Pathology of skeletal muscle cells in adult-onset glycogenosis type II (Pompe disease): ultrastructural study

Ultrastructural analysis of the skeletal muscle in adult-onset Pompe disease revealed lysosomal and cytoplasmic glycogen storage, autophagic vacuoles and abnormal mitochondria. Significant glycogen accumulation within lysosomes causes their rupture and release of glycogen into the cytoplasm. Excess cytoplasmic glycogen could lead to damage of the structure of muscle cells including myofibrils. In consequence, parts of the sarcoplasm and damaged organelles were sequestered within membrane-limited vacuoles. We suppose that massive accumulation of autophagic vacuoles results from the inability of destroyed lysosomes to fuse with vacuoles. Autophagic vacuoles may be a prominent feature of muscle cells in adult glycogenosis type II.     

Pompe Disease: From Basic Science to Therapy

Pompe disease is a rare and deadly muscle disorder. As a clinical entity, the disease has been known for over 75 years. While an optimist might be excited about the advances made during this time, a pessimist would note that we have yet to find a cure. However, both sides would agree that many findings in basic science—such as the Nobel prize-winning discoveries of glycogen metabolism, the lysosome, and autophagy—have become the foundation of our understanding of Pompe disease. The disease is a glycogen storage disorder, a lysosomal disorder, and an autophagic myopathy. In this review, we will discuss how these past discoveries have guided Pompe research and impacted recent therapeutic developments.     

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.     

High-density areas on muscle CT in childhood-onset Pompe disease are caused by excess calcium accumulation

We report two patients with childhood-onset Pompe disease showing striking changes with high-density areas on skeletal muscle CT, not seen in adult- or infantile-onset forms of this disease. While the anterior compartment of the thigh muscles was less affected in the adult-onset form, the rectus femoris and tibial muscles were preferentially involved from the early stage in the childhood-onset form of Pompe disease. The high-density areas became increasingly diffuse with disease progression, producing a marbled pattern and ultimately resulting in homogeneous high density and muscle atrophy. Muscle biopsy specimens from the high-density areas showed striking vacuolar changes with many dense globular bodies in lysosomes. High calcium signals were identified by X-ray microanalysis using energy-dispersive X-ray spectroscopy in these areas. Excess calcium accumulation in the vacuoles was also confirmed with the glyoxal-bis(2-hydroxyanil) (GBHA) staining. The high density on CT was slightly reduced together with clinical improvement after enzyme replacement therapy in patient 2. Our data demonstrate that in childhood-onset Pompe disease, high-density areas on skeletal muscle CT images are due to the accumulation of calcium in dense globular bodies formed by a chronic degenerative process affecting autophagic vacuoles.     

Prevalence of adult Pompe disease in patients with proximal myopathic syndrome and undiagnosed muscle biopsy

We examined patients with limb-girdle muscle weakness and/or hyper-CKaemia and undiagnosed muscle biopsy for late onset Pompe disease (LOPD). Patients with an inconclusive limb-girdle muscle weakness who presented at our neuromuscular centre between 2005 and 2015 with undiagnosed muscle biopsies were examined by dry blood spot testing (DBS) including determination of the enzyme activity of acid alpha-glucosidase (GAA). In the case of depressed enzyme activity, additional gene testing of the GAA gene was carried out. Of the 340 evaluated muscle biopsies, 69 patients fulfilled the inclusion criteria and were examined with DBS. Among those patients, 76% showed a limb-girdle muscle weakness and 14% showed a hyper-CKaemia. A diagnosis of LOPD could be established in the case of two patients (2.9%) with reduced GAA enzyme activity and proof of mutations in the GAA gene. One of the two patients presents in the muscle biopsy suggestive features of Pompe disease including vacuoles with positive acid phosphatase reaction. In summary, our results show that a muscle biopsy can be helpful in identifying LOPD patients, but vacuolation with glycogen storage can also be absent. An inconspicuous muscle biopsy does not rule out Pompe disease. Consequently, all patients with limb-girdle muscle weakness should be examined by DBS before conducting a muscle biopsy.     

Adult-onset glycogen storage disease type 2: clinico-pathological phenotype revisited

The need for clinical awareness and diagnostic precision of glycogen storage disease type 2 (GSD2) has increased, as enzyme replacement therapy has become available. So far, only small series have reported the muscle pathology of late-onset GSD2. We reassessed 43 muscle biopsies of 38 GSD2 patients. In all patients the diagnosis of GSD2 has been established by biochemistry and/or mutational analysis of the GAA gene. Additionally to the expected morphological features, ultrastructural analysis revealed a high incidence of autophagic vacuoles, lipofuscin debris, structural Z-line disorganization and histological neurogenic-like pattern that were not thoroughly appreciated, previously. Comparing age at onset and morphology, excessive vacuolar and autophagic myopathy and mitochondrial disorganization of virtually all fibres is common in infants. At juvenile onset, a more moderate vacuolization without significant differences in overall morphology is notable. At late-onset, the spectrum of vacuolar myopathy is more divergent, ranging from almost normal to severe. Here pronounced secondary alterations are observed that include lipofuscin debris, autophagic vacuoles with residual lysosomal bodies and granular inclusions, structural mitochondrial and Z-line texture alterations. Moreover, there is a high incidence of subtle neurogenic-like alteration in all subtypes. Nineteen patients were genetically tested; in 15 patients the common leaky splicing mutation c.-45T>G (or IVS1-13T>G) in intron1 of the GAA gene was found on at least one allele, facilitating genetic screening. In our patients, GAA genotype appears not to be associated with secondary alterations such as autophagic vacuoles, structural alterations or neurogenic-like changes. These findings may have implications for our understanding of the pathogenesis of GSD2 and for assessing therapeutic success of enzyme replacement therapy.     

糖原累积病的临床电生理、骨骼肌和肝脏病理及基因研究

目的探讨和总结糖原累积病(GSD)的临床病理和基因突变特点。方法回顾性分析18例GSD患者EMG、骨骼肌病理、肝脏病理及二代测序结果。结果GSD慢性起病、波动性,主要表现为四肢近端肌无力,累及膈肌可发生呼吸困难。EMG多为肌源性损害,偶可正常或神经源性损害。骨骼肌活检可见肌纤维胞浆内出现空泡(糖原流失)及嗜碱性颗粒物(糖原蓄积);PAS染色示空泡内异常糖原颗粒沉积。电镜示肌原纤维间糖原贮积伴溶酶体或髓样小体形成。4例患者行肝脏活检示肝细胞肿胀,呈植物细胞壁样镶嵌状排列;胞质内见红色粉尘样物,PAS强阳性证实为糖原。6例患者行二代测序,5例发现GAA杂合突变。7例患者病情迅速进展,5年内死亡;7例缓慢进展,存活5~9年;4例失访。结论(1)GSD早期仅有单纯肌无力症状或低血糖、EMG缺少特异性,多系统受累伴有呼吸困难、肝肿大等提示本病。(2)肌肉和肝脏病理出现大量PAS染色阳性的糖原颗粒对确诊GSD有重要作用。肌活检空泡肌纤维抗线粒体抗体增高提示GSD伴发线粒体代谢紊乱。Dysferlin蛋白免疫组化呈斑片状肌膜和肌质染色,提示钙介导的肌膜融合修复受损可引起继发性肌膜受损。(3)GAA复合杂合突变导致Pompe病(GSDⅡ型)。     

High-density CT of muscle and liver may allow early diagnosis of childhood-onset Pompe disease

Pompe disease is classified into infantile-, childhood- and adult-onset forms based on onset age and the degree of organ involvement. Differing from the infantile-onset form which is characterized by marked organ involvement, the childhood-onset form usually presents with muscle weakness and elevation of serum creatine kinase (CK), mimicking those of progressive muscular dystrophy. We report our successful early diagnosis and initiation of enzyme replacement therapy (ERT) in a young girl with childhood-onset Pompe disease before the development of skeletal muscle symptoms. She was referred to our hospital at the age of 2 years 4 months because of hyperCKemia detected incidentally. She was active and lacked developmental delay and muscle weakness; however, hepatomegaly was noted. The combination of high-density changes in the liver and skeletal muscle on computed tomography (CT) images was suggestive of glycogen storage disorder, especially childhood-onset Pompe disease. Low alpha-glucosidase (GAA) activity on dried blood spots facilitated the diagnostic process, and genetic analysis of GAA allowed a definitive diagnosis, without performing muscle biopsy. We promptly started ERT at the age of 2 years 6 months. After 1 year, she still had not developed any skeletal muscle symptoms, and serum CK level was almost normal. Since the efficacy of ERT is thought to depend on the extent of muscle damage at its commencement, we expect that ERT may have prevented the manifestation of skeletal muscle involvement in this patient.     

Dysfunction of endocytic and autophagic pathways in a lysosomal storage disease

OBJECTIVE: To understand the mechanisms of skeletal muscle destruction and resistance to enzyme replacement therapy in Pompe disease, a deficiency of lysosomal acid alpha-glucosidase (GAA), in which glycogen accumulates in lysosomes primarily in cardiac and skeletal muscles. METHODS: We have analyzed compartments of the lysosomal degradative pathway in GAA-deficient myoblasts and single type I and type II muscle fibers isolated from wild-type, untreated, and enzyme replacement therapy-treated GAA knock-out mice. RESULTS: Studies in myoblasts from GAA knock-out mice showed a dramatic expansion of vesicles of the endocytic/autophagic pathways, decreased vesicular movement in overcrowded cells, and an acidification defect in a subset of late endosomes/lysosomes. Analysis by confocal microscopy of isolated muscle fibers demonstrated that the consequences of the lysosomal glycogen accumulation are strikingly different in type I and II muscle fibers. Only type II fibers, which are the most resistant to therapy, contain large regions of autophagic buildup that span the entire length of the fibers. INTERPRETATION: The vastly increased autophagic buildup may be responsible for skeletal muscle damage and prevent efficient trafficking of replacement enzyme to lysosomes.     

Mitochondrial activity in Pompe's disease

Mitochondrial oxidative metabolism was examined in two infants with Pompe's disease. The clinical diagnosis was confirmed by the demonstration of intralysosomal glycogen accumulation and a deficiency of acid alpha-D-glucosidase in muscle biopsies. Light and electron microscopy studies demonstrated a normal number of mitochondria with normal ultrastructure. Spectrophotometric measurements revealed that the specific activities of citrate synthase and the partial reactions of electron transport were markedly elevated in the skeletal muscle homogenates prepared from both infants with Pompe's disease when calculated as micromoles per minute per gram wet weight of tissue. However, when respiratory chain enzyme activities were expressed relative to citrate synthase as a marker mitochondrial enzyme, a different pattern emerged, in which all Pompe muscle respiratory enzymes, except complex IV, were decreased relative to control subjects. These observations demonstrate that caution should be exercised when analyzing and interpreting data obtained from tissue homogenates in general and, in particular, in those prepared from tissues in which the wet weight of tissue may be altered, for example, by pathologic accumulation of carbohydrate or lipid.     

Pompe disease (glycogen storage disease type II): clinical features and enzyme replacement therapy

Pompe disease (glycogen storage disease type II, acid maltase deficiency) is a progressive metabolic myopathy caused by deficiency of the lysosomal enzyme acid alpha-glucosidase. This leads to an accumulation of glycogen in various tissues of the body, most notably in skeletal muscle. The disease has an autosomal recessive inheritance with a predicted frequency of 1 :40.000. Pompe disease is a continuous spectrum but for clinical practice different subtypes are recognized. The classic infantile form of the disease occurs in infants (shortly after birth) and is characterized by generalized hypotonia, failure to thrive, and cardiorespiratory failure. Patients usually die within the first year of life. The non-classic or late-onset form of the disease may occur at any age in childhood or adulthood. It presents predominantly as a slowly progressive proximal myopathy, with or without respiratory failure. Enzyme replacement therapy (ERT) is under study as treatment for the disease. The first results with recombinant human alpha-glucosidase are promising and a registered therapy seems near. Beneficial effects of ERT have been reported both in patients with the classic infantile form as well as in patients with the non-classic or late-onset form of the disease. The best therapeutic results are achieved when ERT is started early in the course of symptom development and before irreversible muscular damage has occurred. Detailed knowledge about the natural course of the disease becomes more and more essential to determine the indication and timing of treatment.     

Pompe disease: a review of the current diagnosis and treatment recommendations in the era of enzyme replacement therapy

Pompe disease, or glycogen storage disease type II, is a rare autosomal recessive disorder caused by mutations in the gene that encodes for alpha-glucosidase. Presentation in infancy is associated with respiratory failure, cardiomyopathy, and severe muscle weakness. Juvenile- or adult-onset cases typically present with proximal muscle weakness and are associated with respiratory insufficiency or exertional dyspnea. Treatment, until recently, was focused on supportive measures, and infants diagnosed with Pompe disease usually died within the first year of life. The recent development of recombinant alpha-glucosidase has dramatically improved the life expectancy and quality of life of infantile-onset disease with improvements in respiratory and motor function observed in juvenile- or adult-onset cases. This review focuses on the presentation, pathogenesis, diagnosis, and treatment recommendations for Pompe disease in this new era of enzyme replacement therapy.     

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.     

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.     

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     

Both type 1 and type 2a muscle fibers can respond to enzyme therapy in Pompe disease

Muscle weakness is the main symptom of Pompe disease, a lysosomal storage disorder for which major clinical benefits of enzyme replacement therapy (ERT) have been documented recently. Restoration of skeletal muscle function is a challenging goal. Type 2 muscle fibers of mice with Pompe disease have proven resistant to therapy. To investigate the response in humans, we studied muscle biopsies of a severely affected infant before and after 17 months of therapy. Type 1 and 2a fibers were marked with antibodies, and lysosome-associated membrane protein-1 (Lamp1) was used as the lysosomal membrane marker. Quantitative measurements showed a 2.5-3-fold increase of fiber cross-sectional area of both fiber types during therapy and normalization of the Lamp1 signal in approximately 95% of type 1 and approximately 75% of type 2a fibers. The response of both type 1 and 2a muscle fibers in the patient studied herein corroborates the beneficial effects of enzyme therapy seen in patients with Pompe disease.     

Lysosomal glycogen storage disease with normal acid maltase (Danon) without apparent cardiomyopathy and mental retardation]

A 29-year-old male who had a past history of mild ECG abnormality of arrhythmia at the age of 14 years, was referred to our hospital because of elevated serum creatine kinase (CK) level. He had never been aware of muscular weakness nor cardiac symptoms. Neurological examination revealed normal muscle strength of all extremities except marked back muscle weakness. He had normal intelligence. On laboratory examination, serum AST, ALT, LDH, aldolase, CK and myoglobin levels were elevated. Both lactate and pyruvate levels were normally responded after an ischemic exercises test. Acid maltase activity was normal in white blood cells. A muscle biopsy obtained from rectus femoris muscle revealed vacuolar myopathy with mildly increased PAS positive material. On electron microscopy, there were autophagic vacuoles scavenging glycogen particles and cytoplasmic debris, and sarcolemmal indentation, compatible with the findings of lysosomal glycogen storage disease with normal acid maltase. This patient had unusual clinical features of absent mental retardation and no apparent cardiomyopathy. Accordingly, mental retardation is probably not necessary to see later onset of cardiac muscle involvement.     

A case of Pompe disease treated with acid alpha-glucosidase

Pompe disease (type II glycogenosis--GSD II) is a progressive metabolic myopathy caused by lysosomal storage of glycogen due to deficiency of acid alpha-glucosidase. We present the case of a 32-year-old patient with Pompe disease diagnosed 14 years ago in whom enzyme replacement therapy with recombinant human acid alpha-glucosidase (rhGAA) (20 mg/kg i.v. every 2 weeks) has been administered for about 18 months. Despite the fact that therapy was started in the advanced phase of Pompe disease we observed clinical improvement (increased muscle bulk and muscle strength as well as increased range of movements in the distal parts of limbs). In addition, we noticed less effort dyspnoea and use of a respirator during the day shortened to 2-3 hours (previously 5 hours). According to the observation of our patient, we suggest that enzyme replacement therapy causes clinical improvement.     

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.     

Safety and efficacy of recombinant acid alpha-glucosidase (rhGAA) in patients with classical infantile Pompe disease: results of a phase II clinical trial

Pompe disease is an autosomal recessive muscle-wasting disorder caused by the deficiency of the lysosomal enzyme acid alpha-glucosidase. Due to virtual absence of acid alpha-glucosidase, patients with classical infantile Pompe disease develop progressive cardiomyopathy, skeletal muscle weakness and respiratory insufficiency leading to death in early infancy. We report on the results of a phase II clinical trial including two patients with classical infantile Pompe disease receiving enzyme replacement therapy over a period of 48 weeks by weekly infusions. Recombinant acid alpha-glucosidase was derived from the milk of transgenic rabbits. Safety was evaluated by recording adverse events while clinical efficacy was evaluated by ventilator-free survival, left ventricular mass index, motor development as well as histologic and biochemical analysis of muscle biopsies. This therapy was in general well-tolerated. There was an overall improvement in left ventricular mass, cardiac function, skeletal muscle function and histological appearance of skeletal muscle.