Beth L. Thurberg

Recombinant human acid α-glucosidase: Major clinical benefits in infantile-onset Pompe disease

Background: Pompe disease is a progressive metabolic neuromuscular disorder resulting from deficiency of lysosomal acid α-glucosidase (GAA). Infantile-onset Pompe disease is characterized by cardiomyopathy, respiratory and skeletal muscle weakness, and early death. The safety and efficacy of recombinant human (rh) GAA were evaluated in 18 patients with rapidly progressing infantile-onset Pompe disease. Methods: Patients were diagnosed at 6 months of age and younger and exhibited severe GAA deficiency and cardiomyopathy. Patients received IV infusions of rhGAA at 20 mg/kg (n = 9) or 40 mg/kg (n = 9) every other week. Analyses were performed 52 weeks after the last patient was randomized to treatment. Results: All patients (100%) survived to 18 months of age. A Cox proportional hazards analysis demonstrated that treatment reduced the risk of death by 99%, reduced the risk of death or invasive ventilation by 92%, and reduced the risk of death or any type of ventilation by 88%, as compared to an untreated historical control group. There was no clear advantage of the 40-mg/kg dose with regard to efficacy. Eleven of the 18 patients experienced 164 infusion-associated reactions; all were mild or moderate in intensity. Conclusions: Recombinant human acid α-glucosidase is safe and effective for treatment of infantile-onset Pompe disease. Eleven patients experienced adverse events related to treatment, but none discontinued. The young age at which these patients initiated therapy may have contributed to their improved response compared to previous trials with recombinant human acid α-glucosidase in which patients were older.

Characterization of pre- and post-treatment pathology after enzyme replacement therapy for pompe disease

In Pompe disease, a genetic deficiency of lysosomal acid α-glucosidase, glycogen accumulates abnormally in the lysosomes of skeletal, cardiac and smooth muscle, and contributes to clinically progressive and debilitating muscle weakness. The present study involved 8 infantile-onset Pompe patients, treated weekly with 10 mg/kg of recombinant human acid α-glucosidase (rhGAA). Muscle biopsies were obtained at baseline, 12 and 52 weeks post-treatment to establish an indicator of efficacy. Several histologic strategies were employed to characterize changes in pre- and post-treatment samples, including high-resolution light microscopy and digital histomorphometry, electron microscopy, capillary density and fiber type analysis, and confocal microscopy for satellite cell activation analysis. Histomorphometric analysis was performed on muscle samples to assess glycogen depletion in response to enzyme replacement therapy (ERT). The extent of glycogen clearance varied widely among these patient samples, and correlated well with clinical outcome. Low glycogen levels, mild ultrastructural damage, a high proportion of type I fibers, and young age at baseline were all features associated with good histologic response. There was no correlation between capillary density and glycogen clearance, and activated satellite cell levels were shown to be higher in post-treatment biopsies with poor histologic responses. This histopathologic study of infantile Pompe disease provides detailed insight into the cellular progression of the disease and its response to therapy while highlighting a number of methodologies which may be employed to assess regression or progression of the associated pathology. As enzyme replacement therapy becomes more prevalent for the treatment of lysosomal storage diseases, such evaluation of post-treatment pathology will likely become a more common occurrence in the daily practice of pathologists.

Pompe Disease in Infants: Improving the Prognosis by Newborn Screening and Early Treatment

OBJECTIVE: Pompe disease causes progressive, debilitating, and often life-threatening musculoskeletal, respiratory, and cardiac symptoms. Favorable outcomes with early intravenous enzyme-replacement therapy and alglucosidase alfa have been reported, but early clinical diagnosis before the development of severe symptoms has rarely been possible in infants. METHODS: We recently conducted a newborn screening pilot program in Taiwan to improve the early detection of Pompe disease. Six of 206088 newborns screened tested positive and were treated for Pompe disease. Five had the rapidly progressive form of Pompe disease, characterized by cardiac and motor involvement, and were treated soon after diagnosis. The sixth patient was started on treatment at 14 months of age because of progressive muscle weakness. Outcomes were compared with treated patients whose disease was diagnosed clinically and with untreated historical control subjects. RESULTS: At the time of this report, patients had been treated for 14 to 32 months. The 5 infants who had early cardiac involvement demonstrated normalization of cardiac size and muscle pathology with normal physical growth and age-appropriate gains in motor development. The infant without cardiac involvement also achieved normal motor development with treatment. Survival in patients who had newborn screening was significantly improved compared with those in the untreated reference cohort (P = .001). Survival in the treated clinical comparators was reduced but not statistically different from that in the newborn screening group (P = .48). CONCLUSIONS: Results from this study indicate that early treatment can benefit infants with Pompe disease and highlight the advantages of early diagnosis, which can be achieved by newborn screening.

Cardiac Microvascular Pathology in Fabry Disease Evaluation of Endomyocardial Biopsies Before and After Enzyme Replacement Therapy

Background— In classic Fabry patients, accelerated coronary atherosclerosis and left ventricular hypertrophy manifest in the fourth decade; however, signs of cardiovascular disease also are observed later in life in “cardiac variant” patients and symptomatic female heterozygotes. These disturbances are caused by globotriaosylceramide (GL-3) accumulation in the heart resulting from lysosomal &agr;-galactosidase A deficiency. Methods and Results— We analyzed pretreatment and posttreatment endomyocardial biopsies from 58 Fabry patients enrolled in a 5-month, phase 3, double-blind, randomized, placebo-controlled trial, followed by a 54-month open-label extension study of recombinant human &agr;-galactosidase A. Baseline evaluations revealed GL-3 deposits in interstitial capillary endothelial cells and large, laminated inclusions within cardiomyocytes. In this study, we evaluated microvascular GL-3 clearance; no clearance of GL-3 was observed in the cardiomyocytes during this trial. Five months of recombinant human &agr;-galactosidase A treatment in the phase 3 trial resulted in complete microvascular clearance of GL-3 from 72% of treated patients compared with only 3% of placebo patients (P<0.001). The placebo group achieved similar results after 6 months of treatment in the open-label trial. In addition, the capillary endothelium remained free of GL-3 for up to 60 months in 6 of 8 patients who consented to an end-of-study biopsy. Conclusions— The findings suggest that long-term treatment with recombinant human &agr;-galactosidase A may halt the progression of vascular pathology and prevent the clinical manifestations of atherosclerotic disease. This histopathological study should be a useful guide for clinicians and pathologists who diagnose and follow Fabry patients.

Exercise Capacity of Mice Genetically Lacking Muscle Glycogen Synthase IN MICE, MUSCLE GLYCOGEN IS NOT ESSENTIAL FOR EXERCISE

The glucose storage polymer glycogen is generally considered to be an important source of energy for skeletal muscle contraction and a factor in exercise endurance. A genetically modified mouse model lacking muscle glycogen was used to examine whether the absence of the polysaccharide affects the ability of mice to run on a treadmill. The MGSKO mouse has the GYS1 gene, encoding the muscle isoform of glycogen synthase, disrupted so that skeletal muscle totally lacks glycogen. The morphology of the soleus and quadriceps muscles from MGSKO mice appeared normal. MGSKO-null mice, along with wild type littermates, were exercised to exhaustion. There were no significant differences in the work performed by MGSKO mice as compared with their wild type littermates. The amount of liver glycogen consumed during exercise was similar for MGSKO and wild type animals. Fasting reduced exercise endurance, and after overnight fasting, there was a trend to reduced exercise endurance for the MGSKO mice. These studies provide genetic evidence that in mice muscle glycogen is not essential for strenuous exercise and has relatively little effect on endurance.

Carbohydrate-remodelled acid α-glucosidase with higher affinity for the cation-independent mannose 6-phosphate receptor demonstrates improved delivery to muscles of Pompe mice

To enhance the delivery of rhGAA (recombinant GAA, where GAA stands for acid alpha-glucosidase) to the affected muscles in Pompe disease, the carbohydrate moieties on the enzyme were remodelled to exhibit a high affinity ligand for the CI-MPR (cation-independent M6P receptor, where M6P stands for mannose 6-phosphate). This was achieved by chemically conjugating on to rhGAA, a synthetic oligosaccharide ligand bearing M6P residues in the optimal configuration for binding the receptor. The carbonyl chemistry used resulted in the conjugation of approx. six synthetic ligands on to each enzyme. The resulting modified enzyme [neo-rhGAA (modified recombinant human GAA harbouring synthetic oligosaccharide ligands)] displayed near-normal specific activity and significantly increased affinity for the CI-MPR. However, binding to the mannose receptor was unaffected despite the introduction of additional mannose residues in neo-rhGAA. Uptake studies using L6 myoblasts showed neo-rhGAA was internalized approx. 20-fold more efficiently than the unmodified enzyme. Administration of neo-rhGAA into Pompe mice also resulted in greater clearance of glycogen from all the affected muscles when compared with the unmodified rhGAA. Comparable reductions in tissue glycogen levels in the Pompe mice were realized using an approx. 8-fold lower dose of neo-rhGAA in the heart and diaphragm and an approx. 4-fold lower dose in the skeletal muscles. Treatment of older Pompe mice, which are more refractory to enzyme therapy, with 40 mg/kg neo-rhGAA resulted in near-complete clearance of glycogen from all the affected muscles as opposed to only partial correction with the unmodified rhGAA. These results demonstrate that remodelling the carbohydrate of rhGAA to improve its affinity for the CI-MPR represents a feasible approach to enhance the efficacy of enzyme replacement therapy for Pompe disease.

BIOCHEMICAL AND PHARMACOLOGICAL CHARACTERIZATION OF DIFFERENT RECOMBINANT ACID α-GLUCOSIDASE PREPARATIONS EVALUATED FOR THE TREATMENT OF POMPE DISEASE

Pompe disease results in the accumulation of lysosomal glycogen in multiple tissues due to a deficiency of acid alpha-glucosidase (GAA). Enzyme replacement therapy for Pompe disease was recently approved in Europe, the U.S., Canada, and Japan using a recombinant human GAA (Myozyme, alglucosidase alfa) produced in CHO cells (CHO-GAA). During the development of alglucosidase alfa, we examined the in vitro and in vivo properties of CHO cell-derived rhGAA, an rhGAA purified from the milk of transgenic rabbits, as well as an experimental version of rhGAA containing additional mannose-6-phosphate intended to facilitate muscle targeting. Biochemical analyses identified differences in rhGAA N-termini, glycosylation types and binding properties to several carbohydrate receptors. In a mouse model of Pompe disease, glycogen was more efficiently removed from the heart than from skeletal muscle for all enzymes, and overall, the CHO cell-derived rhGAA reduced glycogen to a greater extent than that observed with the other enzymes. The results of these preclinical studies, combined with biochemical characterization data for the three molecules described within, led to the selection of the CHO-GAA for clinical development and registration as the first approved therapy for Pompe disease.

Later-Onset Pompe Disease: Early Detection and Early Treatment Initiation Enabled by Newborn Screening

OBJECTIVE To determine whether newborn screening facilitates early detection and thereby early treatment initiation for later-onset Pompe disease. STUDY DESIGN We have conducted a newborn screening program since 2005. Newborns with deficient skin fibroblast acid α-glucosidase activity and two acid α-glucosidase gene mutations but no cardiomyopathy were defined as having later-onset Pompe disease, and their motor development and serum creatine kinase levels were monitored every 3 to 6 months. RESULTS Among 344 056 newborns, 13 (1 in 26 466) were found to have later-onset Pompe disease. During a follow-up period of up to 4 years, four patients were treated because of hypotonia, muscle weakness, delayed developmental milestones/motor skills, or elevated creatine kinase levels starting at the ages of 1.5, 14, 34, and 36 months, respectively. Muscle biopsy specimens obtained from the treated patients revealed increased storage of glycogen and lipids. CONCLUSION Newborn screening was found to facilitate the early detection of later-onset Pompe disease. A subsequent symptomatic approach then identifies patients who need early treatment initiation.

High-resolution Light Microscopy (HRLM) and Digital Analysis of Pompe Disease Pathology

Pompe disease is an autosomal recessive lysosomal storage disorder caused by a deficiency of the lysosomal enzyme acid α-glucosidase, responsible for the degradation of lysosomal glycogen. Absent or low levels of the enzyme leads to lysosomal glycogen accumulation in cardiac and skeletal muscle cells, resulting in progressive muscle weakness and death from cardiac or respiratory failure. Recombinant enzyme replacement and gene therapy are now being investigated as treatment modalities for this disease. A knockout mouse model for Pompe disease, induced by the disruption of exon 6 within the acid α-glucosidase gene, mimics the human disease and has been used to evaluate the efficacy of treatment modalities for clearing glycogen. However, for accurate histopathological assessment of glycogen clearance, maximal preservation of in situ lysosomal glycogen is essential. To improve retention of glycogen in Pompe tissues, several fixation and embedding regimens were evaluated. The best glycogen preservation was obtained when tissues fixed with 3% glutaraldehyde and postfixed with 1% osmium tetroxide were processed into epon-araldite. Preservation was confirmed by staining with the Periodic acid-Schiffs reaction and by electron microscopy. This methodology resulted in high-resolution light microscopy (HRLM) sections suitable for digital quantification of glycogen content in heart and skeletal muscle. Combining this method of tissue fixation with computer-assisted histomorphometry has provided us with what we believe is the most objective and reproducible means of evaluating histological glycogen load in Pompe disease.

Autopsy findings in late-onset Pompe disease: A case report and systematic review of the literature

BACKGROUND Late-onset Pompe disease (LOPD) is a rare cause of declining proximal muscle strength and respiratory function that can also affect other organ systems. The development of enzyme replacement therapy has made it one of the few inherited muscle disorders with treatment, but clinical response is difficult to assess due to the variable and often slow progression of illness. A better understanding of the diseases systemic effects can be gleaned through autopsy findings. PURPOSE The purpose of this study was to: (1) describe the histological findings observed in LOPD, (2) provide correlations between reported histological and clinical findings, and (3) review the literature on autopsy findings in LOPD. METHODS Histological evaluation of autopsy tissues from a 62-year-old woman with LOPD was conducted. A clinical history was obtained by review of the medical records. The literature was reviewed for previously reported histological and clinical findings in LOPD. Based on this case report and information from prior publications, histological and clinical findings for the disease were correlated. RESULTS Histologic examination revealed mostly mild vacuolar myopathy typical of glycogen accumulation within skeletal and smooth muscle cells. The most prominent vacuolar myopathy was in quadriceps muscle, which also exhibited chronic myositis with degenerating and regenerating muscle fibers. Transmission electron microscopy disclosed lysosomal glycogen accumulation within skeletal, cardiac, and vascular smooth muscle cells, correlating with published case reports of basilar artery and ascending aortic aneurysms and carotid artery dissection. Organs containing smooth muscle cells (the bladder, intestine, and esophagus) were also affected, explaining reports of symptoms such as urinary incontinence and dysphagia. In addition to glycogen accumulation, there was obvious damage to the contraction apparatus of myofibrils within cardiac and skeletal muscle cells. These histological and ultrastructural findings correlate with the clinical manifestations of LOPD. CONCLUSIONS This study is the first to describe histological findings of LOPD utilizing both traditional paraffin-processed tissues and epoxy resin embedded tissues for high-resolution light microscopy. The findings are similar to those seen in previous studies, but with improved morphological detail and glycogen preservation. This patient exhibited histological involvement of multiple organs, correlating with the clinical features of LOPD. With the advent of definitive therapy for Pompe disease, it is important to be aware of these findings and use them to develop methods for tracking therapeutic response.