The clinical data of 2 infants with infantile glycogen storage disease type II (GSD II) from one pedigree were collected. The method of dried blood spots (DBS) was applied to collect peripheral blood samples, and the activity of acid alpha-D-glucosidase (GAA) in leukocytes was measured. The coding region of GAA gene in this pedigree was amplified by polymerase chain reaction and then direct sequencing was used to analyze mutations in GAA gene. The two infants were twins, who were admitted to the hospital due to feeding difficulties, generalized muscle weakness and hypotonia, cardiomegaly, and cardiac insufficiency when they were 10 months old. The GAA activity in leukocytes in the two infants was significantly lower than in normal controls. Gene sequencing revealed 2 compound heterozygous mutations in the two infants, i.e., G1942A and G2214A, respectively. G1942A had been proved pathogenic, and the latter one, G2214A, was a nonsense mutation, resulting in the change of tryptophan, the 738th amino acid of GAA, into a stop codon. The two infants were diagnosed with GSD II by gene detection and no enzyme replacement therapy could be provided to them. Follow-up visits showed that the two infants died at home at the age of 15 months and 17 months, respectively. GSD II is caused by deficiency of GAA activity resulting from mutation of GAA gene. The detection of GAA activity in peripheral blood by DBS and GAA gene detection are effective and feasible methods for diagnosis of GSD II.
Female ; Glycogen Storage Disease Type II ; genetics ; Humans ; Infant ; Mutation ; Pedigree ; alpha-Glucosidases ; genetics

Glycogen storage disease type II (GSD II) is an autosomal recessive disorder caused by a deficiency of the lysosomal glycogen-hydrolyzing enzyme acid α-glucosidase (GAA) and can affect multiple systems including the heart and skeletal muscle. The aim of this study was to investigate three children with GSD II confirmed by GAA gene analysis and to report their clinical characteristics and gene mutations. One case was classified as infantile-onset GSD II, and two cases as late-onset GSD II. The infantile-onset patient (aged 4 months) showed no weight increase and had dyspnea, muscle hypotonia, and increased alanine aminotransferase and creatine kinase; echocardiography showed hypertrophic cardiomyopathy. The late-onset patients (aged 8 years and 13 years respectively) showed persistently elevated liver enzymes; one of them had recurrent respiratory tract infection and restrictive ventilation disorder, and the other case showed significantly increased creatase but normal electromyographic findings. Peripheral blood genetic testing for GAA gene showed six pathogenic mutations in the three cases, and the mutations c.2738C>T and c.568C>T had not been reported. Therefore, peripheral blood genetic testing for GAA gene is an effective diagnostic method.
Adolescent ; Child ; Child, Preschool ; Female ; Glycogen Storage Disease Type II ; genetics ; Humans ; Male ; Mutation ; alpha-Glucosidases ; genetics

OBJECTIVE: To explore the clinical features, lysosomal enzymatic [acid α-glucosidase (GAA)] activities and genetic variants in a child with late-onset Pompe disease (LOPD). METHODS: Clinical data of a child who had presented at the Genetic Counseling Clinic of West China Second University Hospital in August 2020 was retrospectively analyzed. Blood samples were collected from the patient and her parents for the isolation of leukocytes and lymphocytes as well as DNA extraction. The activity of lysosomal enzyme GAA in leukocytes and lymphocytes was analyzed with or without addition of inhibitor of GAA isozyme. Potential variants in genes associated with neuromuscular disorders were analyzed, in addition with conservation of the variant sites and protein structure. The remaining samples from 20 individuals undergoing peripheral blood lymphocyte chromosomal karyotyping were mixed and used as the normal reference for the enzymatic activities. RESULTS: The child, a 9-year-old female, had featured delayed language and motor development from 2 years and 11 months. Physical examination revealed unstable walking, difficulty in going upstairs and obvious scoliosis. Her serum creatine kinase was significantly increased, along with abnormal electromyography, whilst no abnormality was found by cardiac ultrasound. Genetic testing revealed that she has harbored compound heterozygous variants of the GAA gene, namely c.1996dupG (p.A666Gfs*71) (maternal) and c.701C>T (p.T234M) (paternal). Based on the guidelines from the American College of Medical Genetics and Genomics, the c.1996dupG (p.A666Gfs*71) was rated as pathogenic (PVS1+PM2_Supporting+PM3), whilst the c.701C>T (p.T234M) was rated as likely pathogenic (PM1+PM2_Supporting+PM3+PM5+PP3). The GAA in the leukocytes from the patient, her father and mother were respectively 76.1%, 91.3% and 95.6% of the normal value without the inhibitor, and 70.8%, 112.9% and 128.2% of the normal value with the inhibitor, whilst the activity of GAA in their leukocytes had decreased by 6 ~ 9 times after adding the inhibitor. GAA in lymphocytes of the patient, her father and mother were 68.3%, 59.0% and 59.5% of the normal value without the inhibitor, and 41.0%, 89.5% and 57.7% of the normal value with the inhibitor, the activity of GAA in lymphocytes has decreased by 2 ~ 5 times after adding the inhibitor. CONCLUSION The child was diagnosed with LOPD due to the c.1996dupG and c.701C>T compound heterozygous variants of the GAA gene. The residual activity of GAA among LOPD patients can range widely and the changes may be atypical. The diagnosis of LOPD should not be based solely on the results of enzymatic activity but combined clinical manifestation, genetic testing and measurement of enzymatic activity.
Humans ; Child ; Male ; Female ; Glycogen Storage Disease Type II/pathology* ; Retrospective Studies ; alpha-Glucosidases/genetics* ; Mothers ; Lysosomes/pathology* ; Mutation

OBJECTIVETo carry out prenatal diagnosis for a glycogen storage disease type II (GSD II ) affected family.

METHODSThe acid-α -glucosidase (GAA) activity was measured in whole leukocytes and cultured amniocytes with 4-methylumbelliferyl-α -D-glucopyranoside as substrate and with acarbose as inhibitor. The coding regions of GAA gene were amplified by polymerase chain reaction and analyzed by direct DNA sequencing.

RESULTSThe proband and the fetus had low GAA activity (12.3% and 1.1% of the average normal range, respectively). Mutation analysis of the GAA gene revealed a novel nonsense mutation p.W738X and a reported nonsense mutation p.E888X in both the proband and the fetus; the reported pseudodeficiency allele c.[1726G to A: 2065G to A] was found in the proband, the mother and the fetus.

CONCLUSIONThe proband and the fetus were both GSD II affected. A combination of GAA activity analysis and mutation analysis is efficient for the prenatal diagnosis of GSD II. Mutation analysis should be a routine method in the prenatal diagnosis of GSD II in Asian population, where pseudodeficiency allele can cause low GAA activity in normal individuals which is relatively common in Asian.

Alleles ; Base Sequence ; Female ; Glycogen Storage Disease Type II ; diagnosis ; enzymology ; genetics ; Humans ; Mutation ; Pedigree ; Pregnancy ; Prenatal Diagnosis ; alpha-Glucosidases ; genetics ; metabolism

Pompe disease, also called type II glycogen storage disease, is a rare autosomal recessive inherited disease caused by the storage of glycogen in lysosome due to acid α-glucosidase (GAA) deficiency, with the most severe conditions in the skeletal muscle, the myocardium, and the smooth muscle. Patients may have the manifestations of dyspnea and dyskinesia, with or without hypertrophic cardiomyopathy. GAA gene mutation has ethnic and regional differences, and new mutation sites are found with the advances in research. Gene analysis is the gold standard for the diagnosis of Pompe disease. Conventional methods, such as skin and muscle biopsies and dried blood spot test, have certain limitations for the diagnosis of this disease. In recent years, prenatal diagnosis and newborn screening play an important role in early diagnosis of this disease. Enzyme replacement therapy (ERT) has a satisfactory effect in the treatment of this disease, but it may lead to immune intolerance. New targeted gene therapy and modified ERT will be put into practice in the future. This article reviews the research advances in the diagnosis and treatment of Pompe disease.
Animals ; Enzyme Replacement Therapy ; Glycogen Storage Disease Type II ; diagnosis ; enzymology ; genetics ; therapy ; Humans ; Targeted Gene Repair ; alpha-Glucosidases ; genetics ; metabolism

OBJECTIVETo investigate the levels and changes of sexual hormone in serum and seminal plasma, and the epidermal growth factor (EGF), alpha-glucosidase, and fructose in the seminal plasma of non-obstructive azoospermic patients, and to assess the significance of the analysis of their chromosomes.

METHODSThirty-six non-obstructive azoospermic males and 26 normal males were chosen. The results in reproductive endocrine and genetics obtained by radioimmunoassay, colorimetry, and chromosomes G and C banding assay were compared and analyzed to explore into the causes of infertility.

RESULTSThe levels of FSH, LH, PRL and E2 in the serum of the non-obstructive azoospermic patients were higher than those of the control group, but the T level had no significant difference between the two groups. There were no obvious differences in the sexual hormones except in FSH of the seminal plasma. There were 2 cases of abnormal sex chromosomes, 2 cases of big Y chromosomes and 7 cases of small Y chromosomes in the non-obstructive azoospermic patients. No correlation was found between EGF and fructose in the seminal plasma.

CONCLUSIONThe level of sexual hormone in serum, alpha-glucosidase in seminal plasma and abnormal chromosomes might be closely related to non-obstructive azoospermia.

Adult ; Azoospermia ; etiology ; genetics ; metabolism ; Case-Control Studies ; Chromosome Banding ; Chromosomes, Human, Y ; Epidermal Growth Factor ; metabolism ; Gonadal Steroid Hormones ; metabolism ; Humans ; Male ; Semen ; chemistry ; alpha-Glucosidases ; metabolism

OBJECTIVETo summarize clinical features and diagnosis of Chinese infantile patients with glycogen storage disease type II (GSD II).

METHODSix infant patients with GSD II diagnosed from January 2012 to June 2014 in the Department of Pediatrics, Peking University First Hospital were enrolled into this study. Clinical information of the 6 patients, including clinical manifestation, blood biochemistry, chest X-ray, echocardiogram, electrocardiogram, acid alpha-glucosidase (GAA) activity and GAA gene mutation analysis by direct sequencing of polymerase chain reaction (PCR) product were reviewed.

RESULTOf the 6 patients, five were female and one was male, five of whom were classic infantile type while the other one was atypical. The age of onset ranged from birth to 3-month-old. All patients had varying degrees of generalized muscle weakness, hypotonia and development retardation or retrogression. Other common findings were feeding difficulties in two patients, tongue weakness in two patients, respiratory distress in four patients, macroglossia in one patient, and hepatomegaly in two patients. Left ventricular hypertrophy and cardiomegaly were obvious in all the six patients. All six patients were found to have a enlarged heart in physical examination, and three patients who underwent a chest X-ray examination had an enlarged heart shadow. Four patients who had an echocardiography were found to have myocardial hypertrophy. The electrocardiogram in three patients showed short PR intervals and high voltage. The creatine kinase (CK) levels were three to seven times elevated. The mildest elevated CK was 441 IU/L, and the highest CK level was 1 238 U/L. Assay of GAA enzyme activity in whole blood showed significantly reduced activity (1.3 nmol/ (spot·d) to 2 nmol/(spot·d)) in the patients tested. Gene sequencing in 4 patients showed 8 pathogenic mutations, including 6 missense mutations, one nonsense mutation and one frameshift mutation. The missense mutations were c.998C > A (p.Thr333Lys), c.1280T > C (p.Met427Thr), c.1760T > C (p.Leu587Pro), c.1924G > T (p.Val642Phe), c.2012T > A (p.Met671Lys) and c.2105G > A (p.Arg702His). The nonsense mutation was c2662G > T (p.Glu888X), and the frameshift mutation was c2812_2813delTG (p.Cys938fs). The 5 classic infantile patients died at the age of 7 to 22 months. The atypical infantile patient was 2 years and five months old according to our latest follow up.

CONCLUSIONInfantile GSD II had similar motor manifestations and cardiac involvements, blood biochemical test, imaging findings, enzyme assays, though there were slight differences. The probability of GSD II should be taken into consideration if an infant has both muscular disease and cardiac involvement.

Asian Continental Ancestry Group ; Female ; Glycogen Storage Disease Type II ; diagnosis ; pathology ; Humans ; Infant ; Infant, Newborn ; Macroglossia ; congenital ; Male ; Muscle Weakness ; Mutation ; Mutation, Missense ; Polymerase Chain Reaction ; alpha-Glucosidases ; genetics ; metabolism

Human maltase-glucoamylase (MGAM) hydrolyzes linear alpha-1,4-linked oligosaccharide substrates, playing a crucial role in the production of glucose in the human lumen and acting as an efficient drug target for type 2 diabetes and obesity. The amino- and carboxyl-terminal portions of MGAM (MGAM-N and MGAM-C) carry out the same catalytic reaction but have different substrate specificities. In this study, we report crystal structures of MGAM-C alone at a resolution of 3.1 Å, and in complex with its inhibitor acarbose at a resolution of 2.9 Å. Structural studies, combined with biochemical analysis, revealed that a segment of 21 amino acids in the active site of MGAM-C forms additional sugar subsites (+ 2 and + 3 subsites), accounting for the preference for longer substrates of MAGM-C compared with that of MGAM-N. Moreover, we discovered that a single mutation of Trp1251 to tyrosine in MGAM-C imparts a novel catalytic ability to digest branched alpha-1,6-linked oligosaccharides. These results provide important information for understanding the substrate specificity of alpha-glucosidases during the process of terminal starch digestion, and for designing more efficient drugs to control type 2 diabetes or obesity.
Acarbose ; chemistry ; Amino Acid Sequence ; Catalytic Domain ; Crystallography, X-Ray ; Glycoside Hydrolase Inhibitors ; Humans ; Hydrogen Bonding ; Intestines ; enzymology ; Kinetics ; Maltose ; chemistry ; Molecular Sequence Data ; Mutagenesis, Site-Directed ; Mutation, Missense ; Oligosaccharides ; chemistry ; Pichia ; Protein Binding ; Recombinant Proteins ; antagonists & inhibitors ; chemistry ; genetics ; Substrate Specificity ; Surface Properties ; alpha-Glucosidases ; chemistry ; genetics

As a large family of hydrolases, GTPases are widespread in cells and play the very important biological function of hydrolyzing GTP into GDP and inorganic phosphate through binding with it. GTPases are involved in cell cycle regulation, protein synthesis, and protein transportation. Chaperones can facilitate the folding or refolding of nascent peptides and denatured proteins to their native states. However, chaperones do not occur in the native structures in which they can perform their normal biological functions. In the current study, the chaperone activity of the conserved GTPases of Escherichia coli is tested by the chemical denaturation and chaperone-assisted renaturation of citrate synthase and α-glucosidase. The effects of ribosomes and nucleotides on the chaperone activity are also examined. Our data indicate that these conserved GTPases have chaperone properties, and may be ancestral protein folding factors that have appeared before dedicated chaperones.
Citrate (si)-Synthase ; chemistry ; Cloning, Molecular ; Conserved Sequence ; Escherichia coli ; cytology ; enzymology ; GTP Phosphohydrolases ; chemistry ; genetics ; isolation & purification ; metabolism ; Guanosine Diphosphate ; pharmacology ; Guanosine Triphosphate ; analogs & derivatives ; pharmacology ; Molecular Chaperones ; chemistry ; genetics ; isolation & purification ; metabolism ; Protein Denaturation ; drug effects ; Protein Renaturation ; drug effects ; Ribosomes ; metabolism ; alpha-Glucosidases ; chemistry