Fetal lung development in rats with a glycogen storage disorder.

A New Zealand strain of rats (NZR/Mh) is unable to mobilize liver glycogen due to a deficiency of phosphorylase b kinase. Affected homozygous rats (gsd/gsd) were used to assess the developmental relationship between lung glycogen loss and surfactant phospholipid and protein biosynthesis. Phosphorylase a and phosphorylase b kinase activities were negligible in gsd/gsd fetal lungs compared with controls from gestational day (D18) until postnatal day 1 (D + 1). At D20, tissue glycogen content was 158 +/- 5 and 181 +/- 6 mumol/g lung for control and gsd/gsd, respectively. Control rats mobilized 84% of their lung glycogen by D + 1, whereas the gsd/gsd strain retained 70-80% of D19-20 levels. This apparent fall in gsd/gsd glycogen per gram lung was due to an increase in cellular protein and size. Thus, in controls, total glycogen per lung decreased 65% from D20 to D + 1, whereas DNA doubled. In contrast, gsd/gsd lung growth resulted in a doubling of total lung glycogen, whereas the glycogen-to-DNA ratio remained constant. A lack of cellular glycogenolysis was confirmed by electron microscopy where gsd/gsd type II cells remained large and glycogen-rich over the entire perinatal interval. The potential for glycogen breakdown by a lysosomal alpha-amyloglucosidase in gsd/gsd lungs was estimated in tissue homogenates, whereas rates of hydrolysis of glycogen or p-nitrophenylglucoside were significant and equal to controls at all ages tested. Incorporation of [14C]choline into phosphatidylcholine (PC) of incubated lung slices increased 1.7-fold in control lungs from D20-D21. Over the same interval, PC synthesis in gsd/gsd lungs was 40% lower and did not change.(ABSTRACT TRUNCATED AT 250 WORDS)

The action of adenosine in relation to that of insulin on the low-Km cyclic AMP phosphodiesterase in rat adipocytes.

The adenosine-sensitive cyclic AMP phosphodiesterase of rat adipocytes was found to reside in the same subcellular fraction as the enzyme sensitive to insulin. There were several similarities between the action of adenosine and that of insulin on the enzyme. The action of adenosine on the phosphodiesterase is probably like that of insulin, both being receptor-mediated, although different sites or different receptors could be involved. Adenosine analogues with intact ribose but a modified purine moiety elicited a response similar to that of adenosine. Added Ca2+ was also not a requirement for the action of adenosine. The action of adenosine was not synergistic with that of insulin, neither was adenosine essential for insulin action. Insulin stimulated the enzyme even at low cell concentrations and in the presence of adenosine deaminase. Adenosine, however, enhanced the effect of insulin, but only at insulin concentrations that produced submaximal effects. Thus the mechanisms of action could be similar or related. The time-course effect of a suboptimal concentration of insulin was transitory, like that of adenosine, and was influenced by the presence of adenosine, whereas that of a maximally effective concentration of insulin was sustained for at least 20 min and was not affected by the presence of adenosine. Isoprenaline enhanced phosphodiesterase activity stimulated by optimal concentrations of either adenosine or insulin, suggesting that their effects were mediated through different mechanisms of action.

Blood glucose homeostasis in rats with a deficiency of liver phosphorylase kinase.

The glycogen storage disorder (gsd/gsd) rat has little or no phosphorylase kinase activity in the liver and is unable to break down liver glycogen on fasting. Nevertheless, gsd/gsd rats do not become hypoglycaemic on fasting. Gsd/gsd rats showed a decreased rate of glucose turnover measured with [6-3H]glucose. Perfused livers from gsd/gsd rats showed decreased rates of gluconeogenesis from lactate and alanine when the results were expressed per gram of liver, but the total glucose produced per liver was normal. Measurement of gluconeogenesis in vivo using [14C]-bicarbonate showed that gsd/gsd rats had a decreased rate of glucose production from substrates that enter the gluconeogenic pathway before pyruvate. We conclude that gsd/gsd rats have adapted to unavailability of liver glycogen by decreasing peripheral uptake of glucose and not by increasing gluconeogenesis.

The action of anoxia and cyanide on glycogen breakdown in the liver of the gsd/gsd rat.

Perfusion of normal rat livers under anoxic conditions or the addition of KCN to aerobic perfusions activated phosphorylase and stimulated glycogen breakdown and glucose output. Livers from rats with a deficiency of liver phosphorylase kinase (gsd/gsd) showed a much smaller activation of phosphorylase with anoxia or KCN and produced glucose at about half the rate of normal livers. The increase in phosphorylase a in gsd/gsd livers was insufficient to account for the increase in glucose output. The addition of KCN to normal hepatocytes, activated phosphorylase and stimulated glucose output almost as effectively as glucagon. Hepatocytes from gsd/gsd rats showed only a very small increase in phosphorylase a on the addition of KCN, and glucose output did not increase. We conclude that in the perfused liver, anoxia and KCN stimulate glycogen breakdown and glucose output, at least in part, by a mechanism that does not involve conversion of phosphorylase b to phosphorylase a. In isolated hepatocytes KCN stimulates glucose output only by increasing the content of phosphorylase a.

Formation of cyclic AMP from exogenous ATP by isolated hepatocytes and adipocytes.

Suspensions of isolated rat hepatocytes and adipocytes converted exogenous ATP to cyclic AMP at a rate which was about 30--50% of that observed with homogenates of isolated cells. Formation of cyclic AMP was stimulated by hormones (isoprenaline in the case of adipose tissue and glucagon in the case of liver) and sodium fluoride. Experiments with [alpha-32P]ATP indicated that the conversion of exogenous ATP to cyclic AMP did not occur within the cells. It is proposed that in isolated hepatocytes ad adipocytes some catalytic units of adenylate cyclase are exposed on the outer surface of the cell membrane.

The adenylate cyclase activity of isolated hepatocytes actions of glucagon and sodium fluoride.

Isolated hepatocytes converted exogenous [alpha-32P]ATP to cyclic [32P]AMP at high rates. This system was used for kinetic studies of the effects of glucagon, fluoride, free magnesium and free ATP4- on adenylate cyclase. In the absence or presence of glucagon, free Mg2+ activated adenylate cyclase by decreasing the Km for MgATP2- without changing V. Free ATP4- was not a potent inhibitor of adenylate cyclase and the only effect of glucagon was to increase V. Fluoride also increased the V of adenylate cyclase, but, in contrast to the results obtained with glucagon, the effect increased as the concentration of free Mg2+ increased. One explanation of the effect of fluoride, consistent with the idea that free Mg2+ activates adenylate cyclase and free ATP is not an inhibitor, is that fluoride increases the affinity of the enzyme for Mg2+. Weak inhibition of adenylate cyclase by ATP4- in the presence of fluoride cannot be excluded.

Glycogen-storage disease in rats, a genetically determined deficiency of liver phosphorylase kinase.

Rats from an inbred strain (NZR/Mh) were found to have high concentrations of glycogen in their livers, even after 24 h of starvation. Despite this, blood glucose concentrations were well maintained on starvation for up to 72 h. The primary defect is a deficiency of liver phosphorylase kinase, causing a lack of active glycogen phosphorylase, although total phosphorylase is normal. The intravenous injection of glucagon caused a rapid activation of cyclic AMP-dependent protein kinase in the liver, but no increase in either phosphorylase kinase or phosphorylase a activity. Although total glycogen synthase activity in the livers of affected rats was higher than normal, glycogen synthase in the active form was very low, presumably as a result of the high liver glycogen content. The condition is transmitted as autosomal recessive and, apart from hepatomegaly, the affected rats appear healthy.

An effect of insulin on adipose-tissue adenosine 3':5'-cyclic monophosphate phosphodiesterase.

1. 3':5'-Cyclic nucleotide phosphodiesterase activity was measured in homogenates prepared from epididymal fat-pads and isolated fat-cells incubated in the absence and presence of insulin. 2. Homogenates of insulin-treated tissues showed an increase in phosphodiesterase activity compared with controls. No effect of insulin was observed when the hormone was added directly to homogenates. 3. There was kinetic evidence for the presence of two 3':5'-cyclic nucleotide phosphodiesterases in adipose tissue. Insulin raised the maximal velocity of the low-K(m) enzyme and lowered the K(m) of the higher-K(m) enzyme. 4. It is suggested that the effect of insulin on adipose tissue phosphodiesterase accounts for the ability of this hormone to lower cyclic-AMP concentration in the tissue.