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Approved therapies for Fabry disease (FD) include migalastat, an oral pharmacological chaperone, and agalsidase beta and agalsidase alfa, 2 forms of enzyme replacement therapy. Broad tissue distribution may be beneficial for clinical efficacy in FD, which has severe manifestations in multiple organs. Here, migalastat and agalsidase beta biodistribution were assessed in mice and modeled using physiologically based pharmacokinetic (PBPK) analysis, and migalastat biodistribution was subsequently extrapolated to humans. In mice, migalastat concentration was highest in kidneys and the small intestine, 2 FD‐relevant organs. Agalsidase beta was predominantly sequestered in the liver and spleen (organs unaffected in FD). PBPK modeling predicted that migalastat 123 mg every other day resulted in concentrations exceeding the in vitro half‐maximal effective concentration in kidneys, small intestine, skin, heart, and liver in human subjects. However, extrapolation of mouse agalsidase beta concentrations to humans was unsuccessful. In conclusion, migalastat may distribute to tissues that are inaccessible to intravenous agalsidase beta in mice, and extrapolation of mouse migalastat concentrations to humans showed adequate tissue penetration, particularly in FD‐relevant organs.

Pompe disease is a rare inherited disorder of lysosomal glycogen metabolism due to acid α-glucosidase (GAA) deficiency. Enzyme replacement therapy (ERT) using alglucosidase alfa, a recombinant human GAA (rhGAA), is the only approved treatment for Pompe disease. Although alglucosidase alfa has provided clinical benefits, its poor targeting to key disease-relevant skeletal muscles results in suboptimal efficacy. We are developing an rhGAA, ATB200 (Amicus proprietary rhGAA), with high levels of mannose-6-phosphate that are required for efficient cellular uptake and lysosomal trafficking. When administered in combination with the pharmacological chaperone AT2221 (miglustat), which stabilizes the enzyme and improves its pharmacokinetic properties, ATB200/AT2221 was substantially more potent than alglucosidase alfa in a mouse model of Pompe disease. The new investigational therapy is more effective at reversing the primary abnormality — intralysosomal glycogen accumulation — in multiple muscles. Furthermore, unlike the current standard of care, ATB200/AT2221 dramatically reduces autophagic buildup, a major secondary defect in the diseased muscles. The reversal of lysosomal and autophagic pathologies leads to improved muscle function. These data demonstrate the superiority of ATB200/AT2221 over the currently approved ERT in the murine model.

Fabry disease is an X-linked lysosomal storage disorder caused by mutations in the gene that encodes α-galactosidase A and is characterized by pathological accumulation of globotriaosylceramide and globotriaosylsphingosine. Earlier, the authors demonstrated that oral coadministration of the pharmacological chaperone AT1001 (migalastat HCl; 1-deoxygalactonojirimycin HCl) prior to intravenous administration of enzyme replacement therapy improved the pharmacological properties of the enzyme. In this study, the authors investigated the effects of coformulating AT1001 with a proprietary recombinant human α-galactosidase A (ATB100) into a single intravenous formulation. AT1001 increased the physical stability and reduced aggregation of ATB100 at neutral pH in vitro, and increased the potency for ATB100-mediated globotriaosylceramide reduction in cultured Fabry fibroblasts. In Fabry mice, AT1001 coformulation increased the total exposure of active enzyme, and increased ATB100 levels in cardiomyocytes, cardiac vascular endothelial cells, renal distal tubular epithelial cells, and glomerular cells, cell types that do not show substantial uptake with enzyme replacement therapy alone. Notably, AT1001 coformulation also leads to greater tissue globotriaosylceramide reduction when compared with ATB100 alone, which was positively correlated with reductions in plasma globotriaosylsphingosine. Collectively, these data indicate that intravenous administration of ATB100 coformulated with AT1001 may provide an improved therapy for Fabry disease and thus warrants further investigation.

Pompe disease is an inherited lysosomal storage disorder that results from a deficiency in acid α-glucosidase (GAA) activity due to mutations in the GAA gene. Pompe disease is characterized by accumulation of lysosomal glycogen primarily in heart and skeletal muscles, which leads to progressive muscle weakness. We have shown previously that the small molecule pharmacological chaperone AT2220 (1-deoxynojirimycin hydrochloride, duvoglustat hydrochloride) binds and stabilizes wild-type as well as multiple mutant forms of GAA, and can lead to higher cellular levels of GAA. In this study, we examined the effect of AT2220 on mutant GAA, in vitro and in vivo, with a primary focus on the endoplasmic reticulum (ER)-retained P545L mutant form of human GAA (P545L GAA). AT2220 increased the specific activity of P545L GAA toward both natural (glycogen) and artificial substrates in vitro. Incubation with AT2220 also increased the ER export, lysosomal delivery, proteolytic processing, and stability of P545L GAA. In a new transgenic mouse model of Pompe disease that expresses human P545L on a Gaa knockout background (Tg/KO) and is characterized by reduced GAA activity and elevated glycogen levels in disease-relevant tissues, daily oral administration of AT2220 for 4 weeks resulted in significant and dose-dependent increases in mature lysosomal GAA isoforms and GAA activity in heart and skeletal muscles. Importantly, oral administration of AT2220 also resulted in significant glycogen reduction in disease-relevant tissues. Compared to daily administration, less-frequent AT2220 administration, including repeated cycles of 4 or 5 days with AT2220 followed by 3 or 2 days without drug, respectively, resulted in even greater glycogen reductions. Collectively, these data indicate that AT2220 increases the specific activity, trafficking, and lysosomal stability of P545L GAA, leads to increased levels of mature GAA in lysosomes, and promotes glycogen reduction in situ. As such, AT2220 may warrant further evaluation as a treatment for Pompe disease.

Pompe disease is an inherited lysosomal storage disease that results from deficiency in acid alpha-glucosidase (GAA) activity, and is characterized by progressive accumulation of lysosomal glycogen in heart and skeletal muscles. Enzyme replacement therapy using recombinant human GAA (rhGAA) is the only approved treatment available for Pompe disease. While rhGAA provides some clinical benefits, the infused enzyme tends to be unstable at neutral pH/body temperature, shows insufficient uptake in key tissues, and can elicit immune responses that affect tolerability and efficacy. We have shown previously that oral pre-administration of the pharmacological chaperone AT2220 (1-deoxynojirimycin HCl, duvoglustat HCl) improves the pharmacological properties of rhGAA via binding and stabilization, leading to increased enzyme uptake and glycogen reduction in GAA knock-out (KO) mice. In this study we tested the effects of intravenous (IV) and subcutaneous (SQ) administration of co-formulated AT2220 and rhGAA (AT2220 + rhGAA) as an alternative to giving AT2220 orally prior to rhGAA IV. In rats, IV or SQ administration of co-formulated AT2220 + rhGAA increased the circulating half-life of rhGAA up to twofold, though the maximal rhGAA plasma levels achieved via the SQ route were significantly lower than those seen following IV administration. In GAA KO mice, four IV administrations of co-formulated AT2220 + rhGAA resulted in up to 2.5-fold greater enzyme uptake and glycogen reduction in disease-relevant tissues compared to rhGAA alone; histological staining confirmed reduced skeletal muscle glycogen. Interestingly, four SQ administrations of co-formulated AT2220 + rhGAA increased rhGAA uptake in GAA KO mice, which was not significantly different from those seen following four IV administrations of rhGAA alone. Collectively, these data highlight the potential effects of co-formulated AT2220 + rhGAA using IV or SQ administration, thus warranting further preclinical investigation.

Pompe disease is an inherited lysosomal disorder that results from a deficiency in acid α-glucosidase (GAA), and is characterized by progressive accumulation of lysosomal glycogen in cardiac and skeletal muscles. Enzyme replacement therapy (ERT) using recombinant human GAA (rhGAA) is the only approved treatment available for Pompe disease. This ERT requires the specialized carbohydrate mannose 6-phosphate (M6P) for cellular uptake and subsequent delivery to lysosomes via cell surface cation-independent M6P receptors (CI-MPRs). However, the current rhGAA ERT contains low amounts of M6P that limit drug targeting and efficacy in diseaserelevant tissues. We have developed a proprietary production cell line and manufacturing process that yield a novel rhGAA (designated as ATB200) with optimal glycosylation and higher M6P content, particularly the high-affinity bis-M6P N-glycan structure, for improved drug targeting. ATB200 binds the CI-MPR with high affinity (KD ~ 2–4 nM) and was efficiently internalized by Pompe fibroblasts and skeletal muscle myoblasts (Kuptake ~ 7–14 nM). ATB200 was evaluated in vivo and shown to be much more effective for clearing accumulated glycogen in skeletal muscles of Gaa KO mice than the current rhGAA ERT. Our results indicate that bi-weekly administrations of 5 mg/kg ATB200 were equivalent to 20 mg/kg rhGAA for reducing glycogen, while substantially greater glycogen clearance was observed with 20 mg/kg ATB200 compared to 20 mg/kg rhGAA in key skeletal muscles. These results were confirmed by histological examination. The addition of a pharmacological chaperone (PC) enhanced glycogen reduction by ATB200. Taken together, these data demonstrate that the higher M6P content of ATB200 results in better lysosomal targeting and substrate reduction, which can be further improved by combination with a PC, thus warranting further investigation of this next-generation treatment for Pompe disease.