The biallelic novel pathogenic variants in AGL gene in a chinese patient with glycogen storage disease type III.

BACKGROUND: Glycogen storage disease type III (GSD III) is a rare autosomal recessive glycogenolysis disorder due to AGL gene variants, characterized by hepatomegaly, fasting hypoglycemia, hyperlipidemia, elevated hepatic transaminases, growth retardation, progressive myopathy, and cardiomyopathy. However, it is not easy to make a definite diagnosis in early stage of disease only based on the clinical phenotype and imageology due to its clinical heterogeneity. CASE PRESENTATION: We report a two-year-old girl with GSD III from a nonconsanguineous Chinese family, who presented with hepatomegaly, fasting hypoglycemia, hyperlipidemia, elevated levels of transaminases. Accordingly, Sanger sequencing, whole­exome sequencing of family trios, and qRT-PCR was performed, which revealed that the patient carried the compound heterogeneous variants, a novel frameshift mutation c.597delG (p. Q199Hfs*2) and a novel large gene fragment deletion of the entire exon 13 in AGL gene. The deletion of AGL was inherited from the proband's father and the c.597delG variant was from the mother. CONCLUSIONS: In this study, we identified two novel variants c.597delG (p. Q199Hfs*2) and deletion of the entire exon 13 in AGL in a Chinese GSD III patient. We extend the mutation spectrum of AGL. We suggest that high-throughput sequencing technology can detect and screen pathogenic variant, which is a scientific basis about genetic counseling and clinical diagnosis.

Expected or unexpected clinical findings in liver glycogen storage disease type IX: distinct clinical and molecular variability.

OBJECTIVES: To reveal the different clinical presentations of liver glycogen storage disease type IX (GSD IX), which is a clinically and genetically heterogeneous type of glycogenosis. METHODS: The data from the electronic hospital records of 25 patients diagnosed with liver GSD IX was reviewed. Symptoms, clinical findings, and laboratory and molecular analysis were assessed. RESULTS: Of the patients, 10 had complaints of short stature in the initial presentation additionally other clinical findings. Elevated serum transaminases were found in 20 patients, and hepatomegaly was found in 22 patients. Interestingly, three patients were referred due to neurodevelopmental delay and hypotonia, while one was referred for only autism. One patient who presented with neurodevelopmental delay developed hepatomegaly and elevated transaminases during the disease later on. Three of the patients had low hemoglobin A1C and fructosamine values that were near the lowest reference range. Two patients had left ventricular hypertrophy. Three patients developed osteopenia during follow-up, and one patient had osteoporosis after puberty. The most common gene variant, PHKA2, was observed in 16 patients, 10 variants were novel and six variants were defined before. Six patients had variants in PHKG2, two variants were not defined before and four variants were defined before. PHKB variants were found in three patients. One patient had two novel splice site mutations in trans position. It was revealed that one novel homozygous variant and one defined homozygous variant were found in PHKB. CONCLUSIONS: This study revealed that GSD IX may present with only hypotonia and neurodevelopmental delay without liver involvement in the early infantile period. It should be emphasized that although liver GSDIX is thought of as a benign disease, it might present with multisystemic involvement and patients should be screened with echocardiography, bone mineral densitometry, and psychometric evaluation.

Usher syndrome type 2A complicated with glycogen storage disease type 3 due to paternal uniparental isodisomy of chromosome 1 in a sporadic patient.

BACKGROUND: The condition of uniparental disomy (UPD) occurs when an individual inherits two copies of a chromosome, or part of a chromosome, from one parent. Most cases of uniparental heterodisomy (UPhD) do not cause diseases, whereas cases of uniparental isodisomy (UPiD), while rare, may be pathogenic. Theoretically, UPiD may cause rare genetic diseases in a homozygous recessive manner. METHODS: A 4-year-old girl presented with congenital hearing loss, developmental delay, hepatomegaly, and other clinical features. She and her parents were genetically tested using trio whole exome sequencing (Trio-WES) and copy number variation sequencing (CNV-seq). In addition, we built a structural model to further examine the pathogenicity of the UPiD variants. RESULTS: Trio-WES identified a paternal UPiD in chromosome 1, and two homozygous pathogenic variants AGL c.4284T>G/p.Tyr1428* and USH2A c.6528T>A/p.Tyr2176* in the UPiD region. We further analyzed the pathogenicity of these two variations. The patient was diagnosed with Usher syndrome type 2A (USH2A) and glycogen storage disease type III (GSD3). CONCLUSIONS: Our study reports a rare case of a patient carrying two pathogenic variants of different genes caused by paternal UPiD, supporting the potential application of Trio-WES in detecting and facilitating the diagnosis of UPD.

Glycogen Debrancher Enzyme Deficiency Myopathy.

ABSTRACT: Glycogen storage disease type III is a rare inherited disease caused by decreased activity of glycogen debranching enzyme. It affects primarily the liver, cardiac muscle, and skeletal muscle. Pure involvement of the skeletal muscle with adult onset is extremely rare. We report on a patient with myopathy due to glycogen storage disease III, and describe the clinical features, and pathologic and genetic findings.

Genetic analysis and long-term treatment monitoring of 11 children with glycogen storage disease type IIIa.

Objectives To investigate the clinical and genetic characteristics of children with glycogen storage disease type IIIa (GSD IIIa) and to explore the muscle involvement and manifestations of GSD IIIa patients. Methods The clinical data of 11 patients with GSD IIIa diagnosed by genetic testing from 2003 to 2019 were retrospectively analyzed. Results Twenty variants of AGL gene were detected in 11 patients, eight of which were novel variants. Before treatment, the height was significantly backward. All patients had hepatomegaly. Abnormal biochemical indicators were mainly manifested as significantly increased serum liver and muscle enzymes, accompanied by hypertriglyceridemia, hypoglycemia, hyperlactacidemia, slightly elevated pyruvic acid, and metabolic acidosis. After treatment, the height and liver size of the patients were significantly improved. At the same time, alanine aminotransferase (ALT), aspartate aminotransferase (AST), triglyceride (TG), lactic acid and pyruvic acid in children were significantly decreased, while creatine kinase (CK) was significantly increased. During follow-up monitoring, six patients developed ventricular hypertrophy. Lactate dehydrogenase (LDH) (691.67 ± 545.27 vs. 362.20 ± 98.66), lactic acid (3.18 ± 3.05 vs. 1.10 ± 0.40), and pyruvic acid (64.30 ± 39.69 vs. 32.06 ± 4.61) were significantly increased in patients with ventricular hypertrophy compared with those without ventricular hypertrophy. Conclusions In clinical cases of upper respiratory tract infection or gastrointestinal symptoms accompanied by hypoglycemia, dyslipidemia, metabolites disorders, elevated serum liver, and muscle enzymes, the possibility of GSD IIIa should be vigilant. During treatment monitoring, if lactic acid, pyruvic acid, LDH, and CK rise, it indicates that the disease is not well controlled and there is the possibility of cardiac hypertrophy.

Uniparental isodisomy caused autosomal recessive diseases: NGS-based analysis allows the concurrent detection of homogenous variants and copy-neutral loss of heterozygosity.

BACKGROUND: Uniparental disomy (UPD) leading to autosomal recessive (AR) diseases is rare. We found an unusual homozygous state in two nonconsanguineous families, and only one parent in each family was a heterozygote. METHODS: Two patients with homozygosity for pathogenic variants were revealed by whole-exome sequencing (WES), further Sanger sequencing found that only one of the parents was a heterozygote. Initial genotype and copy number variations analysis from WES data of probands involving whole chromosomes 1 and 9 containing these two pathogenic variants were performed, genome-wide single-nucleotide polymorphism (SNP) array analysis was used to confirm these results. RESULTS: Whole-exome sequencing identified a homozygous c.3423_3424delTG mutation in AGL in patient 1 and a homozygous c.241-1G>C mutation in SURF1 in patient 2. Further parental testing found that only the two patients' healthy fathers were heterozygous. WES-based copy number and genotype analysis found a copy-neutral loss of heterozygosity (LOH) of whole chromosome 1 in patient 1 and of whole chromosomes 9 and 10 in patient 2. Further genome-wide SNP array and family haplotype analyses confirmed whole paternal uniparental isodisomy (UPiD) 1 in patient 1 and paternal UPiD 9 and maternal UPiD 10 in patient 2. Therefore, UPiD caused AR monogenic glycogen storage disease type-III (GSDIII) in patient 1 and Leigh syndrome in patient 2 through non-Mendelian inheritance of two mutant copies of a gene from each patient's father. CONCLUSION: Our report highlights that a single NGS-based analysis could allow us to find homozygous sequence variants and copy-neutral LOH in such cases. Our report also describes the first case of GSDIII caused by UPiD 1 and Leigh syndrome caused by UPiD 9.

First report of glycogen storage disease type 111a in a Nigerian child.

Glycogen storage disease (GSD) is a rare inborn error of metabolism with an incidence of 1/20,000-40,000 live births. Some of the presenting clinical features can mimic diseases commonly seen in the tropics and subtropics. We report a 14-month-old Nigerian child who presented at our institution with GSD Type 111a to alert physicians on the need to consider and recognise this rare disorder. The child presented with progressive abdominal swelling due to marked hepatomegaly. From the clinical history, the only clue to hypoglycaemia was that she eats very frequently. Her random blood sugar was normal; however, fasting blood sugar was low. The diagnosis was further entertained with laboratory results showing hypercholesterolaemia and uricaemia and confirmed by histology of biopsied liver tissue. GSD should be suspected in a child with unexplained hepatomegaly and investigated accordingly.

Neuromuscular Involvement in Glycogen Storage Disease Type III in Fifty Tunisian Patients: Phenotype and Natural History in Young Patients.

BACKGROUND: Our aim was to describe the natural history of neuromuscular involvement (NMI) in glycogen storage disease type III (GSDIII). METHODS: We conducted a longitudinal study of 50 Tunisian patients, 9.87 years old in average. RESULTS: NMI was diagnosed at an average age of 2.66 years and was clinically overt in 85% of patients. Patients with clinical features were older (p = 0.001). Complaints were dominated by exercise intolerance (80%), noticed at 5.33 years in average. Physical signs, observed at 6.75 years in average, were dominated by muscle weakness (62%). Functional impairment was observed in 64% of patients, without any link with age (p = 0.255). Among 33 patients, 7 improved. Creatine kinase (CK) and aspartate aminotransferase (AST) levels were higher with age.Electrophysiological abnormalities, diagnosed in average at 6.5 years, were more frequent after the first decade (p = 0.0005). Myogenic pattern was predominant (42%). Nerve conduction velocities were slow in two patients. Lower caloric intake was associated with more frequent clinical and electrophysiological features. Higher protein intake was related to fewer complaints and physical anomalies. CONCLUSION: Neuromuscular investigation is warranted even in asymptomatic patients, as early as the diagnosis of GSDIII is suspected. Muscle involvement can be disabling even in children. Favorable evolution is possible in case of optimal diet.

[Molecular and clinical characterization of Colombian patients suffering from type III glycogen storage disease].

INTRODUCTION: Type III glycogen storage disease (GSD III) is an autosomal recessive disorder in which a mutation in the AGL gene causes deficiency of the glycogen debranching enzyme. The disease is characterized by fasting hypoglycemia, hepatomegaly and progressive myopathy. Molecular analyses of AGL have indicated heterogeneity depending on ethnic groups. The full spectrum of AGL mutations in Colombia remains unclear. OBJECTIVE: To describe the clinical and molecular characteristics of ten Colombian patients diagnosed with GSD III. MATERIALS AND METHODS: We recruited ten Colombian children with a clinical and biochemical diagnosis of GSD III to undergo genetic testing. The full coding exons and the relevant exon-intron boundaries of the AGL underwent Sanger sequencing to identify mutation. RESULTS: All patients had the classic phenotype of the GSD III. Genetic analysis revealed a mutation p.Arg910X in two patients. One patient had the mutation p.Glu1072AspfsX36, and one case showed a compound heterozygosity with p.Arg910X and p.Glu1072AspfsX36 mutations. We also detected the deletion of AGL gene 3, 4, 5, and 6 exons in three patients. The in silico studies predicted that these defects are pathogenic. No mutations were detected in the amplified regions in three patients. CONCLUSION: We found mutations and deletions that explain the clinical phenotype of GSD III patients. This is the first report with a description of the clinical phenotype and the spectrum of AGL mutations in Colombian patients. This is important to provide appropriate prognosis and genetic counseling to the patient and their relatives.

Enfermedad por almacenamiento de glucógeno de tipo III en pacientes colombianos: caracterización clínica y molecular / Molecular and clinical characterization of Colombian patients suffering from type III glycogen storage disease

Resumen Introducción. La enfermedad por almacenamiento de glucógeno de tipo III es una alteración autosómica recesiva, en la cual las mutaciones del gen AGL causan una deficiencia en la enzima desramificadora de glucógeno. Se caracteriza por hipoglucemia, hepatomegalia y miopatías progresivas. El análisis molecular del gen AGL ha evidenciado mutaciones que difieren según la población estudiada. En la actualidad, no existen reportes que describan mutaciones en el AGL de pacientes colombianos con esta condición. Objetivo. Describir las características clínicas y moleculares de diez pacientes colombianos con enfermedad por almacenamiento del glucógeno de tipo III. Materiales y métodos. Se analizaron diez pacientes pediátricos colombianos con la enfermedad y se hizo su estudio genético mediante la secuenciación de las regiones que codifican y las intrónicas circundantes del gen AGL con el método de Sanger. Resultados. Todos los pacientes tenían el fenotipo clásico de la enfermedad. El estudio genético reveló la mutación p.Arg910X en dos pacientes. Uno presentó la mutación p.Glu1072AspfsX36 y otro resultó heterocigoto compuesto con las mutaciones p.Arg910X y p.Glu1072AspfsX36. Asimismo, en tres pacientes se detectó la deleción de los exones 4, 5 y 6 del gen AGL. Los estudios de simulación computacional predijeron que estos defectos eran patogénicos. En tres pacientes no se encontraron mutaciones en las regiones amplificadas. Conclusión. Se encontraron mutaciones y deleciones que explican el fenotipo clínico de los pacientes. Este es el primer reporte en el que se describe el fenotipo clínico y el espectro de mutaciones en el gen AGL de pacientes colombianos, lo cual es importante para ofrecer un apropiado pronóstico, y asesoría genética al paciente y a su familia.

Abstract Introduction: Type III glycogen storage disease (GSD III) is an autosomal recessive disorder in which a mutation in the AGL gene causes deficiency of the glycogen debranching enzyme. The disease is characterized by fasting hypoglycemia, hepatomegaly and progressive myopathy. Molecular analyses of AGL have indicated heterogeneity depending on ethnic groups. The full spectrum of AGL mutations in Colombia remains unclear. Objective: To describe the clinical and molecular characteristics of ten Colombian patients diagnosed with GSD III. Materials and methods: We recruited ten Colombian children with a clinical and biochemical diagnosis of GSD III to undergo genetic testing. The full coding exons and the relevant exon-intron boundaries of the AGL underwent Sanger sequencing to identify mutation. Results: All patients had the classic phenotype of the GSD III. Genetic analysis revealed a mutation p.Arg910X in two patients. One patient had the mutation p.Glu1072AspfsX36, and one case showed a compound heterozygosity with p.Arg910X and p.Glu1072AspfsX36 mutations. We also detected the deletion of AGL gene 3, 4, 5, and 6 exons in three patients. The in silico studies predicted that these defects are pathogenic. No mutations were detected in the amplified regions in three patients. Conclusion: We found mutations and deletions that explain the clinical phenotype of GSDIII patients. This is the first report with a description of the clinical phenotype and the spectrum of AGLmutations in Colombian patients. This is importantto provide appropriate prognosis and genetic counseling to the patient and their relatives.

Rescue of GSDIII Phenotype with Gene Transfer Requires Liver- and Muscle-Targeted GDE Expression.

Glycogen storage disease type III (GSDIII) is an autosomal recessive disorder caused by a deficiency of glycogen-debranching enzyme (GDE), which results in profound liver metabolism impairment and muscle weakness. To date, no cure is available for GSDIII and current treatments are mostly based on diet. Here we describe the development of a mouse model of GSDIII, which faithfully recapitulates the main features of the human condition. We used this model to develop and test novel therapies based on adeno-associated virus (AAV) vector-mediated gene transfer. First, we showed that overexpression of the lysosomal enzyme alpha-acid glucosidase (GAA) with an AAV vector led to a decrease in liver glycogen content but failed to reverse the disease phenotype. Using dual overlapping AAV vectors expressing the GDE transgene in muscle, we showed functional rescue with no impact on glucose metabolism. Liver expression of GDE, conversely, had a direct impact on blood glucose levels. These results provide proof of concept of correction of GSDIII with AAV vectors, and they indicate that restoration of the enzyme deficiency in muscle and liver is necessary to address both the metabolic and neuromuscular manifestations of the disease.

Late presentation of glycogen storage disease types Ia and III in children with short stature and hepatomegaly.

BACKGROUND: Glycogen storage diseases (GSDs) are a collection of disorders related to glycogen synthesis or degradation that classically present in infancy with hypoglycemia, failure to thrive and hepatomegaly; however, their phenotype can vary significantly. CASE PRESENTATION: We present the cases of two children, 5 years old and 3.5 years old, who were referred to endocrinology for short stature. They were ultimately found to have hepatomegaly, fasting hypoglycemia, mild elevation of transaminases and ketosis. Laboratory and genetic studies were consistent with double heterozygosity for GSDs Ia and III, with one novel mutation discovered in each patient. Nightly, both children were treated with cornstarch, which resulted in resolution of laboratory abnormalities and improvement in their growth velocity. These cases are unusual in that GSD was diagnosed relatively late in life in patients with no previous history of severe hypoglycemia. CONCLUSIONS: They highlight the importance of considering glycogen storage disease in a child presenting with short stature, as it is a treatable disease that can be diagnosed non-invasively with genetic testing.

Glycogen storage disease type III: diagnosis, genotype, management, clinical course and outcome.

Glycogen storage disease type III (GSDIII) is a rare disorder of glycogenolysis due to AGL gene mutations, causing glycogen debranching enzyme deficiency and storage of limited dextrin. Patients with GSDIIIa show involvement of liver and cardiac/skeletal muscle, whereas GSDIIIb patients display only liver symptoms and signs. The International Study on Glycogen Storage Disease (ISGSDIII) is a descriptive retrospective, international, multi-centre cohort study of diagnosis, genotype, management, clinical course and outcome of 175 patients from 147 families (86 % GSDIIIa; 14 % GSDIIIb), with follow-up into adulthood in 91 patients. In total 58 AGL mutations (non-missense mutations were overrepresented and 21 novel mutations were observed) were identified in 76 families. GSDIII patients first presented before the age of 1.5 years, hepatomegaly was the most common presenting clinical sign. Dietary management was very diverse and included frequent meals, uncooked cornstarch and continuous gastric drip feeding. Chronic complications involved the liver (hepatic cirrhosis, adenoma(s), and/or hepatocellular carcinoma in 11 %), heart (cardiac involvement and cardiomyopathy, in 58 % and 15 %, respectively, generally presenting in early childhood), and muscle (pain in 34 %). Type 2 diabetes mellitus was diagnosed in eight out of 91 adult patients (9 %). In adult patients no significant correlation was detected between (non-) missense AGL genotypes and hepatic, cardiac or muscular complications. This study demonstrates heterogeneity in a large cohort of ageing GSDIII patients. An international GSD patient registry is warranted to prospectively define the clinical course, heterogeneity and the effect of different dietary interventions in patients with GSDIII.

Spectrum of AGL mutations in Chinese patients with glycogen storage disease type III: identification of 31 novel mutations.

Glycogen storage disease type III (GSD III), a rare autosomal recessive disease characterized by hepatomegaly, fasting hypoglycemia, growth retardation, progressive myopathy and cardiomyopathy, is caused by deficiency of the glycogen debranching enzyme (AGL). Direct sequencing of human AGL cDNA and genomic DNA has enabled analysis of the underlying genetic defects responsible for GSD III. To date, the frequent mutations in different areas and populations have been described in Italy, Japan, Faroe Islands and Mediterranean area, whereas little has been performed in Chinese population. Here we report a sequencing-based mutation analysis in 43 Chinese patients with GSD III from 41 families. We identified 51 different mutations, including 15 splice-site (29.4%), 11 small deletions (21.6%), 12 nonsense (23.5%), 7 missense (13.7%), 5 duplication (9.8%) and 1 complex deletion/insertion (2.0%), 31 of which are novel mutations. The most common mutation is c.1735+1G>T (11.5%). The association of AGL missense and small in-frame deletion mutations with normal creatine kinase level was observed. Our study extends the spectrum of AGL mutations and suggests a genotype-phenotype correlation in GSD III.

Hepatocellular Adenomas and Carcinoma in Asymptomatic, Non-Cirrhotic Type III Glycogen Storage Disease.

Glycogen storage diseases (GSDs) are a group of inherited metabolic disorders characterized by accumulation of abnormal glycogen in muscle or liver or both. Specific hepatic complications include liver adenomas and hepatocellular carcinoma (HCC). Hepatocellular carcinomas described in GSD type I are often due to the degeneration of liver adenomas. Hepatocellular carcinoma in GSD type III, however, is rare and is thought to be associated with underlying cirrhosis.We present the case of a 63-year old male who was admitted for assessment of suitability for liver transplantation because of development of recurrent HCC in the presence of multiple liver adenomas. A diagnosis of GSD type III was made in this patient without underlying cirrhosis or metabolic disturbances resembling GSD. This case report is the first documentation of HCC development in an asymptomatic, non-cirrhotic patient with GSD type III. This raises the possibility that in GSD type III, the adenoma - carcinoma sequence can occur as it is also seen in GSD type I. Physicians taking care of GSD patients should be aware of this and some form of surveillance for cirrhosis and HCC should be considered. Also male patients with adenomas should have a thorough workup to reveal any underlying disease such as GSD.

Pathological characteristics of glycogen storage disease III in skeletal muscle.

We report a 25-year-old man with glycogenosis III who presented with a progressive 2 year history of fatigue, hand stiffness and cramping. The glycogenoses are a group of rare metabolic disorders which develop as a result of deficiencies in various enzymes involved in the metabolism of glycogen. Some, but not all, glycogenoses, may result in skeletal muscle pathology. Among those that result in vacuolar myopathic changes, glycogen storage disease III or debrancher enzyme deficiency, an autosomal recessive condition, is less commonly encountered than acid maltase (Type II) and myophosphorylase (Type V) deficiencies. Many patients with debrancher enzyme deficiency also have liver involvement. The neurological examination of our patient showed mild proximal limb weakness and decreased reflexes. He had elevated creatine kinase and aldolase levels. He also demonstrated some elevations in his liver function tests, suggesting possible liver involvement. A skeletal muscle biopsy demonstrated vacuolar myopathic changes (acid phosphatase negative) accompanied by focal endomysial fibrosis and chronic inflammation. An ultrastructural examination showed that his vacuoles were filled with glycogen material. An enzyme assay of skeletal muscle tissue showed a significant decrease in debrancher enzyme activity (11% of normal). We review the typical clinical presentation of patients with glycogenosis III and discuss the differential diagnoses of glycogenosis III versus the other glycogenoses resulting in vacuolar myopathy.

Hepatic glycogen storage disorders: what have we learned in recent years?

PURPOSE OF REVIEW: Glycogen storage disorders (GSDs) are inborn errors of metabolism with abnormal storage or utilization of glycogen. The present review focuses on recent advances in hepatic GSD types I, III and VI/IX, with emphasis on clinical aspects and treatment. RECENT FINDINGS: Evidence accumulates that poor metabolic control is a risk factor for the development of long-term complications, such as liver adenomas, low bone density/osteoporosis, and kidney disease in GSD I. However, mechanisms leading to these complications remain poorly understood and are being investigated. Molecular causes underlying neutropenia and neutrophil dysfunction in GSD I have been elucidated. Case series provide new insights into the natural course and outcome of GSD types VI and IX. For GSD III, a high protein/fat diet has been reported to improve (cardio)myopathy, but the beneficial effect of this dietary concept on muscle and liver disease manifestations needs to be further established in prospective studies. SUMMARY: Although further knowledge has been gained regarding pathophysiology, disease course, treatment, and complications of hepatic GSDs, more controlled prospective studies are needed to assess effects of different dietary and medical treatment options on long-term outcome and quality of life.

Lessons from two cases: is Fabry disease the correct diagnosis?

Fabry disease (FD) is an X linked inherited lysosomal storage disorder with complex multisystem involvement; it is caused by deficiency of the lysosomal enzyme α-galactosidase. Deficient enzyme activity leads to a wide spectrum of clinical manifestations consisting of dermatological, ophthalmological, cardiovascular, and urinary and central nervous system findings. As a result, FD should be considered in the differential diagnosis of many systemic diseases. Diagnosis of FD can arise from careful clinical and instrumental investigations, together with family history data and accurate interpretation of genetic and enzymatic analyses. Lack of knowledge on clinical findings of the disease and inept investigation methods unfortunately result in erroneous diagnosis. We present two patients who were referred to our clinic with a suspicion of ED and finally diagnosed as glycogen storage disorder type III and ornithine transcarbamylase deficiency, respectively.

A founder AGL mutation causing glycogen storage disease type IIIa in Inuit identified through whole-exome sequencing: a case series.

BACKGROUND: Glycogen storage disease type III is caused by mutations in both alleles of the AGL gene, which leads to reduced activity of glycogen-debranching enzyme. The clinical picture encompasses hypoglycemia, with glycogen accumulation leading to hepatomegaly and muscle involvement (skeletal and cardiac). We sought to identify the genetic cause of this disease within the Inuit community of Nunavik, in whom previous DNA sequencing had not identified such mutations. METHODS: Five Inuit children with a clinical and biochemical diagnosis of glycogen storage disease type IIIa were recruited to undergo genetic testing: 2 underwent whole-exome sequencing and all 5 underwent Sanger sequencing to confirm the identified mutation. Selected DNA regions near the AGL gene were also sequenced to identify a potential founder effect in the community. In addition, control samples from 4 adults of European descent and 7 family members of the affected children were analyzed for the specific mutation by Sanger sequencing. RESULTS: We identified a homozygous frame-shift deletion, c.4456delT, in exon 33 of the AGL gene in 2 children by whole-exome sequencing. Confirmation by Sanger sequencing showed the same mutation in all 5 patients, and 5 family members were found to be carriers. With the identification of this mutation in 5 probands, the estimated prevalence of genetically confirmed glycogen storage disease type IIIa in this region is among the highest worldwide (1:2500). Despite identical mutations, we saw variations in clinical features of the disease. INTERPRETATION: Our detection of a homozygous frameshift mutation in 5 Inuit children determines the cause of glycogen storage disease type IIIa and confirms a founder effect.

The effect of tailoring of cornstarch intake on stature in children with glycogen storage disease type III.

AIM: To determine the individual fasting tolerance for patients with glycogen storage disease type III (GSD III) and to assess their linear growth velocity after tailoring of dose intervals of oral uncooked cornstarch. PATIENTS AND METHODS: A prospective cohort study included 32 patients with GSD III aged 6 months-11.5 years (median: 3.3 years). The fasting tolerance of each patient was determined as the time interval between starch administration until the drop in blood glucose level was below 60 mg/dL. RESULTS: Some 27 patients (84.4%) developed hypoglycemia. The intervals between oral cornstarch administration were tailored for each child according to his/her individual fasting tolerance. After a 6-month follow up there was a significant reduction in seizure attacks (p<0.01) and liver size (p<0.01), but there was no statistically significant difference in liver transaminase and serum lactate levels. There was a significant improvement in height (p<0.01) and linear growth velocity (p<0.05) of these patients after at least a 12-month follow up. CONCLUSION: Adjusting the intervals between the cornstarch doses for each patient with GSD III, according to individual fasting tolerance test was very beneficial and resulted in improvement of the linear growth velocity and reduction in the frequency of hypoglycemic seizures as well as the size of the liver. Individual scheduling of cornstarch doses prevents complications in those who develop hypoglycemia at short intervals; it also allows some relaxation in schedule for those who can tolerate longer fasting hours to improve their appetite and prolong their uninterrupted sleep hours.