Late-onset Pompe disease associated with polyneuropathy

Late-onset Pompe disease is caused by a glycogen deposition involving mainly striated muscle. It may also target many other tissues such as liver, smooth muscles or spine anterior horn. Glycogen accumulation in Schwann cells and in the perineurium of peripheral nerves was shown in Pompe's disease mouse models. Moreover two late-onset Pompe disease patients were reported as having a small fiber neuropathy. To the best of our knowledge an involvement of large nerve fibers was never depicted. We describe four late-onset Pompe disease patients having a concomitant polyneuropathy of undetermined etiology. Our observations reinforce the proof-of-concept supporting a potential involvement of peripheral nerves as additional organ targeted by late-onset Pompe disease. It has clinical care consequences since peripheral neuropathy in late-onset Pompe disease could worsen patient's disability and needs particular care such as proprioceptive physiotherapy.     

Screening for late-onset Pompe disease in Finland

Pompe disease (glycogen storage disease type II) is caused by autosomal recessive mutations in GAA gene. The estimated frequency of late-onset Pompe disease is around 1:60,000. However, only two infantile and one late-onset Pompe patients have been reported in Finland with a population of 5 million. We screened for late-onset Pompe disease in a cohort of undetermined myopathy patients with proximal muscle weakness and/or elevated serum creatine kinase values. Acid α-glucosidase (GAA) activity in dried blood spots was measured and clinical data collected in 108 patients. Four patients had low normal GAA activity; all the others had activities well within the normal range. Re-analyses of these patients did not reveal new Pompe patients. Our findings suggest that Pompe disease is extremely rare in Finland. Finland is an example of an isolated population with enrichment of certain mutations for genetic disorders and low occurrence of some autosomal recessive diseases.     

Diagnostic criteria for late‐onset (childhood and adult) pompe disease

The diagnosis of late‐onset (childhood and adult) Pompe disease can often be challenging, as it is a rare disease and the heterogeneous clinical presentation can mimic the presentation of other neuromuscular disorders. The objective was to develop a consensus‐based algorithm for the diagnosis of late‐onset Pompe disease. A systematic literature search was conducted, and an expert panel composed of neuromuscular specialists and individuals with expertise in Pompe disease reviewed the literature and convened for consensus development. An algorithm for the diagnosis of late‐onset Pompe disease was created. Patients presenting with either a limb‐girdle syndrome or dyspnea secondary to diaphragm weakness should undergo further testing, including evaluations of muscle strength, motor function, and pulmonary function. A blood‐based acid α‐glucosidase (GAA) enzyme activity assay is the recommended tool to screen for GAA enzyme deficiency. The diagnosis should be confirmed by a second test: either a second GAA enzyme activity assay in another tissue or GAA gene sequencing. Muscle Nerve 40:149–160, 2009     

Clinical and molecular aspects of 30 patients with late-onset Pompe disease (LOPD): unusual features and response to treatment

Pompe disease is a rare metabolic disorder, due to mutations in the gene encoding acid alpha-glucosidase (GAA), of which infantile and late-onset forms may occur. Aim of the work was to analyze clinical and laboratory data of a cohort of late-onset Pompe disease (LOPD) patients, collected during the last 15 years and to point out unusual phenotypic/genotypic features as well as enzyme replacement therapy (ERT) responses. We diagnosed 30 LOPD patients; at follow-up, they underwent motor, respiratory, cardiac and muscle MRI evaluations. Motor performances were tested by Walton Gardner-Medwin, GSGC and 6MWT tests. Respiratory function was assessed as FVC % in upright/supine position. LOPD presentations were represented by presymptomatic hyperCKemia (37 %), proximal/axial muscle weakness (53 %) and respiratory impairment (10 %). Median diagnostic delay was 8.6 years (±8.8). Atypical features were observed in 4 patients: marked distal muscle weakness and severe hearing loss at onset, as well as leukoencephalopathy and mesial temporal sclerosis during the disease course. By GAA sequence analysis, two causing mutations were detected in 22/30 patients, only one in the remaining 8 subjects. Overall, 29/30 patients harbored the common c.?32?13T>G mutation (2 were homozygous). Two new DNA variations were discovered (c.2395C>G, c.1771C>T). 14 patients received ERT for up to 60 months. Our study confirms LOPD clinical and genetic heterogeneity: atypical features may contribute to expand the clinical phenotype highlighting its multi-systemic nature. A timely diagnosis could allow early ERT start. An accurate follow-up is recommended to evaluate treatment responses.     

Swiss national guideline for reimbursement of enzyme replacement therapy in late-onset Pompe disease

Glycogen storage disease type II is a rare multi-systemic disorder characterised by an intracellular accumulation of glycogen due a mutation in the acid alpha glucosidase (GAA) gene. The level of residual enzyme activity, the genotype and other yet unknown factors account for the broad variation of the clinical phenotype. The classical infantile form is characterised by severe muscle hypotonia and cardiomyopathy leading to early death. The late-onset form presents as a limb girdle myopathy with or without pulmonary dysfunction. Enzyme replacement therapy (ERT) with recombinant human GAA (rhGAA) in infants is life saving. In contrast, therapeutic efficacy of rhGAA in the late-onset form is modest. High expenses of rhGAA, on-going infusions and poor pharmacokinetic efficacy raised a discussion of the cost effectiveness of ERT in late-onset Pompe disease in Switzerland. This discussion was triggered by a Swiss federal court ruling which confirmed the reluctance of a health care insurer not to reimburse treatment costs in a 67-year-old female suffering from Pompe disease. As a consequence of this judgement ERT was stopped by all insurance companies in late-onset Pompe patients in Switzerland regardless of their clinical condition. Subsequent negotiations lead to the release of a national guideline of the management of late-onset Pompe disease. Initiation and limitation of ERT is outlined in a national Pompe registry. Reimbursement criteria are defined and individual efficacy of ERT with rhGAA is continuously monitored.     

The clinical presentation of lysosomal storage disorders

Lysosomal storage disorders (LSDs) are present from conception and produce a clinical phenotype that evolves with time. The introduction of new therapies has made early diagnosis a priority. Clues to the clinical diagnosis of a LSD can be found in the tempo of the illness especially if the central nervous system is involved. Loss of a previously acquired skill (regression) is very characteristic of this group of disorders. Other clinical clues can include a dysmorphic appearance or the presence of characteristic skeletal involvement (dysostosis multiplex), but in some disorders such as Pompe disease or Krabbe disease, these do not occur. The approach to diagnosis has to involve "screening" as there can be considerable overlap in clinical presentation (e.g. Gaucher disease and Niemann-Pick B). Both urine and blood testing are necessary and the majority of diagnoses can now be confirmed at a molecular level. Prenatal diagnosis is possible for all.     

Close monitoring of initial enzyme replacement therapy in a patient with childhood-onset Pompe disease

Pompe disease is classified into infantile and late-onset (childhood and adult) forms based on onset age and degree of organ involvement. While benefits of enzyme replacement therapy (ERT) for the infantile form have been confirmed, efficacy for late-onset forms reportedly varies. We report close monitoring of initial ERT, focusing especially on the first year, in a 12-year-old boy with childhood-onset Pompe disease. At age 10, he started ERT at 20 mg/kg every other week. Respiratory and motor functions were evaluated at each infusion, and by skeletal muscle computed tomography (CT) and cardiac echography every 4 months. He gained the ability to climb stairs without a rail and % vital capacity improved just 1.5 months after starting ERT. Grip power, manual muscle testing (MMT) and the timed and 6-min walking distance tests (6MWT) improved promptly, paralleling improvements in clinical symptoms. However, this steady improvement stopped around 8 months, with deterioration to the initial level by about 24 months. Antibody against recombinant human alpha-glucosidase was very low at 15 months; therefore, the lack of treatment response did not completely correspond to antibody production. On the other hand, cardiac wall thickening worsened after 4 months, then improved to better than baseline after 8 months, and this improvement was well maintained. Among our set parameters, the timed test results corresponded better to his changing clinical course than did grip power, MMT or 6-min walking test results.     

Cessation and resuming of alglucosidase alfa in Pompe disease: a retrospective analysis

Enzyme replacement therapy (ERT) with recombinant human alglucosidase alfa (rhGAA) in late-onset Pompe disease is moderately effective. Little is known about the clinical course after treatment termination and the resumption of ERT. In Switzerland, rhGAA therapy for Pompe disease was temporarily withdrawn after the federal court judged that the treatment costs were greatly out of proportion compared to the benefits. Re-treatment was initiated after the therapy was finally licensed. We retrospectively analysed seven Pompe patients, who underwent cessation and resumption of ERT (median age 43 years). The delay from first symptoms to final diagnosis ranged from 4 to 20 years. The demographics, clinical characteristics, assessments with the 6-min walking test (6-MWT), the predicted forced vital capacity (FVC) and muscle strength were analysed. Before initiation of ERT, all patients suffered from proximal muscle weakness of the lower limbs; one was wheelchair-bound and two patients received night-time non-invasive ventilation. Initial treatment stabilised respiratory function in most patients and improved their walking performance. After treatment cessation, upright FVC declined in most and the 6-MWT declined in all patients. Two patients needed additional non-invasive ventilatory support. Twelve months after resuming ERT, the respiratory and walking capacity improved again in most patients. However, aside for one patient, none of the patients reached the same level of respiratory function or distance walked in 6 min, as at the time of ERT withdrawal. We conclude that cessation of ERT in Pompe disease causes a decline in clinical function and should be avoided. Resuming treatment only partially recovers respiratory function and walking capacity.     

New approaches for the treatment of metabolic myopathies

Metabolic myopathies are inborn errors of intermediate muscle metabolism, presenting either by exercise intolerance, or by progressive muscle weakness. Growing knowledge concerning the pathophysiology of these rare disorders, and the development of new technologies, opens new avenues for the treatment of this group of myopathies. Recent studies showed improvement in exercise capacity after regular aerobic exercise training in patients with McArdle's disease and mitochondrial myopathies. In late-onset Pompe disease enzyme replacement therapy trials with recombinant acid alpha-glucosidase (Myozyme) are currently in progress, the first trials conducted in childhood onset Pompe disease having previously shown a clear improvement in life expectancy and cardiac function. The demonstration that fibrates can induce correction of carnitine palmitoyl-transferase II deficiency in patients cells, lead to the development of an open-labelled therapeutic trial with bezafibrate in patients with CPTII deficiency, which is actually ongoing.     

Pompe disease in a Brazilian series: clinical and molecular analyses with identification of nine new mutations

Pompe disease (glycogen storage disease type II or acid maltase deficiency) is an inherited autosomal recessive deficiency of acid α-glucosidase (GAA), with predominant manifestations of skeletal muscle weakness. A broad range of studies have been published focusing on Pompe patients from different countries, but none from Brazil. We investigated 41 patients with either infantile-onset (21 cases) or late-onset (20 cases) disease by muscle pathology, enzyme activity and GAA gene mutation screening. Molecular analyses identified 71 mutant alleles from the probands, nine of which are novel (five missense mutations c.136T > G, c.650C > T, c.1456G > C, c.1834C > T, and c.1905C > A, a splice-site mutation c.1195-2A > G, two deletions c.18_25del and c.2185delC, and one nonsense mutation c.643G > T). Interestingly, the c.1905C > A variant was detected in four unrelated patients and may represent a common Brazilian Pompe mutation. The c.2560C > T severe mutation was frequent in our population suggesting a high prevalence in Brazil. Also, eight out of the 21 infantile-onset patients have two truncating mutations predicted to abrogate protein expression. Of the ten late-onset patients who do not carry the common late-onset intronic mutation c.-32-13T > G, five (from three separate families) carry the recently described intronic mutation, c.-32-3C > A, and one sibpair carries the novel missense mutation c.1781G > C in combination with known severe mutation c.1941C > G. The association of these variants (c.1781G > C and c.-32-3C > A) with late-onset disease suggests that they allow for some residual activity in these patients. Our findings help to characterize Pompe disease in Brazil and support the need for additional studies to define the wide clinical and pathological spectrum observed in this disease.     

Pompe disease,the must‐not‐miss diagnosis: A report of 3 patients

Introduction: Pompe disease is a progressive and debilitating neuromuscular disorder that presents with a heterogeneous array of signs and symptoms including proximal muscle weakness, respiratory insufficiency, and/or elevated creatine kinase levels. It mimics other neuromuscular disorders, making its diagnosis challenging and often significantly delayed, thereby increasing morbidity and early mortality of the disease. Methods: Three Pompe disease patients are discussed to highlight the challenging path to diagnosis and the common cluster of symptoms that could lead to timely and accurate diagnosis. Results: After significant delays in diagnosis, Pompe disease was diagnosed on the basis of the pattern of proximal weakness. Conclusions: Suspicion and recognition of the characteristic symptoms of Pompe disease may improve both the timing and accuracy of the diagnosis, which will improve clinical outcomes and minimize disease progression. Muscle Nerve, 2013     

Presymptomatic late-onset Pompe disease identified by the dried blood spot test

Pompe disease or glycogen storage disease type II is an autosomal recessive disorder caused by mutations in the GAA gene leading to muscle weakness. Here we describe a 15 years old presymptomatic patient with normal muscle MRI, unspecific muscle biopsy findings but abnormal acid maltase activity in a dried blood spot test. Sequencing the GAA-gene identified a heterozygous novel splice-site and a heterozygous previously described mutation. The case highlights the variability in clinical phenotype and difficulties to diagnose late-onset Pompe disease. Dried Blood Spot (DBS) might be the most sensitive tool to pick up mildly symptomatic patients.     

Atrio-ventricular block requiring pacemaker in patients with late onset Pompe disease

Enzyme replacement therapy consistently improves cardiac function in infantile and juvenile onset patients with Pompe disease and cardiomyopathy, but is apparently not effective in preventing rhythm disorders, an emerging cardiac phenotype in long term survivors. In patients with late onset Pompe disease cardiomyopathy is an exceptional finding while heart rhythm disorders seem to be more frequent. We retrospectively identified, among a cohort of 131 French late onset Pompe disease patients, four patients with severe atrio-ventricular blocks requiring pacemaker implantation. These patients had no other risk factors for cardiovascular diseases or cardiomyopathy. In one patient the atrioventricular block was discovered while still asymptomatic. Cardiac conduction defects are relatively rare in late onset Pompe disease and may occur even in absence of cardiac symptoms or EKG abnormalities. However because of the possible life-threatening complications associated with these conduction defects, cardiac follow-up in patients with late onset Pompe disease should include periodical Holter-EKG monitoring.     

Consensus treatment recommendations for late-onset Pompe disease

Introduction: Pompe disease is a rare, autosomal recessive disorder caused by deficiency of the glycogen‐degrading lysosomal enzyme acid alpha‐glucosidase. Late‐onset Pompe disease is a multisystem condition, with a heterogeneous clinical presentation that mimics other neuromuscular disorders. Methods: Objective is to propose consensus‐based treatment and management recommendations for late‐onset Pompe disease. Methods: A systematic review of the literature by a panel of specialists with expertise in Pompe disease was undertaken. Conclusions: A multidisciplinary team should be involved to properly treat the pulmonary, neuromuscular, orthopedic, and gastrointestinal elements of late‐onset Pompe disease. Presymptomatic patients with subtle objective signs of Pompe disease (and patients symptomatic at diagnosis) should begin treatment with enzyme replacement therapy (ERT) immediately; presymptomatic patients without symptoms or signs should be observed without use of ERT. After 1 year of ERT, patients' condition should be reevaluated to determine whether ERT should be continued. Muscle Nerve, 2012     

Mutations in the acid alpha-glucosidase gene (M. Pompe) in a patient with an unusual phenotype

Glycogenosis type II (Pompe disease) is a lysosomal storage disease caused by deficiency of acid alpha-glucosidase (acid maltase). The disease is autosomal recessive inherited and is clinically and genetically heterogenous. The authors describe a 30-year-old woman affected by late-onset Pompe disease with vascular affection resembling atherosclerotic angiopathy of the elderly. Genetic analysis revealed two novel mutations (Ala237Val and Gly293Arg) in the acid alpha-glucosidase gene in this patient.     

Course of disability and respiratory function in untreated late-onset Pompe disease

Fifty-two untreated patients with late-onset Pompe disease completed questionnaires about their clinical condition and level of handicap at baseline and at 1-year (n = 41) and 2-year follow-ups (n = 40). During this period, declines in functional activities, respiratory function, handicap, and survival were recorded on a group level. This study illustrates the progressiveness of late-onset Pompe disease and indicates the need for close clinical follow-up of both children and adults with this disorder.     

Temporal neuropathologic and behavioral phenotype of 6neo/6neo Pompe disease mice

Pompe disease (glycogen storage disease II) is caused by mutations in the acid alpha-glucosidase gene. The most common form is rapidly progressive with glycogen storage, particularly in muscle, which leads to profound weakness, cardiac failure, and death by the age of 2 years. Although usually considered a muscle disease, glycogen storage also occurs in the CNS. We evaluated the progression of neuropathologic and behavioral abnormalities in a Pompe disease mouse model (6neo/6neo) that displays many features of the human disease. Homozygous mutant mice store excess glycogen within large neurons of hindbrain, spinal cord, and sensory ganglia by the age of 1 month; accumulations then spread progressively within many CNS cell types. "Silver degeneration" and Fluoro-Jade C stains revealed severe degeneration in axon terminals of primary sensory neurons at 3 to 9 months. These abnormalities were accompanied by progressive behavioral impairment on rotorod, wire hanging, and foot fault tests. The extensive neuropathologic alterations in this model suggest that therapy of skeletal and cardiac muscle disorders by systemic enzyme replacement therapy may not be sufficient to reverse functional deficits due to CNS glycogen storage, particularly early-onset, rapidly progressive disease. A better understanding of the basis for clinical manifestations is needed to correlate CNS pathology with Pompe disease manifestations.     

Central drive and ventilatory failure in late-onset Pompe disease: At the gates of a new phenotype

Subjects with late-onset Pompe disease (LOPD) typically present as slowly progressive proximal muscle weakness. Respiratory muscle weakness and diaphragmatic paralysis are common features, and may be the initial manifestation of the disease. There is often a poor correlation between the severity of limb and respiratory muscle weakness. Early clinical observations about disproportionate hypercapnia to the respiratory muscular weakness in late-onset Pompe disease were recognized and will be discussed with special reference to blunted respiratory drive, and the connections between early clinical observations, respiratory functional studies and anatomical findings. According to new evidence about blunted respiratory drive in Pompe disease, it is necessary to rethink what is meant by “asymptomatic Pompe disease” and propose a new phenotype with its therapeutic implications. The conceptual model of the mechanisms leading to respiratory failure in this disease could be considered according to these new findings. It may broaden the diagnostic spectrum of the adult forms and warrants a closer interaction between neurologists and pulmonologists. The recognition of this new phenotype of predominant central alveolar hypoventilation in Pompe disease will improve the understanding of the underlying mechanisms of ventilatory failure and could lead to improved future therapeutic strategies.     

Targeted gene panel screening is an effective tool to identify undiagnosed late onset Pompe disease

Mutations in the GAA gene may cause a late onset Pompe disease presenting with proximal weakness without the characteristic muscle pathology, and therefore a test for GAA activity is the first tier analysis in all undiagnosed patients with hyperCKemia and/or limb-girdle muscular weakness. By using MotorPlex, a targeted gene panel for next generation sequencing, we analyzed GAA and other muscle disease-genes in a large cohort of undiagnosed patients with suspected inherited skeletal muscle disorders (n = 504). In this cohort, 275 patients presented with limb-girdle phenotype and/or an isolated hyperCKemia. Mutational analysis identified GAA mutations in ten patients. Further seven affected relatives were identified by segregation studies. All the patients carried the common GAA mutation c.-32-13T >G and a second, previously reported mutation. In the subcohort of 275 patients with proximal muscle weakness and/or hyperCKemia, we identified late-onset Pompe disease in 10 patients. The clinical overlap between Pompe disease and LGMDs or other skeletal muscle disorders suggests that GAA and the genes causing a metabolic myopathy should be analyzed in all the gene panels used for testing neuromuscular patients. However, enzymatic tests are essential for the interpretation and validation of genetic results.     

Clinical guidelines for late-onset Pompe disease

Before 2006, Pompe disease or glycogenosis storage disease type II was an incurable disease whose treatment was merely palliative. The development of a recombinant human alpha-glucosidase enzymatic replacement therapy has become the first specific treatment for this illness. The aim of this guide is to serve as reference for the management of the late-onset Pompe disease, the type of Pompe disease that develops after one year of age. In the guide a group of Spanish experts make specific recommendations about diagnosis, follow-up and treatment of this illness. With regard to diagnosis, the dried blood spots method is essential as the first step for the diagnosis of Pompe disease. The confirmation of the diagnosis of Pompe disease must be made by means of an study of enzymatic activity in isolated lymphocytes or a mutation analysis of the alpha-glucosidase gene. With regard to treatment with enzymatic replacement therapy, the experts say that is effective improving or stabilizating the motor function and the respiratory function and it must be introduced when the first symptoms attributable to Pompe disease appear.