Ni-Chung Lee

Newborn screening for Fabry disease in Taiwan reveals a high incidence of the later-onset GLA mutation c.936+919G>A (IVS4+919G>A).

Fabry disease (α‐galactosidase A (α‐Gal A, GLA) deficiency) is a panethnic inborn error of glycosphingolipid metabolism. Because optimal therapeutic outcomes depend on early intervention, a pilot program was designed to assess newborn screening for this disease in 171,977 consecutive Taiwanese newborns by measuring their dry blood spot (DBS) α‐Gal A activities and β‐galactosidase/α‐Gal A ratios. Of the 90,288 male screenees, 638 (0.7%) had DBS α‐Gal A activity <30% of normal mean and/or activity ratios >10. A second DBS assay reduced these to 91 (0.1%). Of these, 11 (including twins) had <5% (Group‐A), 64 had 5–30% (Group‐B), and 11 had >30% (Group‐C) of mean normal leukocyte α‐Gal A activity. All 11 Group‐A, 61 Group‐B, and 1 Group‐C males had GLA gene mutations. Surprisingly, 86% had the later‐onset cryptic splice mutation c.936+919G>A (also called IVS4+919G>A). In contrast, screening 81,689 females detected two heterozygotes. The novel mutations were expressed in vitro, predicting their classical or later‐onset phenotypes. Newborn screening identified a surprisingly high frequency of Taiwanese males with Fabry disease (∼1 in 1,250), 86% having the IVS4+919G>A mutation previously found in later‐onset cardiac phenotype patients. Further studies of the IVS4 later‐onset phenotype will determine its natural history and optimal timing for therapeutic intervention. Hum Mutat 30:1–9, 2009.

Early Detection of Pompe Disease by Newborn Screening Is Feasible: Results From the Taiwan Screening Program

OBJECTIVE. Pompe disease is an autosomal recessive lysosomal storage disorder that is caused by deficient acid α-glucosidase activity and results in progressive, debilitating, and often life-threatening symptoms involving the musculoskeletal, respiratory, and cardiac systems. Recently, enzyme replacement therapy with alglucosidase α has become possible, but the best outcomes in motor function have been achieved when treatment was initiated early. The aim of this study was to test the feasibility of screening newborns in Taiwan for Pompe disease by using a fluorometric enzymatic assay to determine acid α-glucosidase activity in dried blood spots. METHODS. We conducted a large-scale newborn screening pilot program between October 2005 and March 2007. The screening involved measuring acid α-glucosidase activity in dried blood spots of ∼45% of newborns in Taiwan. The unscreened population was monitored as a control. RESULTS. Of the 132 538 newborns screened, 1093 (0.82%) repeat dried blood-spot samples were requested and retested, and 121 (0.091%) newborns were recalled for additional evaluation. Pompe disease was confirmed in 4 newborns. This number was similar to the number of infants who received a diagnosis of Pompe disease in the control group (n = 3); however, newborn screening resulted in an earlier diagnosis of Pompe disease: patients were <1 month old compared with 3 to 6 months old in the control group. CONCLUSIONS. To our knowledge, this is the first large-scale study to show that newborn screening for Pompe disease is feasible. Newborn screening allows for earlier diagnosis of Pompe disease and, thus, for assessment of the value of an earlier start of treatment.

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.

Mitochondrial DNA polymerase γ mutations: an ever expanding molecular and clinical spectrum

Mutations in the POLG gene have emerged as one of the most common causes of inherited mitochondrial diseases in children and adults. This study sequenced the exons and flanking intronic regions of the POLG gene from 2697 unrelated patients with clinical presentations suggestive of POLG deficiency. Informative mutations have been identified in 136 unrelated individuals (5%), including 92 patients with two recessive pathogenic alleles and three patients harbouring a dominant mutation. Twenty-four novel recessive mutations and a novel possible dominant mutation, p.Y951N, were identified. All missense mutations occurred at evolutionarily conserved amino acids within functionally important regions identified by molecular modelling analyses. Oligonucleotide array comparative genomic hybridisation analyses performed on DNA samples from 81 patients with one mutant POLG allele identified a large intragenic deletion in only one patient, suggesting that large deletions in POLG are rare. The 92 patients with two mutant alleles exhibited a broad spectrum of disease. Almost all patients in all age groups had some degree of neuropathy. Seizures, hepatopathy, and lactic acidaemia were predominant in younger patients. By comparison, patients who developed symptoms in adulthood had a higher percentage of myopathy, sensory ataxia, and chronic progressive external ophthalmoplegia (CPEO)/ptosis. In conclusion, POLG mutations account for a broad clinical spectrum of mitochondrial disorders. Sequence analysis of the POLG gene should be considered as a part of routine screening for mitochondrial disorders, even in the absence of apparent mitochondrial DNA abnormalities.

Gene therapy for aromatic L-amino acid decarboxylase deficiency.

Gene therapy can restore some motor function in patients with aromatic l-amino acid decarboxylase deficiency. Gene Therapy for AADC Deficiency Patients with aromatic l-amino acid decarboxylase (AADC) deficiency cannot produce the neurotransmitter dopamine from its precursor l-DOPA in the brain. Dopamine is a crucial molecule required for normal motor function. There are few treatment options for AADC deficiency, and most patients afflicted with this rare disease die in childhood. In a phase 1 clinical trial, Hwu and colleagues use an adeno-associated virus (AAV) type 2 vector to deliver the AADC gene into a brain area called the putamen in four children with AADC deficiency. Although at first the patients exhibited dyskinesias (abnormal muscle movements), these resolved after a few months and the patients showed improved motor function. One patient after 16 months was able to stand, and the other three patients were able to sit upright with support. Several other symptoms improved as well including mood and oculogyric crises. There were a number of translational challenges for this gene therapy clinical trial. For example, the authors had to work out how to deliver the viral vector carrying the therapeutic gene directly into the putamen, and even then only a small part of the putamen became transduced with the AADC gene. Also, because the patients’ brains had not been able to make dopamine, it was not clear how the neurons would respond once dopamine started to be produced. Despite these challenges, this first-in-human gene therapy clinical trial suggests that targeting localized areas in the brain with a therapeutic gene delivered by an AAV vector could help ameliorate the symptoms of AADC deficiency and may also be useful for treating other diseases caused by lack of a crucial enzyme in brain tissue. Aromatic l-amino acid decarboxylase (AADC) is required for the synthesis of the neurotransmitters dopamine and serotonin. Children with defects in the AADC gene show compromised development, particularly in motor function. Drug therapy has only marginal effects on some of the symptoms and does not change early childhood mortality. Here, we performed adeno-associated viral vector–mediated gene transfer of the human AADC gene bilaterally into the putamen of four patients 4 to 6 years of age. All of the patients showed improvements in motor performance: One patient was able to stand 16 months after gene transfer, and the other three patients achieved supported sitting 6 to 15 months after gene transfer. Choreic dyskinesia was observed in all patients, but this resolved after several months. Positron emission tomography revealed increased uptake by the putamen of 6-[18F]fluorodopa, a tracer for AADC. Cerebrospinal fluid analysis showed increased dopamine and serotonin levels after gene transfer. Thus, gene therapy targeting primary AADC deficiency is well tolerated and leads to improved motor function.

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.

Genetic heterozygosity and pseudodeficiency in the Pompe disease newborn screening pilot program

Pompe disease is an autosomal recessive lysosomal storage disorder (LSD) caused by deficiency of lysosomal acid alpha-glucosidase (GAA) activity. This is the first LSD in which newborn screening has been shown to improve clinical outcomes. Newborn screening also identified multiple rare gene variants in this population. Among 132,538 newborns screened, 107 babies (1 in 1239) who had low dried blood spot GAA activity were genotyped. Sixty-nine (64.5%) babies had a total of 54 mutations and 35 novel predictably pathogenic mutations; 36 babies (33.6%) who had no mutation were homozygous for the c.[1726A; 2065A] pseudodeficiency allele. Because 81% of the chromosomes (14% in the controls) were in haplotype *03, we found a link between the pseudodeficiency allele and other mutated alleles. The newborns with Pompe disease detected by screening had lymphocyte GAA activities 0.45 to 1.65 nmol/mg/h (normal 66.7+/-33.8), while only 2 of the 100 false-positive cases had GAA activity less than 2.00 nmol/mg/h (or 3% of the normal mean). Therefore, newborn screening for Pompe disease could be successfully conducted by including genotyping and lymphocyte GAA assay, even in a population with mutation heterozygosity and pseudodeficiency.

Pompe Disease: Early Diagnosis and Early Treatment Make a Difference

Pompe disease (glycogen storage disease type II or acid maltase deficiency) is a lysosomal disorder in which acid α-glucosidase (GAA) deficiencies lead to intralysosomal accumulation of glycogen in all tissues; most notably in skeletal muscles. Both the patients age at the onset of Pompe disease symptoms and the rate of deterioration caused by the disease can vary considerably. In classical infant-onset Pompe disease (IOPD), symptoms start very early in life, and death occurs soon afterward if the disease remains untreated. In later-onset Pompe disease, symptoms are slower to appear, and patients often progress to wheelchair confinement and eventual respiratory failure. A diagnosis can be made by screening for GAA in dried blood samples, followed either by GAA assessment in lymphocytes or in fibroblasts or by the genetic analysis of mutations. Treatment by enzyme replacement therapy (ERT) with alglucosidase alfa was approved for human use in 2006. In classical IOPD, treatment significantly lengthens survival and improves motor development and cardiac function. The sooner ERT begins, the better are the results. Newborn screening aims to take advantage of different technologies for diagnosing and treating newborns early on and it yields better outcomes. However, newborns diagnosed early and other long-term survivors may encounter fresh problems, making up a new phenotype of IOPD patients. Further modifications of the treatment, such as a decrease in immune responses to ERT, a higher dosage, a better uptake formulation, and gene therapy delivered locally or systemically are being explored.

Reversal of Cardiac Dysfunction after Enzyme Replacement in Patients with Infantile-Onset Pompe Disease

OBJECTIVE To compare the effects of enzyme replacement therapy (ERT) on cardiac performance in symptomatic and symptom-free infants with Pompe disease. STUDY DESIGN Patients diagnosed between 1983 and 2008 were identified. Before the initiation of ERT, systolic dysfunction appeared only in patients > or = 5 months; thus we used this cut-point in age to divide clinically symptomatic patients into early and late treatment groups (Clin-E and Clin-L). Newborn screening (NBS) identified symptom-free patients. RESULTS Among a total of 40 patients, 14 received ERT: 5 in the Clin-L, 4 in the Clin-E, and 5 in the NBS groups. All patients showed cardiomegaly, hypertrophic myocardium, and elevated B-type natriuretic peptide (measured in the Clin-E and NBS groups). ERT improved the survival and outcomes. Regressed myocardial hypertrophy and lowered B-type natriuretic peptide level occurred after 1 to 6 months of ERT. Nonetheless, there were 2 deaths and 2 survivors requiring ventilator support in the Clin-L group. Despite the regressed QRS voltage and shortened QT dispersion, life-threatening arrhythmias were still observed in 3, but none in the NBS group. CONCLUSION ERT may restore the cardiac function in both symptomatic and symptom-free patients, but the beneficial effect may be unpredictable if given after the age of 5 months.

Brain Development in Infantile-Onset Pompe Disease Treated by Enzyme Replacement Therapy

The primary manifestations of Pompe disease are muscle weakness and cardiomyopathy. Although accumulation of glycogen has also been seen in the nervous system in patients, the significance of brain involvement in infantile-onset Pompe disease is not clear. In this study, brain development in five cases of infantile-onset Pompe disease, whose survivals have been prolonged by enzyme replacement therapy (ERT), were studied by brain magnetic resonance imaging (MRI) and magnetic resonance spectroscopy (MRS). The results revealed delay in myelination milestones in all patients at a median age of 6 mo upon the initiation of treatment. After ERT, four of the five cases showed good progression in myelination, even though mild dilatation of the ventricles was still observed. In the case with no response to ERT in the muscles, however, brain myelination was slow and follow-up MRI and MRS studies suggested both neuron and myelination loss. Therefore, myelination defects are common in infantile-onset Pompe disease. Improvement in brain myelination could be seen in those who survive by effective treatment, although we do not know whether ERT does have a direct therapeutic effect on the brain.