Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P06889 (Mol)
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Glycogen storage disease due to phosphorylase kinase deficiency occurs in several variants that differ in mode of inheritance and tissue-specificity. This heterogeneity is suspected to be largely due to mutations affecting different subunits and isoforms of phosphorylase kinase. The gene of the ubiquitously expressed beta subunit, PHKB, was a candidate for involvement in autosomally transmitted phosphorylase kinase deficiency of liver and muscle. To identify such mutations, the complete PHKB coding sequence was amplified by RT-PCR of RNA isolated from blood samples of patients and analyzed by direct sequencing of PCR products. The characterization of mutations was complemented by PCR of genomic DNA. In one female and four male patients, we identified five independent nonsense mutations (Y418ter; R428ter; Y974H+E975ter; Q656ter in two cases), one single-base insertion in codon N421, one splice-site mutation affecting exon 31, and a large deletion involving the loss of exon 8. Although these severe translation-disrupting mutations occur in constitutively expressed sequences of the only known beta subunit gene of phosphorylase kinase, PHKB, they are associated with a surprisingly mild clinical phenotype, affecting virtually only the liver, and relatively high residual enzyme activity of approximately 10%.
Hum Mol Genet 1997 Jul
PMID:Autosomal glycogenosis of liver and muscle due to phosphorylase kinase deficiency is caused by mutations in the phosphorylase kinase beta subunit (PHKB). 921 82

Mutations in three different genes of phosphorylase kinase (Phk) subunits, PHKA2, PHKB and PHKG2, can give rise to glycogen storage disease of the liver. The autosomal-recessive, liver-specific variant of Phk deficiency is caused by mutations in the gene encoding the testis/liver isoform of the catalytic gamma subunit, PHKG2. To facilitate mutation detection and to improve our understanding of the molecular evolution of Phk subunit isoforms, we have determined the structure of the human PHKG2 gene. The gene extends over 9.5 kilonucleotides and is divided into 10 exons; positions of introns are highly conserved between PHKG2 and the gene of the muscle isoform of the gamma subunit, PHKG1. The beginning of intron 2 harbors a highly informative GGT/GT microsatellite repeat, the first polymorphic marker in the PHKG2 gene at human chromosome 16p11.2-p12.1. Employing the gene sequence, we have identified homozygous translation-terminating mutations, 277delC and Arg44ter, in the two published cases of liver Phk deficiency who developed cirrhosis in childhood. As liver Phk deficiency is generally a benign condition and progression to cirrhosis is very rare, this finding suggests that PHKG2 mutations are associated with an increased cirrhosis risk.
Hum Mol Genet 1998 Jan
PMID:Liver glycogenosis due to phosphorylase kinase deficiency: PHKG2 gene structure and mutations associated with cirrhosis. 938 16

Unequal homologous recombination between repetitive genetic elements is one mechanism that mediates genome instability. We have characterized a homologous recombination event between two neighboring LINE-1 sequences in the human gene encoding the beta subunit of phosphorylase kinase (PHKB). It has lead to the deletion of 7574 nucleotides of genomic DNA including exon 8 of this gene, giving rise to glycogen storage disease through phosphorylase kinase deficiency. To our knowledge, this is the first example of a mutation due to unequal homologous recombination between LINE-1 elements. The sequence features of the recombining LINE-1 elements and of the recombination junction site, and possible reasons for the more frequent occurrence of unequal homologous recombination between Alu elements are discussed.
J Mol Biol 1998 Apr 03
PMID:Unequal homologous recombination between LINE-1 elements as a mutational mechanism in human genetic disease. 953 76

Pompe disease is a generalized lysosomal glycogenosis affecting essentially the skeletal muscles and the heart. It is due to the deficiency of acid alpha-glucosidase, also called acid maltase, involved in glycogen degradation by the cleavage of alpha-1,4 and alpha-1,6 glycosidic linkages. The severe infantile, milder juvenile, and late-onset or adult forms are associated under the generic name of glycogenoses type II. The clinical picture can differ according to these variants, forming a clinical spectrum from cardiorespiratory failure with early death in the infantile variant to late muscular weakness or respiratory problems in the adult variant. Enzymatic pre- and postnatal diagnoses and mutation characterization are available. Different therapeutic attempts have been conceived and some of them have come to clinical trials. Several pilot studies have demonstrated the feasibility of gene therapy and remarkable advances have been realized. Of particular interest, strategies for gene therapy in a generalized disease like Pompe disease must be accompanied by the secretion and uptake of the corrective enzyme by more distant cells or tissues in order to obtain efficient results. Preliminary positive results have been obtained in animal models, and new approaches with improvements in the access to muscle and heart, in the efficacy and innocuity of vectors, and in the clinical evolution are proposed. Gene therapy is a promising strategy for Pompe disease. However, several steps must be explored before this method becomes clinically successful.
Mol Genet Metab 2000 Jul
PMID:Approach to gene therapy of glycogenosis type II (Pompe disease). 1092 70

The purpose of this study was to investigate the usefulness of urinary lactate measurements to assess the adequacy of dietary treatment in patients with type I glycogen storage disease (GSD-I). We determined the correlation of urine and blood lactate concentrations in 21 GSD-I patients during 24-h admissions to the General Clinical Research Center (GCRC) during which hourly blood samples and aliquots of every void were obtained. In all but 1 patient, we found a good correlation between blood lactate concentrations and urinary lactate excretion. One patient did not excrete lactate in significant amounts despite elevated blood lactate concentrations. In 17 patients, the highest blood lactate concentrations occurred during the night. Markedly elevated nighttime average blood lactate concentrations above 3.5 mmol/l resulted in a urinary lactate concentration above the normal limit of 0.067 mmol/mmol creatinine in the first morning urine specimen. Mildly elevated nighttime blood lactate concentrations (between 2.2 and 3.5 mmol/l) led to urinary lactate concentrations that were either normal or moderately elevated. All patients with normal blood lactate concentrations during the night also had normal first morning urinary lactate concentrations. The degree of urinary lactate excretion in relation to blood lactate concentrations varied by individual. Urinary filter paper specimens, collected at home during the night and in the morning and mailed to the laboratory, were used to monitor the dietary compliance of 5 GSD-I patients at home over a period of 6 to 9 weeks prior to their GCRC admissions. These data suggested variable degrees of dietary control. In conclusion, the urinary lactate concentration is a useful parameter to monitor therapy of GSD-I patients at home. To be interpretable, the baseline urinary lactate concentration in relation to the blood lactate concentration has to be determined.
Mol Genet Metab 2000 Jul
PMID:Urinary lactate excretion to monitor the efficacy of treatment of type I glycogen storage disease. 1092 73

Glycogen storage disease type 1 (GSD 1) comprises a group of autosomal recessive inherited metabolic disorders caused by deficiency of the microsomal multicomponent glucose-6-phosphatase system. Of the two known transmembrane proteins of the system, malfunction of the catalytic subunit (G6Pase) characterizes GSD 1a. GSD 1 non-a is characterized by defective microsomal glucose-6-phosphate or pyrophosphate/phosphate transport due to mutations in G6PT (glucose-6-phosphate translocase gene) encoding a microsomal transporter protein. Mutations in G6Pase and G6PT account for approximately 80 and approximately 20% of GSD 1 cases, respectively. G6Pase and G6PT work in concert to maintain glucose homeostasis in gluconeogenic organs. Whereas G6Pase is exclusively expressed in gluconeogenic cells, G6PT is ubiquitously expressed and its deficiency generally causes a more severe phenotype. Rapid confirmation of clinically suspected diagnosis of GSD 1, reliable carrier testing, and prenatal diagnosis are facilitated by mutation analyses of the chromosome 11-bound G6PT gene as well as the chromosome 17-bound G6Pase gene.
Mol Genet Metab 2001 Jun
PMID:Molecular genetics of type 1 glycogen storage disease. 1138 47

Danon disease ('lysosomal glycogen storage disease with normal acid maltase') is characterized by a cardiomyopathy, myopathy and variable mental retardation. Mutations in the coding sequence of the lysosomal-associated membrane protein 2 (LAMP-2) were shown to cause a LAMP-2 deficiency in patients with Danon disease. LAMP-2 deficient mice manifest a similar vacuolar cardioskeletal myopathy. In addition to the patient reports LAMP-2 deficiency in mice causes pancreatic, hepatocytic, endothelial and leucocyte vacuolation. LAMP-2 deficient mice represent a valuable animal model of Danon disease. They will further be used to study the exact role of LAMP-2 in autophagy and to analyse the consequences of an impaired autophagic pathway in various tissues.
Trends Mol Med 2001 Jan
PMID:Disease model: LAMP-2 enlightens Danon disease. 1142 88

Maturity-onset diabetes of the young (MODY), an autosomal dominant, early-onset form of type-2 diabetes, is caused by mutations in five different genes all leading to defect(s) in the pancreatic beta cell. However, some patients with this form of diabetes do not bear a mutation in any of the known (MODY1-MODY5) loci, a notion prompting the search for new MODY genes. Clinical and genetic data point toward a defect in beta cell function in the majority of patients with MODY, and partners of the glucose-sensing device are reasonable functional candidates. The high-capacity glucose transporter GLUT2 has the ideal kinetic features for performing this task. However, complete GLUT2 deficiency in humans leads to hepato-renal glycogenosis (Fanconi-Bickel syndrome), and heterozygous GLUT2 mutations apparently behave in a recessive manner. Furthermore, in the human beta cell GLUT1 mRNA is predominant when compared to GLUT2 and glucose influx appears to be largely mediated by this low-Km transporter. Thus, we looked for the presence of sequence variants by polymerase chain reaction and single-strand conformation polymorphism (PCR-SSCP) within the GLUT1 gene in 90 Italian pedigrees negative at the search for mutations in glucokinase (MODY2) and hepatocyte nuclear factor-1alpha (MODY3), the two genes responsible for about 60% of MODY cases in Italian children. We found three already described silent mutations and a new single base deletion in position -173 of the 5' regulatory region. The -173de1A variant, which was detected in the heterozygous or homozygous state in 30.8% of MODY patients examined and is located in a Nuclear Factor Y binding sequence, is not associated with hyperglycemia in affected relatives of MODY probands. In conclusion, it appears from these results that the glucose transporter gene GLUT1 is unlikely to play a major role in the etiology of MODY diabetes.
J Mol Med (Berl) 2001 Jun
PMID:Single-strand conformation polymorphism analysis of the glucose transporter gene GLUT1 in maturity-onset diabetes of the young. 1148 13

Glucose-6-phosphatase (G6Pase), an enzyme found mainly in the liver and the kidneys, plays the important role of providing glucose during starvation. Unlike most phosphatases acting on water-soluble compounds, it is a membrane-bound enzyme, being associated with the endoplasmic reticulum. In 1975, W. Arion and co-workers proposed a model according to which G6Pase was thought to be a rather unspecific phosphatase, with its catalytic site oriented towards the lumen of the endoplasmic reticulum [Arion, Wallin, Lange and Ballas (1975) Mol. Cell. Biochem. 6, 75--83]. Substrate would be provided to this enzyme by a translocase that is specific for glucose 6-phosphate, thereby accounting for the specificity of the phosphatase for glucose 6-phosphate in intact microsomes. Distinct transporters would allow inorganic phosphate and glucose to leave the vesicles. At variance with this substrate-transport model, other models propose that conformational changes play an important role in the properties of G6Pase. The last 10 years have witnessed important progress in our knowledge of the glucose 6-phosphate hydrolysis system. The genes encoding G6Pase and the glucose 6-phosphate translocase have been cloned and shown to be mutated in glycogen storage disease type Ia and type Ib respectively. The gene encoding a G6Pase-related protein, expressed specifically in pancreatic islets, has also been cloned. Specific potent inhibitors of G6Pase and of the glucose 6-phosphate translocase have been synthesized or isolated from micro-organisms. These as well as other findings support the model initially proposed by Arion. Much progress has also been made with regard to the regulation of the expression of G6Pase by insulin, glucocorticoids, cAMP and glucose.
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PMID:The glucose-6-phosphatase system. 1187 77

Glycogen storage disease type 1 (GSD-1), also known as von Gierke disease, is a group of autosomal recessive metabolic disorders caused by deficiencies in the activity of the glucose-6-phosphatase (G6Pase) system that consists of at least two membrane proteins, glucose-6-phosphate transporter (G6PT) and G6Pase. G6PT translocates glucose-6-phosphate (G6P) from cytoplasm to the lumen of the endoplasmic reticulum (ER) and G6Pase catalyzes the hydrolysis of G6P to produce glucose and phosphate. Therefore, G6PT and G6Pase work in concert to maintain glucose homeostasis. Deficiencies in G6Pase and G6PT cause GSD-1a and GSD-1b, respectively. Both manifest functional G6Pase deficiency characterized by growth retardation, hypoglycemia, hepatomegaly, kidney enlargement, hyperlipidemia, hyperuricemia, and lactic acidemia. GSD-1b patients also suffer from chronic neutropenia and functional deficiencies of neutrophils and monocytes, resulting in recurrent bacterial infections as well as ulceration of the oral and intestinal mucosa. The G6Pase gene maps to chromosome 17q21 and encodes a 36-kDa glycoprotein that is anchored to the ER by 9 transmembrane helices with its active site facing the lumen. Animal models of GSD-1a have been developed and are being exploited to delineate the disease more precisely and to develop new therapies. The G6PT gene maps to chromosome 11q23 and encodes a 37-kDa protein that is anchored to the ER by 10 transmembrane helices. A functional assay for the recombinant G6PT protein has been established, which showed that G6PT functions as a G6P transporter in the absence of G6Pase. However, microsomal G6P uptake activity was markedly enhanced in the simultaneous presence of G6PT and G6Pase. The cloning of the G6PT gene now permits animal models of GSD-1b to be generated. These recent developments are increasing our understanding of the GSD-l disorders and the G6Pase system, knowledge that will facilitate the development of novel therapeutic approaches for these disorders.
Curr Mol Med 2001 Mar
PMID:The molecular basis of type 1 glycogen storage diseases. 1189 41


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