ABSTRACT
Introducción: La enfermedad por almacenamiento del glucógeno tipo III (GSDIII, Glycogen storage disease type III) o Enfermedad de Cori Forbes es un trastorno del proceso de glucogenólisis ocasionado por variantes del gen AGL que codifica la enzima desramificante del glucógeno; se encuentra ubicado en el cromosoma 1p21.2 y su alteración genera una degradación incompleta del glucógeno, llevando a una acumulación de dextrina límite en órganos blanco, ocasionando organomegalia y disfunción. Objetivo: Caracterizar molecularmente un paciente lactante mayor con diagnóstico clínico y bioquímico sospechoso de GSDIII. Materiales y Métodos: Paciente lactante mayor masculino con antecedente de displasia broncopulmonar, infección respiratoria aguda, reflujo gastroesofágico, hepatomegalia e intolerancia a la lactosa. Se realizó estudio molecular mediante secuenciación de exoma completo; las variantes reportadas fueron evaluadas por Software de predicción como: Mutation Tas-ter, PROVEAN, UMD-Predictor, POLYPHEN, SIFT, Human Splicing Finder. Finalmente, se realizó una red de interacción génica mediante el programa GeneMania para determinar asociaciones génicas cercanas. Resultados: Se identifi caron 3 variantes heterocigotas ubicadas en el gen AGL: p.Arg910* que ocasiona pérdida del dominio amilo-1,6 glucosidasa y el dominio de unión al glucógeno, y las variantes p.Trp373Cys, p.Asn565Ser que generan cambios missense en la proteína. El análisis de significancia clínica por medio de métodos in-sílico determinó una clasificación patogénica para todas las variantes. La red de interacción permitió observar asociaciones entre el gen AGL y los genes FOXA2, PPP1R3B, NHLRC1 y GCK, que tienen relación con procesos metabólicos. Conclusión: una sospecha clínica inicial, a través de una buena historia clínica y la pertinencia de estudios bioquímicos-metabólicos-genómicos dirigidos, permite brindar un correcto diagnóstico, tratamiento y seguimiento, acercándonos a la medicina de precisión.
Introduction: Glycogen storage disease type III (GSDIII) or Cori Forbes disease is a disorder of the glycogeno-lysis process caused by variants of the AGL gene that encodes the glycogen debranching enzyme; It is located on chromosome 1p21.2 and its alteration generate an incomplete degradation of glycogen, leading to an accumu-lation of borderline dextrin in target organs, causing organomegaly and dysfunction. Objective: To characterize at the molecular level an elderly male lactating patient from southwestern Colombia with a clinical, biochemical diagnosis suspected of GSDIII. Materials and methods: An elderly male infant with a history of bronchopul-monary dysplasia, acute respiratory infection, gastroesophageal refl ux, hepatomegaly, and lactose intolerance. A molecular study was performed by whole exome sequencing; the reported variants were evaluated by prediction software such as Mutation Taster, PROVEAN, UMD-Predictor, POLYPHEN, SIFT, Human Splicing Finder. Fi-nally, a gene interaction network was performed using the GeneMania program to determine close gene associa-tions. Results: 3 heterozygous variants located in the AGL gene were identifi ed: p.Arg910 * that causes loss of the amyl-1,6 glucosidase domain and the glycogen-binding domain, and the variants p.Trp373Cys, p.Asn565 in the protein. The analysis of clinical signifi cance by means of in-silico methods determined a pathogenic classifi cation for all the variants. The interaction network will observe associations between the AGL gene and the FOXA2, PPP1R3B, NHLRC1 and GCK genes, which are related to metabolic processes. Conclusion: an initial clinical suspicion, through a good clinical history and the relevance of directed biochemical-metabolic-genomic studies, allows us to provide a correct diagnosis, treatment, and follow-up, bringing us closer to precision medicine
Subject(s)
Humans , Male , Infant , Computational Biology , Glycogen Storage Disease Type III , ColombiaABSTRACT
OBJECTIVE@#To explore the clinical features and genetic basis of two children with glycogen storage disease type III (GSD III).@*METHODS@#The probands and their parents were subjected to genetic testing, and the pathogenity of candidate variants was analyzed by using bioinformatic tools.@*RESULTS@#Sequencing has identified compound heterozygous variants of the AGL gene in both children, namely c.1423+1G>A and c.3701-2A>G in case 1, and c.4213_c.4214insA (p.Glu1405Glufs*17) and c.3589-3C>G in case 2. Both children were diagnosed with GSD III. Literature review suggested that the main type variant among Chinese patients with GSD III involve splice sites of the AGL gene, with c.1735+1G>T being the most common. Based on the American College of Medical Genetics and Genomics standards and guidelines,c.1423+1G>A, c.3701-2A>G and c.4213_c.4214insA variants of AGL gene were predicted to be of pathogenic (PVS1+PM2+PM3, PVS1+PM2+PM3, PVS1+PM2+PP5), and c.3589-3C>G variant was predicted to be of uncertain significance (PM2+PM3+PP3).@*CONCLUSION@#The compound heterozygous variants of the AGL gene probably underlay the GSD III in both children. Above findings have enriched the spectrum of genetic variants underlying this disease.
Subject(s)
Child , Humans , Genetic Testing , Genomics , Glycogen Storage Disease Type III/genetics , MutationABSTRACT
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.
Subject(s)
Child , Child, Preschool , Female , Humans , Infant , Male , Glycogen Storage Disease Type III/diagnosis , Glycogen Storage Disease Type III/genetics , Phenotype , Sequence Deletion , Colombia , MutationABSTRACT
<p><b>OBJECTIVE</b>To detect potential mutation of the AGL gene in two siblings affected with glycogen storage disease type IIIa.</p><p><b>METHODS</b>Clinical data of the two siblings was collected and analyzed. Genomic DNA was extracted from peripheral venous blood samples from the patients and their parents. All exons and their flanking sequences of the AGL gene were subjected to PCR amplification and Sanger sequencing. Suspected mutation was verified in 75 healthy controls.</p><p><b>RESULTS</b>The main clinical features of the two siblings included hypoglycemia and hepatomegaly, along with markedly elevated liver and myocardial enzymes. Genetic analysis revealed that both siblings harbored compound heterozygous mutations c.1735+1G>T and c.959-1G>C of the AGL gene. Among these, the splicing mutation c.959-1G>C was a novel one with an allele frequency of <1%.</p><p><b>CONCLUSION</b>Based on their clinical features and genetic analysis, the siblings were diagnosed with glycogen storage disease type IIIa. The c.959-1G>C has enriched the spectrum of AGL gene mutations.</p>
Subject(s)
Adolescent , Female , Humans , Infant , Male , Amino Acid Sequence , Glycogen Debranching Enzyme System , Genetics , Glycogen Storage Disease Type III , Genetics , Mutation , Genetics , SiblingsABSTRACT
<p><b>OBJECTIVE</b>To investigate the clinical features and AGL gene mutations in a family with glycogen storage disease type IIIa (GSD IIIa).</p><p><b>METHODS</b>Clinical data for diagnosis, treatment and follow-up of a sick child with GSD III was collected and analyzed. Genomic DNA was extracted from the peripheral blood samples from the patient and his parents. Polymerase chain reaction and direct DNA sequencing were utilized to analyze all of the exons of the AGL gene.</p><p><b>RESULTS</b>The genotype of the child was found to be c.3710_3711delTA/IVS14+1G>T. The former was a maternally-inherited mutation, which has not been reported previously. The latter was an abnormal splice-site mutation inherited from the father.</p><p><b>CONCLUSION</b>Based on its clinical and molecular evidences, the patient was diagnosed as GSD IIIa in conjunction with retrobular optic neuritis.</p>
Subject(s)
Adult , Child, Preschool , Female , Humans , Male , Asian People , Genetics , Base Sequence , China , Glycogen Debranching Enzyme System , Genetics , Metabolism , Glycogen Storage Disease Type III , Genetics , Molecular Sequence Data , Pedigree , Point MutationABSTRACT
<p><b>OBJECTIVE</b>To reveal the molecular genetic pathogenesis of the glycogen storage disease type III (GSDIII) and to provide a prerequisite for prenatal gene diagnosis in future.</p><p><b>METHOD</b>All the coding regions as well as the border areas between exons and introns of the AGL gene and the parental relevant mutation sites were directly sequenced, so that to affirm the origin of the mutation. Then, detected novel heterozygous mutation was confirmed by cloning sequencing. Finally, definite diagnoses of the novel mutation were performed by a series of identification methods, including screening for the 100 normal controls by DHPLC in order to count the mutational frequency, analyze the conservative of the mutant amino acid sequence from 11 kinds of species and comprise the difference of the tertiary structure between the mutant protein and the normal one.</p><p><b>RESULT</b>The patient had compound heterozygous mutations, the c.100C>T (p.R34X) nonsense mutation and c. 1176_1178 del TCA deletion mutation. The p.R34X has been reported abroad, but the 1176_1178 del TCA/p.His392fs mutation is a novel one. The proband's father is heterozygous with the p.R34X mutation while his mother carries the c.1176_1178 del TCA mutation. The result from searching the dbSNP database, HGMD database and papers published in recent years showed that the c.1176_1178 del TCA is a novel mutation, but not an SNP. Conservative analysis results in 11 species indicate that the amino acid of the mutation site is highly conserved in the stage of evolution. Comparison results between the mutant protein and the normal one demonstrate that the deletion mutation results in the obvious variation of the spatial conformation of AGL protein.</p><p><b>CONCLUSION</b>The "c.1176_1178 del TCA (p.392delHis)" mutation is a novel pathogenic mutation. This mutation and the c.100C>T (p.R34X) is the cause that the proband suffer from the GSDIIIa disease. These two mutations are inherited from mother and father respectively. The methods from this paper can be used for further prenatal gene diagnosis.</p>
Subject(s)
Adult , Child, Preschool , Female , Humans , Male , Amino Acid Sequence , Base Sequence , Case-Control Studies , DNA Mutational Analysis , Exons , Glycogen Debranching Enzyme System , Chemistry , Genetics , Glycogen Storage Disease Type III , Diagnosis , Genetics , Heterozygote , Mutation , Pedigree , Polymerase Chain Reaction , Protein Conformation , Sequence AlignmentABSTRACT
<p><b>OBJECTIVE</b>Glycogen debranching enzyme (AGL) plays an important role in complete degradation of the glycogen, and has two independent catalytic activities, i.e., those of alpha-1, 4-glucanotransferase (EC 2.4. 1.25) and amylo-1,6-glucosidase (EC 3.2. 1.33). A deficiency in activities of AGL causes excessive accumulation of glycogen with short branched outer chains and results in glycogen storage disease type III (GSD III; MIM #232 400), an autosomal recessive inborn disorder of glycogen metabolism. The present study aimed to investigate the mutation of AGL in 10 Chinese patients with GSD III.</p><p><b>METHOD</b>Clinical and laboratory data of 10 patients with typical clinical manifestations of GSD III suggesting hypoglycemia, hyperlipidemia, increased creatine-phosphokinase and its isozyme were collected. The coding regions and their flanking introns of AGL gene of the 10 patients were amplified by PCR and analyzed by direct DNA sequencing. All the mutated alleles were confirmed by bidirectional DNA sequencing. The 3 novel splicing mutations were analyzed by restriction fragment length polymorphism (RFLP) in 50 healthy children (control). The 2 small deletions (c.408-411delTTTG, c.2717-2721delAGATC) were analyzed by fluorescent polymerase chain reaction and gene scan analysis to confirm the number of deleted bases.</p><p><b>RESULT</b>Thirteen different mutations were identified, including 4 splicing mutations (IVS6 + 1G > A, IVS6-1G > A, IVS14 + 1G > T, IVS26-2A > C), 5 nonsense mutations (R469X, R864X, S929X, R977X, Y1428X), 3 small deletions (c.408-411delTTTG, c.2717-2721delAGATC, c.2823delT) and 1 insert mutation (c.4234insT). Except for IVS14 + 1G > T, R864X, and R977X, the other 10 mutations are novel; 18 mutated alleles were identified in the 20 alleles (90%). IVS14 + 1G > T was the most frequently seen mutation, accounting for 5 of 20 (25%) alleles examined. None of homozygote and heterozygote of the 3 novel splicing mutations was found in the 50 healthy controls by RFLP analysis. With the fluorescent polymerase chain reaction and gene scan analysis, c.408411deTTTG mutation and c.2717-2721delAGATC mutation were confirmed to have 4 and 5 bases deletion respectively.</p><p><b>CONCLUSION</b>Thirteen mutations were identified in the 10 cases with GSD III, with 10 novel mutations. IVS14 + 1G > T was a relatively common mutation. This study revealed the heterozygosity of AGL gene in Chinese patients with GSD III.</p>
Subject(s)
Adolescent , Child , Child, Preschool , Humans , Asian People , Genetics , Base Sequence , DNA Mutational Analysis , Glycogen Debranching Enzyme System , Genetics , Glycogen Storage Disease Type III , GeneticsABSTRACT
<p><b>OBJECTIVE</b>Glycogen storage disease type III (GSD III) is an autosomal recessive disease caused by glycogen debranching enzyme (GDE) gene (AGL gene) mutation resulting in hepatomegaly, hypoglycemia, short stature and hyperlipidemia. GSD IIIA, involves both liver and muscle, and accounts for up to 80% of GSD III. The definitive diagnosis depends on either mutation analysis or liver and muscle glycogen debranching enzyme activity tests. This study aimed to establish enzymologic diagnostic method for GSD IIIA firstly in China by detecting muscular GDE activity, glycogen content and structure and to determine the normal range of muscular GDE activity, glycogen content and structure in Chinese children.</p><p><b>METHOD</b>Muscle samples were collected from normal controls (male 15, female 20; 12-78 years old), molecularly confirmed GSD III A patients (male 8, female 4, 2-27 years old) and other myopathy patients (male 9, 2-19 years old). Glycogen in the muscle homogenate was degraded into glucose by amyloglucosidase and phosphorylase respectively. The glycogen content and structure were identified by glucose yield determination. The debranching enzyme activity was determined using limit dextrin as substrate. Independent samples Kruskal-Wallis H test, Nemenyi-Wilcoxson-Wilcox test, and Chi-square test were used for statistical analyses by SPSS 11.5.</p><p><b>RESULT</b>(1) GSD III A patients' glycogen content were higher, but G1P/G ratio and GDE activity were lower than those of the other two groups (P < 0.01). In all of the three parameters, there were no significant difference between normal controls and other myopathy patients. (2) The range of normal values: glycogen content 0.31%-0.43%, G1P/G ratio 22.37%- 26.43%, GDE activity 0.234-0.284 micromol/(g. min). (3) Enzymologic diagnostic method had a power similar to that of gene analysis in diagnosis of GSD-IIIA patients. The sensitivity and specificity of enzymologic diagnostic method and mutation detection were 91.7% and 100% respectively.</p><p><b>CONCLUSION</b>Enzymologic diagnostic method of GSD IIIA was firstly established in China. The range of normal values was determined. This method could be used in diagnosing suspected GSD IIIA patients in the clinic.</p>
Subject(s)
Adolescent , Adult , Aged , Child , Child, Preschool , Female , Humans , Male , Middle Aged , Young Adult , Biopsy , Case-Control Studies , China , Glycogen , Glycogen Debranching Enzyme System , Glycogen Storage Disease Type III , Diagnosis , Pathology , Muscles , Chemistry , PathologyABSTRACT
Glycogen storage disease type III (GSD III) is a very rare disorder caused by a deficiency in the activities of glycogen debranching enzymes (amylo-1-6-glucosidase and 4-alpha-glucanotransferase). GSD III is characterized by the accumulation of abnormal glycogen in the liver and skeletal muscle. The primary clinical manifestations are hepatomegaly, fasting hypoglycemia, and hyperlipidemia in infants. We report a rare case of GSD III in an adult. A 52-year-old woman presented to our clinic due to dyspnea on exertion, severe general weakness, and hepatomegaly. Hypertrophic cardiomyopathy was diagnosed based on echocardiogram findings. The microscopic findings of liver and skeletal muscle biopsies were consistent with the diagnosis of GSD. DNA analysis prompted by clinical and pathologic findings led to a definitive diagnosis of GSD IIIa. Diet therapy with cornstarch was started, and the patient was followed closely. This represents the first reported case of GSD IIIa diagnosed in an adult in Korea.
Subject(s)
Female , Humans , Middle Aged , Amino Acid Substitution , Base Sequence , Glycogen Storage Disease Type III/diagnosis , Hepatomegaly/genetics , Heterozygote , Liver/pathology , Molecular Sequence Data , Muscle, Skeletal/pathology , Starch/therapeutic use , Tomography, X-Ray ComputedABSTRACT
Glycogen-storage diseases (GSD) are caused by enzymatic defects of glycogen degradation. Most of these enzymatic defects are mainly localized in the liver. In this group the clinical symptoms are hepatomegaly and hypoglycemia. Other enzyme defects are localized in muscles. Their global incidence is 1: 20.000 newborns and the inheritance is autosomal recessive, except for one, that is X-linked inherited. The most frequent GSD types are I, II, III and VI. Type I-a GSD is due to glucose-6- phosphatase deficiency and type III GSD is due to debranching-enzyme deficiency. In both types the clinical presentations include hypoglycemia, hepatomegaly, hyperlactacidemia and hyperlipidemia. The complications like gout, progressive renal failure and liver adenoma in type I-a GSD are particularly observed in adults. The aim of treatment is to prevent hypoglycemia and suppress secondary metabolic derangements with a diet every 2-3 hours 24 hours a day, providing precooked starch and uncooked starch. The prognosis, as in the majority of inborn errors of metabolism, depends on the age at diagnosis, early treatment and good follow-up during life.
Las glucogenosis son alteraciones del metabolismo del glucógeno, ocasionados por la ausencia o deficiencia de enzimas que participan tanto de su síntesis como en su degradación. La mayoría están localizadas en el hígado, siendo los signos clínicos característicos la hepatomegalia y la hipoglucemia. El resto se ubica en el tejido muscular. Su frecuencia es de 1:20 000 recién nacidos y son de herencia autosómica recesiva, excepto una que está ligada al cromosoma X. Las formas más frecuentes son las tipo I, II, III y VI. La glucogenosis tipo I-a se produce por la deficiencia de la enzima glucosa-6- fosfata y la glucogenosis tipo III por la falta de la enzima desramificadora de glucógeno hepático. En ambas, las manifestaciones clínicas son hipoglucemia, hepatomegalia, hiperlactacidemia, hiperlipidemia. Las complicaciones a largo plazo son gota, insuficiencia renal progresiva, adenoma hepático principalmente en la glucogenosis tipo I-a. El tratamiento consiste en evitar las hipoglucemias y las manifestaciones secundarías con una dieta fraccionada durante las 24 h del día, proporcionando carbohidratos de preferencia de absorción lenta y almidón crudo. El pronóstico general como en la mayoría de los errores innatos del metabolismo, dependerá de la edad de diagnóstico, del tratamiento oportuno y del buen control metabólico durante toda la vida.
Subject(s)
Humans , Glycogen Storage Disease Type I/complications , Glycogen Storage Disease Type I/diagnosis , Glycogen Storage Disease Type I/therapy , Glycogen Storage Disease Type III/complications , Glycogen Storage Disease Type III/diagnosis , Glycogen Storage Disease Type III/therapy , Hepatomegaly/etiologyABSTRACT
There are 3 cases of liver type glycogen storage diseases. All of them presented with protruding abdomen, failure to thrive, doll face and mark hepatomegaly. Laboratory findings were hypoglycemia, metabolic acidosis, abnormal liver function test, hyperlipidemia and prolonged bleeding time in GSD Ia. GSD III has no hypoglycemia and borderline hyperuricemia. Glucagon stimulation test helps to differentiate typing. The aim of treatment is to prevent hypoglycemia, suppress lactic acid production, decrease blood lipid and uric acid levels and enhances statural growth by uncooked cornstarch. Complications such as epistaxis and suspected liver adenoma have to be closely followed up. Genetic counseling for both types GSD are autosomal recessive with recurrence risk of 25%. Prenatal diagnosis by enzymes assay or molecular diagnosi are not available in this hospital.
Subject(s)
Child , Child, Preschool , Female , Glycogen Storage Disease Type I/complications , Glycogen Storage Disease Type III/complications , Humans , ThailandABSTRACT
<p><b>OBJECTIVE</b>Type III glycogen storage disease (GSD-III, McKusick 232400), is a rare autosomal recessive disorder, also known as Cori's or Forbe's disease. The affected enzyme is amylo-1,6-glucosidase, 4-alpha-glucanotransferase (glycogen debrancher enzyme, GDE or amylogluco-sidase, AGL), which is responsible for the debranching of the glycogen molecule during catabolism. The AGL gene is located on chromosome 1p21 and contains 35 exons translated in a monomeric protein product. The clinical manifestations of GSD-III are represented by hepatomegaly, recurrent hypoglycemia, seizures, growth failure, dysmorphism, hyperlipidemia, raised transaminases and creatine kinase concentrations and, in a number of subjects, myopathy and cardiomyopathy. The hepatocellular adenoma, hepatocellular carcinoma, diabetes mellitus and liver fibrosis remain rare events. The diagnosis of debrancher deficiency was established by laboratory tests, electromyography (EMG), and muscle and liver biopsy.</p><p><b>METHODS</b>We studied six GSD-III families after patients or parental consent and the clinical characteristics were documented. Analysis of 33 exons and part exon-intron boundaries of the AGL gene in patients and their parents were carried out by PCR and direct DNA sequencing.</p><p><b>RESULTS</b>The clinical features included hepatomegaly, splenomegaly, recurrent hypoglycemia, hyperlipidemia, growth failure, raised transaminases and acidosis. Administration of epinephrine 2 hours after a carbohydrate meal could provoke normal rise of blood glucose in the affected individuals, but could not evoke any response after overnight fasting. Administration of raw-corn-starch could maintain normoglycemia and improve the disease condition. Mutation analysis for patient 1 was normal. Patient 2 had a compound heterozygote: a C-to-T transition at nucleotide 1294 (come from father, 1294C > T, L 298 L) in exon 8 and a G-to-T transition at nucleotide 4747 (from mother, 4747G > T, E1450X) in exon 34. Patient 3 had a compound heterozygote: a C-to-T transition at nucleotide 1294 (from father, 1294C > T, L 298 L) in exon 8 and a G-to-A transition at nucleotide -10 (from mother, -10G > A) in exon 3. Patient 4 was a homozygote: an insertion of a nucleotide CT into position +65 in exon 35 (4664 ins CT). Patient 5 had a compound heterozygote: a 8 bp deletion at nucleotide 2341 (from father, 2341delGCCATAGA, frameshift mutation) in exon 16 and a G-to-A transition at nucleotide 1559 (from mother, 1559G > A, R 387 Q) in exon 10. Patient 6 had a compound heterozygote: a T-to-G transition at nucleotide 1686 (from mother, 1686T > G, Y429 X) in exon 12 and a G-to-A transition at nucleotide 3742 (from father, 3742G > A, G 1115 R) in exon 26.</p><p><b>CONCLUSION</b>GSD-III patients have variable phenotypic characteristics. Administration of raw-corn-starch can effectively improve the disease outcome. We identified 8 new mutations on AGL gene through nucleotide sequence analysis.</p>
Subject(s)
Child , Child, Preschool , Female , Humans , Male , Glycogen Debranching Enzyme System , Genetics , Glycogen Storage Disease Type III , Genetics , Therapeutics , MutationABSTRACT
A case of a 21 years male patient with type 3 glycogen storage disorder diagnosed at necropsy, who died suddenly with hypovolemic shock following a massive upper gastrointestinal bleeding due to hepatocellular failure is reported. Salient features of GSD type 3 are briefly discussed.
Subject(s)
Abdominal Pain/diagnosis , Adult , Autopsy , Biopsy, Needle , Combined Modality Therapy , Disease Progression , Fatal Outcome , Gastrointestinal Hemorrhage/etiology , Glycogen Storage Disease Type III/complications , Humans , Immunohistochemistry , India , Liver Failure, Acute/etiology , Male , Severity of Illness IndexABSTRACT
The relationship between essential fatty acid [EFA] status and degree of hyperbilirubinaemia and oxidant stress in infants and children with chronic liver diseases was evaluated. Thirty patients with chronic cholestasis and 30 with liver cirrhosis were examined; 30 healthy subjects served as controls. Patient groups had significant decreases in EFAs and significant elevation of total bilirubin. Levels of thiobarbituric acid reactive substances were significantly raised and were significantly inversely correlated to decreased EFA levels. There were also significant decreases in retinol, alpha-tocopherol and alpha-tocopherol/total lipids ratio, which had significant positive correlations with decreased EFA levels. Infants and children with chronic liver diseases have a high risk of EFA deficiency correlated with progressive elevation of serum bilirubin and progressive deterioration of oxidant status