirty-six patients (48.6%) responded, 55 patients' genotypes are known, 38 unique genotypes are present. Alleles consistently associated with response include Y414C (8/8 patients, 6 genotypes) and I65T (9/9 patients, 6 genotypes). The p.R408W mutation, in which substitution of straight chain arginine with bulky aromatic amine, tryptophan, at the crux of a strategic hinge site activating folding of PAH, amino acid sequence 408, was strongly associated with non-response (21/29 patients non-responsive, 12/17 genotypes non-responsive). Genotypes containing at least one allele with ≥25% residual activity compared to wild type, were strongly associated with response. CONCLUSIONS: The START protocol provides a rigorous pharmacogenetic test to identify sapropterin responsiveness and genotypes associated with responsiveness and non-responsiveness. Some genotypes were found to be predictive of responsiveness or non-responsiveness, and responsiveness was associated with specific alleles. The START protocol provides a reliable test for sapropterin responsiveness and will continue to improve understanding of how PKU mutations impact PAH protein-folding dynamics and enhance understanding of PKU disease and its management.
RCT Entities:
UNLABELLED: Sapropterin dihydrochloride, a synthetic tetrahydrobiopterin (BH4), works as a chaperone of phenylalanine hydroxylase (PAH) in phenylketonuria (PKU) to facilitate and stabilize folding of PAH into its most active conformation. No standard pharmacogenetic tests exist to identify responsive genotypes. Previous studies have failed to identify genotypes that consistently predict response; they are weakened by varied: 1) doses; 2) response definitions; 3) duration; 4) phenylalanine (PHE) test times during different protein catabolic states; 5) control of dietary PHE. START (sapropterin therapy actual response test) protocol is a double blind, placebo-controlled, 4-week clinical test that obviates the confounders aforementioned. START results were evaluated for response-genotype correlates and trends in molecular characteristics. RESULTS: Seventy-four patients completed START. Thirty-six patients (48.6%) responded, 55 patients' genotypes are known, 38 unique genotypes are present. Alleles consistently associated with response include Y414C (8/8 patients, 6 genotypes) and I65T (9/9 patients, 6 genotypes). The p.R408W mutation, in which substitution of straight chain arginine with bulky aromatic amine, tryptophan, at the crux of a strategic hinge site activating folding of PAH, amino acid sequence 408, was strongly associated with non-response (21/29 patients non-responsive, 12/17 genotypes non-responsive). Genotypes containing at least one allele with ≥25% residual activity compared to wild type, were strongly associated with response. CONCLUSIONS: The START protocol provides a rigorous pharmacogenetic test to identify sapropterin responsiveness and genotypes associated with responsiveness and non-responsiveness. Some genotypes were found to be predictive of responsiveness or non-responsiveness, and responsiveness was associated with specific alleles. The START protocol provides a reliable test for sapropterin responsiveness and will continue to improve understanding of how PKU mutations impact PAH protein-folding dynamics and enhance understanding of PKU disease and its management.
Authors: Priscila Nicolao Mazzola; George Albert Karikas; Kleopatra H Schulpis; Carlos Severo Dutra-Filho Journal: Metab Brain Dis Date: 2013-05-09 Impact factor: 3.584
Authors: Sarah Leuders; Eva Wolfgart; Torsten Ott; Marcel du Moulin; Agnes van Teeffelen-Heithoff; Lydia Vogelpohl; Ulrike Och; Thorsten Marquardt; Josef Weglage; Reinhold Feldmann; Frank Rutsch Journal: JIMD Rep Date: 2013-11-05
Authors: Jerry Vockley; Steven F Dobrowolski; Georgianne L Arnold; Ruben Bonilla Guerrero; Terry G J Derks; David A Weinstein Journal: Mol Genet Metab Date: 2019-07-19 Impact factor: 4.797