Gene/Protein
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Enzyme
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Gene/Protein
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Target Concepts:
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Query: EC:3.1.3.16 (
calcineurin
)
17,112
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Glycogen-bound
protein phosphatase
G from rat liver was transferred from glycogen to beta-cyclodextrin (cycloheptaamylose) linked to Sepharose 6B. After removal of the catalytic subunit and of contaminating proteins with 2 M NaCl, elution with beta-cyclodextrin yielded a single protein on native polyacrylamide gel electrophoresis and two polypeptides (161 and 54 kDa) on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Several lines of evidence indicate that the latter polypeptides are subunits of the
protein phosphatase
G holoenzyme. First, these polypeptides were also present, together with the catalytic subunit, in the extensively purified holoenzyme. Also, polyclonal antibodies against these polypeptides were able to bind the holoenzyme. Further, while bound to cyclodextrin-Sepharose, the polypeptides were able to recombine with separately purified type-1 (AMD) catalytic subunit, but not with type-2A (PCS) catalytic subunit. The characteristics of the reconstituted enzyme resembled those of the nonpurified
protein phosphatase
G. At low dilutions, the spontaneous phosphorylase phosphatase activity of the reconstituted enzyme was about 10 times lower than that of the catalytic subunit, but it was about 1000-fold more resistant to inhibition by the modulator protein (inhibitor-2). In contrast with the free catalytic subunit, the reconstituted enzyme co-sedimented with glycogen, and it was able to activate purified
liver glycogen synthase
b. Also, the synthase phosphatase activity was synergistically increased by a cytosolic phosphatase and inhibited by physiological concentrations of phosphorylase alpha and of Ca2+.
...
PMID:Purification and characterization of the glycogen-bound protein phosphatase from rat liver. 189 24
The prominent protein phosphatases involved in liver glycogen metabolism are the AMD (ATP, Mg-dependent, type-1) and PCS (polycation-stimulated, type-2A) phosphatases. The glycogen synthase phosphatase activity, measured from the rate of activation of
liver glycogen synthase
, is virtually accounted for by AMD phosphatases; the bulk of the activity belongs to the glycogen-bound
protein phosphatase
G and a small part is present in the cytosol. The major part of the phosphorylase phosphatase activity present in the post-mitochondrial supernatant is shared by
protein phosphatase
G and cytosolic enzymes, and a minor part belongs to a microsomal AMD phosphatase. In the liver cytosol, the phosphorylase phosphatase activity is about equally distributed between AMD and PCS phosphatases. Studies in vivo as well as on isolated, perfused livers have shown that glucagon (which raises the level of cyclic AMP) as well as vasopressin (which increases the cytosolic Ca2+ concentration) decrease the phosphorylase phosphatase activity in liver extract or cytosol (filtered through Sephadex G-25) by about 25% within a few minutes. These effects were not additive, and the activity of glycogen synthase phosphatase was not affected. Conversely, insulin as well as glucose increased both phosphatase activities by about 25%, and these effects were additive. Vanadate mimicked the effect of insulin on the perfused liver. All the activity changes were only observed when the assays were performed at high tissue concentration. Upon subcellular fractionation all the effects were well expressed in the cytosol, but not in the particulate fraction (glycogen and microsomes). However, quantitatively the hormonal responses were largely lost during the fractionation procedure; they could be restored by recombination of the liver cytosol from a hormone-treated rat with the particulate fraction from either a treated or an untreated animal. It appears that the effects of glucagon, insulin and glucose are mediated by cytosolic, transferable effectors of the Vmax of protein phosphatases. These effectors are eluted in the void volume of a Sephadex G-25 column. Rats of the gsd/gsd strain, which have a genetic deficiency of hepatic phosphorylase kinase, responded to an injection of insulin plus glucose with a normal increase in the cytosolic phosphorylase phosphatase activity. In contrast, they failed to respond to glucagon as well as vasopressin. A transient 80% inhibition of the phosphorylase phosphatase activity could be induced in vitro in a concentrate liver cytosol from Wistar rats upon addition of MgATP.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Short-term hormonal control of protein phosphatases involved in hepatic glycogen metabolism. 216 98
Liver glycogen synthase activity is increased, and glycogen phosphorylase activity and glucose 6-phosphate content reduced by in vivo insulin during a euglycemic hyperinsulinemic clamp in lean young adult rhesus monkeys. To examine the mechanism of dephosphorylation of
liver glycogen synthase
and glycogen phosphorylase, the enzyme activities of
protein phosphatase-1
,
protein phosphatase-2C
, cAMP-dependent protein kinase, glycogen synthase kinase-3, protein kinase C and protein tyrosine kinase were determined before and after three hours of in vivo insulin in these same monkeys. The bioactivity of an inositol phosphoglycan insulin mediator (pH 2.0) and cAMP concentrations were also measured in the liver before and after insulin administration. Insulin caused significant increases in
protein phosphatase-1
(p = 0.005) and in
protein phosphatase-2C
activities (p = 0.001). Insulin-stimulated minus basal bioactivity of the pH 2.0 insulin mediator was strongly inversely related to the insulin-stimulated minus basal glucose 6-phosphate content (r = -0.93, p < 0.0001). These findings suggest that
protein phosphatase-1
and
protein phosphatase-2C
may be involved in the mechanism of in vivo insulin activation of
liver glycogen synthase
and inactivation of liver glycogen phosphorylase.
...
PMID:Insulin increases liver protein phosphatase-1 and protein phosphatase-2C activities in lean, young adult rhesus monkeys. 993 Jun 26
Glucokinase (GK, hexokinase type IV) is required for the accumulation of glycogen in adult liver and hepatoma cells. Paradoxically, mammalian embryonic livers store glycogen successfully in the absence of GK. Here we address how mammalian embryonic livers, but not adult livers or hepatoma cells, manage to accumulate glycogen in the absence of this enzyme. Hexokinase type I or II (HKI, HKII) substitutes for GK in hepatomas and in embryonic livers. We engineered FTO2B cells, a hepatoma cell line in which GK is not expressed, to unveil the modifications required to allow them to accumulate glycogen. In the light of these results, we then examined glycogen metabolism in embryonic liver. Glycogen accumulation in FTO2B cells can be triggered through elevated expression of HKI or either of the
protein phosphatase
1 regulatory subunits, namely PTG or G L. Between these two strategies to activate glycogen deposition in the absence of GK, embryonic livers choose to express massive levels of HKI and HKII. We conclude that although the GK/
liver glycogen synthase
tandem is ideally suited to store glycogen in liver when blood glucose is high, the substitution of HKI for GK in embryonic livers allows the HKI/
liver glycogen synthase
tandem to make glycogen independently of the glucose concentration in blood, although it requires huge levels of HK. Moreover, the physiological consequence of the HK isoform switch is that the embryonic liver safeguards its glycogen deposits, required as the main source of energy at birth, from maternal starvation.
...
PMID:Hepatic glycogen synthesis in the absence of glucokinase: the case of embryonic liver. 1816 36
The liver responds to an increase in blood glucose levels in the postprandial state by uptake of glucose and conversion to glycogen. Liver glycogen synthase (
GYS2
), a key enzyme in glycogen synthesis, is controlled by a complex interplay between the allosteric activator glucose-6-phosphate (G6P) and reversible phosphorylation through glycogen synthase kinase-3 and the glycogen-associated form of
protein phosphatase
1. Here, we initially performed mutagenesis analysis and identified a key residue (Arg(582)) required for activation of
GYS2
by G6P. We then used
GYS2
Arg(582)Ala knockin (+/R582A) mice in which G6P-mediated
GYS2
activation had been profoundly impaired (60-70%), while sparing regulation through reversible phosphorylation. R582A mutant-expressing hepatocytes showed significantly reduced glycogen synthesis with glucose and insulin or glucokinase activator, which resulted in channeling glucose/G6P toward glycolysis and lipid synthesis.
GYS2
(+/R582A) mice were modestly glucose intolerant and displayed significantly reduced glycogen accumulation with feeding or glucose load in vivo. These data show that G6P-mediated activation of
GYS2
plays a key role in controlling glycogen synthesis and hepatic glucose-G6P flux control and thus whole-body glucose homeostasis.
...
PMID:Glucose-6-phosphate-mediated activation of liver glycogen synthase plays a key role in hepatic glycogen synthesis. 2399 Mar 65
