Malte Lenders1, Leon Paul Neußer2, Michael Rudnicki3, Peter Nordbeck4, Sima Canaan-Kühl5, Albina Nowak6, Markus Cybulla7, Boris Schmitz8, Jan Lukas9, Christoph Wanner4, Stefan-Martin Brand8, Eva Brand2. 1. Internal Medicine D, Department of Nephrology, Hypertension and Rheumatology and Eva.Brand@ukmuenster.de. 2. Internal Medicine D, Department of Nephrology, Hypertension and Rheumatology and. 3. Department of Internal Medicine IV - Nephrology and Hypertension, Medical University Innsbruck, Innsbruck, Austria. 4. Department of Internal Medicine I, Comprehensive Heart Failure Center, and Fabry Center for Interdisciplinary Therapy, University Hospital and University of Wuerzburg, Wuerzburg, Germany. 5. Division of Nephrology, Department of Medicine, Charité Universitätsmedizin Berlin, Berlin, Germany. 6. University Heart Center, Cardiology Department, University Hospital of Zurich and University of Zurich, Zurich, Switzerland. 7. Center of Internal Medicine, Department of Nephrology and Rheumatology, Fachinternistische Gemeinschaftspraxis Markgraeflerland, Muellheim, Germany; and. 8. Institute of Sports Medicine, Molecular Genetics of Cardiovascular Disease, University Hospital Muenster, Muenster, Germany. 9. Albrecht Kossel Institute for Neuroregeneration, University Rostock Medical Center, Rostock, Germany.
Abstract
BACKGROUND: Use of enzyme replacement therapy (ERT) to treat Fabry disease, caused by deficient lysosomal α-galactosidase A activity, can lead to formation of neutralizing antidrug antibodies (ADAs). These antibodies are associated with increased accumulation of plasma globotriaosylceramide (Gb3) and disease progression. Because agalsidase ERT can saturate ADA-binding sites during infusions (achieving agalsidase/antibody equilibrium), we investigated in this open cohort study whether saturated patients (who have excess agalsidase after infusions) experience better clinical outcomes compared with not saturated patients (who have excess ADAs after infusions). METHODS: We isolated ADAs from sera of 26 men with Fabry disease receiving ERT (for a median of 94 months) and determined the amount of agalsidase necessary for antibody saturation. Clinical and biochemical outcomes included measurements of eGFR, interventricular septum thickness, and lyso-Gb3. RESULTS: ADA titers decreased significantly in all patients during infusion. Agalsidase-α and agalsidase-β had similar ADA-binding capacity and comparable ADA saturation frequency. Fourteen patients with saturated ADAs presented with mild (but significant) loss of eGFR, stable septum thickness, and significantly decreased lyso-Gb3 levels. The 12 not saturated patients had a more pronounced and significant loss of eGFR, increased septum thickness, and a smaller, nonsignificant reduction in lyso-Gb3, over time. In three patients, dose escalation resulted in partially elevated ADA titers, but importantly, also in reduced lyso-Gb3 levels. CONCLUSIONS: A not saturated ADA status during infusion is associated with progressive loss of eGFR and ongoing cardiac hypertrophy. Dose escalation can result in saturation of ADAs and decreasing lyso-Gb3 levels, but may lead to increased ADA titers.
BACKGROUND: Use of enzyme replacement therapy (ERT) to treat Fabry disease, caused by deficient lysosomal α-galactosidase A activity, can lead to formation of neutralizing antidrug antibodies (ADAs). These antibodies are associated with increased accumulation of plasma globotriaosylceramide (Gb3) and disease progression. Because agalsidase ERT can saturate ADA-binding sites during infusions (achieving agalsidase/antibody equilibrium), we investigated in this open cohort study whether saturated patients (who have excess agalsidase after infusions) experience better clinical outcomes compared with not saturated patients (who have excess ADAs after infusions). METHODS: We isolated ADAs from sera of 26 men with Fabry disease receiving ERT (for a median of 94 months) and determined the amount of agalsidase necessary for antibody saturation. Clinical and biochemical outcomes included measurements of eGFR, interventricular septum thickness, and lyso-Gb3. RESULTS:ADA titers decreased significantly in all patients during infusion. Agalsidase-α and agalsidase-β had similar ADA-binding capacity and comparable ADA saturation frequency. Fourteen patients with saturated ADAs presented with mild (but significant) loss of eGFR, stable septum thickness, and significantly decreased lyso-Gb3 levels. The 12 not saturated patients had a more pronounced and significant loss of eGFR, increased septum thickness, and a smaller, nonsignificant reduction in lyso-Gb3, over time. In three patients, dose escalation resulted in partially elevated ADA titers, but importantly, also in reduced lyso-Gb3 levels. CONCLUSIONS: A not saturated ADA status during infusion is associated with progressive loss of eGFR and ongoing cardiac hypertrophy. Dose escalation can result in saturation of ADAs and decreasing lyso-Gb3 levels, but may lead to increased ADA titers.
Authors: Maryam Banikazemi; Jan Bultas; Stephen Waldek; William R Wilcox; Chester B Whitley; Marie McDonald; Richard Finkel; Seymour Packman; Daniel G Bichet; David G Warnock; Robert J Desnick Journal: Ann Intern Med Date: 2006-12-18 Impact factor: 25.391
Authors: Dominique P Germain; Derralynn A Hughes; Kathleen Nicholls; Daniel G Bichet; Roberto Giugliani; William R Wilcox; Claudio Feliciani; Suma P Shankar; Fatih Ezgu; Hernan Amartino; Drago Bratkovic; Ulla Feldt-Rasmussen; Khan Nedd; Usama Sharaf El Din; Charles M Lourenco; Maryam Banikazemi; Joel Charrow; Majed Dasouki; David Finegold; Pilar Giraldo; Ozlem Goker-Alpan; Nicola Longo; C Ronald Scott; Roser Torra; Ahmad Tuffaha; Ana Jovanovic; Stephen Waldek; Seymour Packman; Elizabeth Ludington; Christopher Viereck; John Kirk; Julie Yu; Elfrida R Benjamin; Franklin Johnson; David J Lockhart; Nina Skuban; Jeff Castelli; Jay Barth; Carrolee Barlow; Raphael Schiffmann Journal: N Engl J Med Date: 2016-08-11 Impact factor: 91.245
Authors: Karen M Ashe; Eva Budman; Dinesh S Bangari; Craig S Siegel; Jennifer B Nietupski; Bing Wang; Robert J Desnick; Ronald K Scheule; John P Leonard; Seng H Cheng; John Marshall Journal: Mol Med Date: 2015-04-30 Impact factor: 6.354
Authors: Derralynn A Hughes; Kathleen Nicholls; Suma P Shankar; Gere Sunder-Plassmann; David Koeller; Khan Nedd; Gerard Vockley; Takashi Hamazaki; Robin Lachmann; Toya Ohashi; Iacopo Olivotto; Norio Sakai; Patrick Deegan; David Dimmock; François Eyskens; Dominique P Germain; Ozlem Goker-Alpan; Eric Hachulla; Ana Jovanovic; Charles M Lourenco; Ichiei Narita; Mark Thomas; William R Wilcox; Daniel G Bichet; Raphael Schiffmann; Elizabeth Ludington; Christopher Viereck; John Kirk; Julie Yu; Franklin Johnson; Pol Boudes; Elfrida R Benjamin; David J Lockhart; Carrolee Barlow; Nina Skuban; Jeffrey P Castelli; Jay Barth; Ulla Feldt-Rasmussen Journal: J Med Genet Date: 2016-11-10 Impact factor: 6.318
Authors: Maarten Arends; Marieke Biegstraaten; Christoph Wanner; Sandra Sirrs; Atul Mehta; Perry M Elliott; Daniel Oder; Oliver T Watkinson; Daniel G Bichet; Aneal Khan; Mark Iwanochko; Frédéric M Vaz; André B P van Kuilenburg; Michael L West; Derralynn A Hughes; Carla E M Hollak Journal: J Med Genet Date: 2018-02-07 Impact factor: 6.318
Authors: Aizeddin A Mhanni; Christiane Auray-Blais; Michel Boutin; Alie Johnston; Kaye LeMoine; Jill Patterson; Johannes M F G Aerts; Michael L West; Cheryl Rockman-Greenberg Journal: Mol Genet Metab Rep Date: 2020-06-24
Authors: Sanne J van der Veen; Carla E M Hollak; André B P van Kuilenburg; Mirjam Langeveld Journal: J Inherit Metab Dis Date: 2020-03-02 Impact factor: 4.982