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Query: EC:3.1.3.9 (
glucose-6-phosphatase
)
3,081
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Glucose-6-phosphate transport was investigated in rat or human liver microsomal vesicles using rapid filtration and light-scattering methods. Upon addition of glucose-6-phosphate, rat liver microsomes accumulated the radioactive tracer, reaching a steady-state level of uptake. In this phase, the majority of the accumulated tracer was glucose, but a significant intraluminal glucose-6-phosphate pool could also be observed. The extent of the intravesicular glucose pool was proportional with
glucose-6-phosphatase
activity. The relative size of the intravesicular glucose-6-phosphate pool (irrespective of the concentration of the extravesicular concentration of added glucose-6-phosphate) expressed as the apparent intravesicular space of the hexose phosphate was inversely dependent on
glucose-6-phosphatase
activity. The increase of hydrolysis by elevating the extravesicular glucose-6-phosphate concentration or temperature resulted in lower apparent intravesicular glucose-6-phosphate spaces and, thus, in a higher transmembrane gradient of glucose-6-phosphate concentrations. In contrast, inhibition of glucose-6-phosphate hydrolysis by vanadate, inactivation of
glucose-6-phosphatase
by acidic pH, or genetically determined low or absent
glucose-6-phosphatase
activity in human hepatic microsomes of patients suffering from
glycogen storage disease
type 1a led to relatively high intravesicular glucose-6-phosphate levels. Glucose-6-phosphate transport investigated by light-scattering technique resulted in similar traces in control and vanadate-treated rat microsomes as well as in microsomes from human patients with
glycogen storage disease
type 1a. It is concluded that liver microsomes take up glucose-6-phosphate, constituting a pool directly accessible to intraluminal
glucose-6-phosphatase
activity. In addition, normal glucose-6-phosphate uptake can take place in the absence of the
glucose-6-phosphatase
enzyme protein, confirming the existence of separate transport proteins.
...
PMID:Demonstration of a metabolically active glucose-6-phosphate pool in the lumen of liver microsomal vesicles. 915 6
Glycogen storage disease
type 1a (von Gierke disease, GSD 1a) is caused by the deficiency of microsomal
glucose-6-phosphatase
(
G6Pase
) activity which catalyzes the final common step of glycogenolysis and gluconeogenesis. The recent cloning of the
G6Pase
cDNA and characterization of the human
G6Pase
gene enabled the characterization of the mutations causing GSD 1a. This, in turn, allows the introduction of a noninvasive DNA-based diagnosis that provides reliable carrier testing and prenatal diagnosis. In this study, we report the biochemical and clinical characteristics as well as mutational analyses of 12 Israeli GSD 1a patients of different families, who represent most GSD 1a patients in Israel. The mutations,
G6Pase
activity, and glycogen content of 7 of these patients were reported previously. The biochemical data and clinical findings of all patients were similar and compatible with those described in other reports. All 9 Jewish patients, as well as one Muslim Arab patient, presented the R83C mutation. Two Muslim Arab patients had the V166G mutation which was not found in other patients' populations. The V166G mutation, which was introduced into the
G6Pase
cDNA by site-directed mutagenesis following transient expression in COS-1 cells, was shown to cause complete inactivation of the
G6Pase
. The characterization of all GSD 1a mutations in the Israeli population lends itself to carrier testing in these families as well as to prenatal diagnosis, which was carried out in 2 families. Since all Ashkenzai Jewish patients harbor the same mutation, our study suggests that DNA-based diagnosis may be used as an initial diagnostic step in Ashkenazi Jews suspected of having GSD 1a, thereby avoiding liver biopsy.
...
PMID:Glycogen storage disease type 1a in Israel: biochemical, clinical, and mutational studies. 933 55
Glycogen storage disease
type 1a (von Gierke disease, GSD-1A) is caused by the deficiency of microsomal
glucose-6-phosphatase
(
G6Pase
) activity which catalyzes the final common step of glycogenolysis and gluconeogenesis. The cloning of the
G6Pase
cDNA and characterization of the human
G6Pase
gene enabled the identification of the mutations causing GSD-1a. This, in turn, allows the development of non-invasive DNA-based diagnosis that provides reliable carrier testing and prenatal diagnosis. Here we report on two new mutations E110Q and D38V causing GSD-1a in two Hungarian patients. The analyses of these mutations by site-directed mutagenesis followed by transient expression assays demonstrated that E110Q retains 17% of
G6Pase
enzymatic activity while the D38V abolishes the enzymatic activity. The patient with the E110Q has G222R as his other mutation. G222R was also shown to preserve about 4% of the
G6Pase
enzymatic activity. Nevertheless, the patient presented with the classical severe symptomatology of the GSD-1a.
...
PMID:Two new mutations in the glucose-6-phosphatase gene cause glycogen storage disease in Hungarian patients. 935 38
We report the sequence of a human cDNA that encodes a 46 kDa transmembrane protein homologous to bacterial transporters for phosphate esters. This protein presents at its carboxy terminus the consensus motif for retention in the endoplasmic reticulum. Northern blots of rat tissues indicate that the corresponding mRNA is mostly expressed in liver and kidney. In two patients with
glycogen storage disease
type Ib, mutations were observed that either replaced a conserved Gly to Cys or introduced a premature stop codon. The encoded protein is therefore most likely the glucose 6-phosphate translocase that is functionally associated with
glucose-6-phosphatase
.
...
PMID:Sequence of a putative glucose 6-phosphate translocase, mutated in glycogen storage disease type Ib. 1009 5
The transport of glucose-6-phosphate (G6P), glucose, and orthophosphate into liver microsomes, isolated from six patients with various subtypes of type 1
glycogen storage disease
(
GSD
), was measured using a light-scattering method. We found that G6P, glucose, and phosphate could all cross the microsomal membrane, in four cases of type 1a
GSD
. In contrast, liver microsomal transport of G6P and phosphate was deficient in the
GSD
1b and 1c patients, respectively. These results support the involvement of multiple proteins (and genes) in
GSD
type 1. The results obtained with the light-scattering method are in accordance with conventional kinetic analysis of the microsomal
glucose-6-phosphatase
system. Therefore, this technique could be used to directly diagnose type 1b and 1c
GSD
.
...
PMID:Liver microsomal transport of glucose-6-phosphate, glucose, and phosphate in type 1 glycogen storage disease. 943 46
Glycogen-storage disease type 1 (GSD-1), also known as "von
Gierke
disease," is caused by a deficiency in microsomal
glucose-6-phosphatase
(
G6Pase
) activity. There are four distinct subgroups of this autosomal recessive disorder: 1a, 1b, 1c, and 1d. All share the same clinical manifestations, which are caused by abnormalities in the metabolism of glucose-6-phosphate (G6P). However, only GSD-1b patients suffer infectious complications, which are due to both the heritable neutropenia and the functional deficiencies of neutrophils and monocytes. Whereas
G6Pase
deficiency in GSD-1a patients arises from mutations in the
G6Pase
gene, this gene is normal in GSD-1b patients, indicating a separate locus for the disorder in the 1b subgroup. We now report the linkage of the GSD-1b locus to genetic markers spanning a 3-cM region on chromosome 11q23. Eventual molecular characterization of this disease will provide new insights into the genetic bases of G6P metabolism and neutrophil-monocyte dysfunction.
...
PMID:The gene for glycogen-storage disease type 1b maps to chromosome 11q23. 946 34
Deficiency of microsomal
glucose-6-phosphatase
(
G6Pase
), the key enzyme in glucose homeostasis, causes
glycogen storage disease
type 1a, an autosomal recessive disorder. Characterization of the transmembrane topology of
G6Pase
should facilitate the identification of amino acid residues contributing to the active site and broaden our understanding of the effects of mutations that cause
glycogen storage disease
type 1a. Using N- and C-terminal tagged
G6Pase
, we show that in intact microsomes, the N terminus is resistant to protease digestion, whereas the C terminus is sensitive to such treatment. Our results demonstrate that
G6Pase
possesses an odd number of transmembrane helices, with its N and C termini facing the endoplasmic reticulum lumen and the cytoplasm, respectively. During catalysis, a phosphoryl-enzyme intermediate is formed, and the phosphoryl acceptor in
G6Pase
is a His residue. Sequence alignment suggests that mammalian G6Pases, lipid phosphatases, acid phosphatases, and a vanadium-containing chloroperoxidase (whose tertiary structure is known) share a conserved phosphatase motif. Active-site alignment of the vanadium-containing chloroperoxidase and G6Pases predicts that Arg-83, His-119, and His-176 in
G6Pase
contribute to the active site and that His-176 is the residue that covalently binds the phosphoryl moiety during catalysis. This alignment also predicts that Arg-83, His-119, and His-176 reside on the same side of the endoplasmic reticulum membrane, which is supported by the recently predicted nine-transmembrane helical model for
G6Pase
. We have previously shown that Arg-83 is involved in positioning the phosphate during catalysis and that His-119 is essential for
G6Pase
activity. Here we demonstrate that substitution of His-176 with structurally similar or dissimilar amino acids inactivates the enzyme, suggesting that His-176 could be the phosphoryl acceptor in
G6Pase
during catalysis.
...
PMID:Transmembrane topology of glucose-6-phosphatase. 949 33
A 4-year-old German girl was diagnosed as having
glycogen storage disease
type la and showed no other marked symptoms except hepatomegaly. The
glucose-6-phosphatase
activity in the liver was approximately 1.5% to 5.0% of normal values, and molecular analysis revealed compound heterozygosity for R83C and the novel mutation N264K. This result indicates that there is a wide clinical variation of
glucose-6-phosphatase
deficiency. DNA analysis is helpful for confirmation of the diagnosis, as well as establishment of the genotype and phenotype correlation in
glycogen storage disease
type 1a.
...
PMID:A new mutation of the glucose-6-phosphatase gene in a 4-year-old girl with oligosymptomatic glycogen storage disease type 1a. 950 59
The microsomal
glucose-6-phosphatase
(
G6Pase
) complex regulates the final step in glucose production from glycogenolysis and gluconeogenesis.
Glycogen storage disease
type 1c (GSD-1c) results from deficient activity of the phosphate/ pyrophosphate transporter of this complex and is associated with neutropenia as well as hepatomegaly and hypoglycaemia. Using three affected subjects from a single highly consanguineous family, we have used homozygosity mapping to localise the gene responsible for GSD-1c to a 10.2 cM region on 11q23.3-24.2. The maximum lod score was 3.12. GSD-1c is therefore distinct from GSD-1a, which has been shown previously to be caused by mutations in the
G6Pase
gene on chromosome 17.
...
PMID:Localisation of the gene for glycogen storage disease type 1c by homozygosity mapping to 11q. 959 17
Glycogen storage disease
type la (GSD1a) is an autosomal recessive metabolic disorder caused by a deficiency in
glucose-6-phosphatase
(
G6Pase
). We analyzed the
G6Pase
genes of two unrelated Chinese families with GSD1a. DNA sequencing of all five exons and the exon-intron boundaries revealed a G T transversion at nucleotide 727 (727G-->T) in exon 5, which has previously been reported to cause abnormal splicing. In one family, the subject and her affected sister were confirmed to be homozygous for this mutation and their parents to be heterozygotes. In the other family, the proband was identified to be heterozygous for this mutation, and a novel mutation, the 341delG in exon 2, was identified. This mutation alters the reading frame and creates a stop codon TAA 15 codons downstream from the mutation, resulting in a truncated protein. Family studies revealed that the father was heterozygous for the 727G-->T mutation and that the mother was heterozygous for the 341delG mutation. This is the first time that the 727G T mutation has been found in Chinese patients or outside Japan. Since we only tested two GSD1a families and found 727G-->T in both, we believe that this mutation may also be prevalent in our local Chinese population. To investigate allele frequencies, we screened 385 Chinese healthy volunteers and found two asymptomatic carriers. Our findings suggest that the 727G-->T mutation is indeed prevalent in Hong Kong.
...
PMID:Glucose-6-phosphatase gene (727G-->T) splicing mutation is prevalent in Hong Kong Chinese patients with glycogen storage disease type 1a. 963 72
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