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Enzyme
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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)
Because P(i) deprivation markedly affects the Na/P(i) co-transporter in kidney and has been related to insulin resistance and glucose intolerance, the effect of a P(i)-deficient diet on the liver microsomal
glucose-6-phosphatase
(
G6Pase
) system was investigated. Rats were fed with a control diet (+P(i)) or a diet deficient in phosphate (-P(i)) for 2 days and killed on the morning of the third day, after an overnight fast (fasted) or not (fed). Kinetic parameters of P(i) transport (t((1/2)) and equilibration) into liver microsomes were not changed by the different nutritional conditions. In contrast, it was found that
G6Pase
activity was significantly increased in the (-P(i)) groups. This was due to an increase in the V(max) of the enzyme, without change in the K(m) for G6P. There was no correlation between liver microsomal glycogen content and
G6Pase
activity, but both protein abundance and mRNA of liver 36 kDa catalytic subunit of
G6Pase
(p36) were increased. The mRNA of the putative G6P translocase protein (
p46
) was changed in parallel with that of the catalytic subunit, but the
p46
immunoreactive protein was unchanged. These findings indicate that dietary P(i) deficiency causes increased
G6Pase
activity by up-regulation of the expression of the 36 kDa-catalytic-subunit gene.
...
PMID:Up-regulation of liver glucose-6-phosphatase in rats fed with a P(i)-deficient diet. 1051 Mar 5
The effect of streptozocin diabetes on the expression of the catalytic subunit (p36) and the putative glucose-6-phosphate translocase (
p46
) of the
glucose-6-phosphatase
system (G6Pase) was investigated in rats. In addition to the documented effect of diabetes to increase p36 mRNA and protein in the liver and kidney, a approximately 2-fold increase in the mRNA abundance of
p46
was found in liver, kidney, and intestine, and a similar increase was found in the
p46
protein level in liver. In HepG2 cells, glucose caused a dose-dependent (1-25 mM) increase (up to 5-fold) in p36 and
p46
mRNA and a lesser increase in
p46
protein, whereas insulin (1 microM) suppressed p36 mRNA, reduced
p46
mRNA level by half, and decreased
p46
protein by about 33%. Cyclic AMP (100 microM) increased p36 and
p46
mRNA by >2- and 1.5-fold, respectively, but not
p46
protein. These data suggest that insulin deficiency and hyperglycemia might each be responsible for up-regulation of G6Pase in diabetes. It is concluded that enhanced hepatic glucose output in insulin-dependent diabetes probably involves dysregulation of both the catalytic subunit and the putative glucose-6-phosphate translocase of the liver G6Pase system.
...
PMID:Diabetes affects similarly the catalytic subunit and putative glucose-6-phosphate translocase of glucose-6-phosphatase. 1056 46
The catalytic subunit (p36) and putative glucose-6-phosphate (G6P) transporter (
p46
) protein levels of the rat
glucose-6-phosphatase
(
G6Pase
) system were studied in relation to
G6Pase
hydrolytic activity and G6P uptake in liver microsomes during the fetal to neonatal period. The mean G6P hydrolytic activity in liver microsomes increased significantly from the 20th to 21st day of gestation (from 6 to 22 mU/mg protein) and was further enhanced by 3-fold 6 hours after birth, with a maximal activity at 1 day of age (112 mU/mg protein). In contrast, G6P uptake into the vesicles was undetectable before birth, appeared after day 1 (656 pmol/mg protein), and decreased after day 2 (about 330 pmol/mg protein). Immunoblot analysis showed that the mean p36 protein level was low (< 1.6 arbitrary units [AU]) during gestation, increased sharply (to about 4.0 AU) during the first day, and remained stable afterward. Unlike p36,
p46
protein was present before birth at values comparable to those postpartum. P46 increased from 3.2 AU at 20 days to 4.6 AU at 21 days of gestation, and decreased transiently after birth. These results show that (1)
G6Pase
hydrolytic activity before birth can occur without detectable G6P uptake function; (2) the presence of the putative G6P transporter protein is not sufficient to elicit G6P uptake; and (3) full
G6Pase
activity requires optimal expression of both p36 and
p46
proteins. These data are discussed in relation to the function of
G6Pase
.
...
PMID:Ontogeny of the catalytic subunit and putative glucose-6-phosphate transporter proteins of the rat microsomal liver glucose-6-phosphatase system. 1101 4
High-fat (HFD) and high-sucrose diets (HSD) reduce insulin suppression of glucose production in vivo, increase the capacity for gluconeogenesis in vitro, and increase
glucose-6-phosphatase
(
G-6-Pase
) activity in whole cell homogenates. The present study examined the effects of HSD and HFD on in vivo gluconeogenesis, the catalytic and glucose-6-phosphate translocase subunits of
G-6-Pase
, glucokinase (GK) translocation, and glucose cycling. Rats were fed a high-starch control diet (STD; 68% cornstarch), HSD (68% sucrose), or HFD (45% fat) for 7-13 days. The ratio of 3H in C6:C2 of glucose after 3H2O injection into 6- to 8-h-fasted rats was significantly increased in HSD (0.68 +/- 0.07) and HFD (0.71 +/- 0.08) vs. STD (0.40 +/- 0.10).
G-6-Pase
activity was significantly higher in HSD and HFD vs. STD in both intact and disrupted liver microsomes. HSD and HFD significantly increased the amount of the p36 catalytic subunit protein, whereas the
p46
glucose-6-phosphate translocase protein was increased in HSD only. Despite increased nonglycerol gluconeogenesis and increased
G-6-Pase
, basal glucose and insulin levels as well as glucose production were not significantly different among groups. Hepatocyte cell suspensions were used to ascertain whether diet-induced adaptations in glucose phosphorylation and GK might serve to compensate for upregulation of
G-6-Pase
. Tracer-estimated glucose phosphorylation and glucose cycling (glucose <--> glucose 6-phosphate) were significantly higher in cells isolated from HSD only. After incubation with either 5 or 20 mM glucose and no insulin, GK activity (nmol. mg protein(-1). min(-1)) in digitonin-treated eluates (translocated GK) was significantly higher in HSD (32 +/- 4 and 146 +/- 6) vs. HFD (4 +/- 1 and 83 +/- 10) and STD (9 +/- 2 and 87 +/- 9). Thus short-term, chronic exposure to HSD and HFD increase in vivo gluconeogenesis and the
G-6-Pase
catalytic subunit. Exposure to HSD diet also leads to adaptations in glucose phosphorylation and GK translocation.
...
PMID:Diets enriched in sucrose or fat increase gluconeogenesis and G-6-Pase but not basal glucose production in rats. 1216 48
We previously showed that a phosphate-deficient diet resulting in hypophosphatemia upregulated the catalytic subunit p36 of rat liver
glucose-6-phosphatase
, which is responsible for hepatic glucose production. A possible association between phosphate and glucose homeostasis was now further evaluated in the Hyp mouse, a murine homologue of human X-linked hypophosphatemia. We found that in the Hyp mouse as in the dietary Pi deficiency model, serum insulin was reduced while glycemia was increased, and that liver
glucose-6-phosphatase
activity was enhanced as a consequence of increased mRNA and protein levels of p36. In contrast, the Hyp model had decreased mRNA and protein levels of the putative glucose-6-phosphate translocase
p46
and liver cyclic AMP was not increased as in the phosphate-deficient diet rats. It is concluded that in genetic as in dietary hypophosphatemia, elevated glucose-6-phosphatase activity could be partially responsible for the impaired glucose metabolism albeit through distinct mechanisms.
...
PMID:Up-regulation of liver glucose-6-phosphatase in x-linked hypophosphatemic mice. 1217 68
