C. Filoni

Bio: C. Filoni is an academic researcher. The author has contributed to research in topics: Mutant & Stop codon. The author has an hindex of 2, co-authored 2 publications receiving 51 citations.

Treatment of Fabry’s Disease with the Pharmacologic Chaperone Migalastat

Abstract: BackgroundFabry’s disease, an X-linked disorder of lysosomal α-galactosidase deficiency, leads to substrate accumulation in multiple organs. Migalastat, an oral pharmacologic chaperone, stabilizes specific mutant forms of α-galactosidase, increasing enzyme trafficking to lysosomes. MethodsThe initial assay of mutant α-galactosidase forms that we used to categorize 67 patients with Fabry’s disease for randomization to 6 months of double-blind migalastat or placebo (stage 1), followed by open-label migalastat from 6 to 12 months (stage 2) plus an additional year, had certain limitations. Before unblinding, a new, validated assay showed that 50 of the 67 participants had mutant α-galactosidase forms suitable for targeting by migalastat. The primary end point was the percentage of patients who had a response (≥50% reduction in the number of globotriaosylceramide inclusions per kidney interstitial capillary) at 6 months. We assessed safety along with disease substrates and renal, cardiovascular, and patient-re...

Oral pharmacological chaperone migalastat compared with enzyme replacement therapy in Fabry disease: 18-month results from the randomised phase III ATTRACT study

Abstract: Background Fabry disease is an X-linked lysosomal storage disorder caused by GLA mutations, resulting in α-galactosidase (α-Gal) deficiency and accumulation of lysosomal substrates. Migalastat, an oral pharmacological chaperone being developed as an alternative to intravenous enzyme replacement therapy (ERT), stabilises specific mutant ( amenable ) forms of α-Gal to facilitate normal lysosomal trafficking. Methods The main objective of the 18-month, randomised, active-controlled ATTRACT study was to assess the effects of migalastat on renal function in patients with Fabry disease previously treated with ERT. Effects on heart, disease substrate, patient-reported outcomes (PROs) and safety were also assessed. Results Fifty-seven adults (56% female) receiving ERT (88% had multiorgan disease) were randomised (1.5:1), based on a preliminary cell-based assay of responsiveness to migalastat, to receive 18 months open-label migalastat or remain on ERT. Four patients had non-amenable mutant forms of α-Gal based on the validated cell-based assay conducted after treatment initiation and were excluded from primary efficacy analyses only. Migalastat and ERT had similar effects on renal function. Left ventricular mass index decreased significantly with migalastat treatment (−6.6 g/m 2 (−11.0 to −2.2)); there was no significant change with ERT. Predefined renal, cardiac or cerebrovascular events occurred in 29% and 44% of patients in the migalastat and ERT groups, respectively. Plasma globotriaosylsphingosine remained low and stable following the switch from ERT to migalastat. PROs were comparable between groups. Migalastat was generally safe and well tolerated. Conclusions Migalastat offers promise as a first-in-class oral monotherapy alternative treatment to intravenous ERT for patients with Fabry disease and amenable mutations. Trial registration number: NCT00925301; Pre-results.

Functional Characterisation of Alpha-Galactosidase A Mutations as a Basis for a New Classification System in Fabry Disease

Abstract: Fabry disease (FD) is an X-linked hereditary defect of glycosphingolipid storage caused by mutations in the gene encoding the lysosomal hydrolase α-galactosidase A (GLA, α-gal A). To date, over 400 mutations causing amino acid substitutions have been described. Most of these mutations are related to the classical Fabry phenotype. Generally in lysosomal storage disorders a reliable genotype/phenotype correlation is difficult to achieve, especially in FD with its X-linked mode of inheritance. In order to predict the metabolic consequence of a given mutation, we combined in vitro enzyme activity with in vivo biomarker data. Furthermore, we used the pharmacological chaperone (PC) 1-deoxygalactonojirimycin (DGJ) as a tool to analyse the influence of individual mutations on subcellular organelle-trafficking and stability. We analysed a significant number of mutations and correlated the obtained properties to the clinical manifestation related to the mutation in order to improve our knowledge of the identity of functional relevant amino acids. Additionally, we illustrate the consequences of different mutations on plasma lyso-globotriaosylsphingosine (lyso-Gb3) accumulation in the patients' plasma, a biomarker proven to reflect the impaired substrate clearance caused by specific mutations. The established system enables us to provide information for the clinical relevance of PC therapy for a given mutant. Finally, in order to generate reliable predictions of mutant GLA defects we compared the different data sets to reveal the most coherent system to reflect the clinical situation.

Cerebrovascular Involvement in Fabry Disease Current Status of Knowledge

Abstract: Fabry disease (FD) is a rare and highly debilitating lysosomal storage disorder that results from a total lack of, or deficiency in, the enzyme α-galactosidase A (α-Gal A) because of mutations in the GLA gene.1 FD is inherited as an X-linked trait; many of the male patients develop a classic severe phenotype with early onset of symptoms, whereas heterozygous females exhibit phenotypes ranging from asymptomatic to major involvement of vital organs.2 Most families inherit private mutations; to date, >600 mutations have been identified and are listed in the online FD database (Fabry-database.org).3 The deficiency in α-Gal A causes the accumulation of globotriaosylceramide (GL-3; also abbreviated Gb3) in various cellular compartments, particularly lysosomes, causing structural damage and cellular dysfunction, as well as triggering secondary, tissue-level responses, such as inflammation, ischemia, hypertrophy, and the development of fibrosis resulting in progressive organ dysfunction.4 Deacylated globotriaosylceramide (lyso- globotriaosylceramide [lyso-GL-3]) has also been shown to be present in increased concentrations in the plasma of patients with FD. It has been suggested that lyso-GL-3 promotes GL-3 accumulation, induces proliferation of smooth muscle cells in vitro, and may have deleterious effects on the intima and media of small arterioles.5 Many cell types are involved in FD pathology, including vascular cells (endothelial and smooth muscle cells), cardiac cells (cardiomyocytes and valvular cells), a variety of renal cells (tubular and glomerular cells, and podocytes), and nerve cells.2 The underlying pathophysiological mechanisms of FD are complex and incompletely understood.6 Early pathophysiological changes are thought to predominantly involve the microvasculature.7 As age increases, arterial remodeling and intima-media thickening in medium-to-large caliber vessels occur.2 The first clinical symptoms of FD occur in childhood (eg, neuropathic pain, hypohidrosis, and gastrointestinal problems)8 and are primarily because of autonomic neuropathy.9 As the disease …