Regulation of glycogen metabolism in liver by the autonomic nervous system. VI. Possible mechanism of phosphorylase activation by the splanchnic nerve.

The effects of autonomic-nerve stimulation on the activities of phosphorylase (EC 2.4.1.1), dephospho-phosphorylase kinase (EC 2.7.1.38) and phosphorylase phosphatase (EC 3.1.3.17), and on the concentration of adenosine 3', 5'-monophosphate in rabbit liver were investiaged. Results were compared with the effects of epinephrine and glucagon on these enzymes. 1. The acitivity of liver phosphorylase increased rapidly and markedly on electrical stimulation of the splanchnic nerve, or after intraportal administration of epinephrine or glucagon. The activity was not affected by vagal stimulation. 2. The activity of dephospho-phosphorylase kinase increased about 2--3-fold 1 min after injections of epinephrine and glucagon, glucagon causing more activation than epinephrine. The enzyme activity was not altered by splanchnic-nerve, or vagal stimulation. 3. Injections of epinephrine and glucagon caused marked elevation of liver adenosine 3', 5'-monophosphate within a few minutes. With epinephrine, the nucleotide concentration rose to a maximum after 1 min and amounted to about 3-fold increase, while with glucagon the maximum increase of approximately 8-fold increase was observed after 2 min. Stimulation of the splanchnic nerve for 10 min did not affect the adenosine 3', 5'-monophosphate level in the liver. Vagal stimulation also had no effect on the level. 4. The activity of phosphorylase phosphatase decreased promptly (within 30 s) and markedly on splanchnic-nerve stimulation, but did not change significantly on administration of epinephrine of glucagon. A small but insignificant increase in phosphatase activity wasobserved upon vagal stimulation. 5. The effect of Ca-2+ on purified dephospho-phosphorylase kinase was studied. The activity was found to depend partially on free Ca-2+ at low Ca-2+ concentrations (1-10-minus 7--1-10-minus 5 M). 6. These results suggest that the rise in hepatic phosphorylase content upon splanchnic-nerve stimulation, unlike that induced by epinephrine and glucagon, is not mediated by adenosine 3', 5'-monophosphate and subsequent activation of dephospho-phosphorylase kinase, but rather by inactivation of phosphorylase phosphatase. The possible existence of a new factor in this mechanism is discussed.     

Regulation of glycogen metabolism in the liver and hepatic glycogenosis due to phosphorylase system deficiency]

Glycogen synthesis and breakdown in the liver are tightly controlled through different mechanisms. The purpose of this review is to describe some properties of the enzymes involved in the glycogen metabolism and the sequence of events by which glucose, allosteric effectors and hormones control this metabolism in the liver. Clinical, genetic and biological aspects of the phosphorylase and the phosphorylase kinase deficiencies are examined. The enzymatic analysis of the haemolysates from the patients allows discrimination of these two types of glycogenosis.     

The role of the autonomic nervous liver innervation in the control of energy metabolism

Despite a longstanding research interest ever since the early work by Claude Bernard, the functional significance of autonomic liver innervation, either sympathetic or parasympathetic, is still ill defined. This scarcity of information not only holds for the brain control of hepatic metabolism, but also for the metabolic sensing function of the liver and the way in which this metabolic information from the liver affects the brain. Clinical information from the bedside suggests that successful human liver transplantation (implying a complete autonomic liver denervation) causes no life threatening metabolic derangements, at least in the absence of severe metabolic challenges such as hypoglycemia. However, from the benchside, data are accumulating that interference with the neuronal brain–liver connection does cause pronounced changes in liver metabolism. This review provides an extensive overview on how metabolic information is sensed by the liver, and how this information is processed via neuronal pathways to the brain. With this information the brain controls liver metabolism and that of other organs and tissues. We will pay special attention to the hypothalamic pathways involved in these liver–brain–liver circuits. At this stage, we still do not know the final destination and processing of the metabolic information that is transferred from the liver to the brain. On the other hand, in recent years, there has been a considerable increase in the understanding which brain areas are involved in the control of liver metabolism via its autonomic innervation. However, in view of the ever rising prevalence of type 2 diabetes, this potentially highly relevant knowledge is still by far too limited. Thus the autonomic innervation of the liver and its role in the control of metabolism needs our continued and devoted attention.     

Regulation of cholesterol homeostasis by the liver X receptors in the central nervous system

The nuclear oxysterol receptors liver X receptor-alpha [LXRalpha (NR1H3)] and LXRbeta (NR1H2) coordinately regulate genes involved in cholesterol homeostasis. Although both LXR subtypes are expressed in the brain, their roles in this tissue remain largely unexplored. In this report, we show that LXR agonists have marked effects on gene expression in murine brain tissue both in vitro and in vivo. In primary astrocyte cultures, LXR agonists regulated several established LXR target genes, including ATP binding cassette transporter A1, and enhanced cholesterol efflux. In contrast, little or no effect on gene expression or cholesterol efflux was detected in primary neuronal cultures. Treatment of mice with a selective LXR agonist resulted in the induction of several LXR target genes related to cholesterol homeostasis in the cerebellum and hippocampus. These data provide the first evidence that the LXRs regulate cholesterol homeostasis in the central nervous system. Because dysregulation of cholesterol balance is implicated in central nervous system diseases such as Alzheimer's and Niemann-Pick disease, pharmacological manipulation of the LXRs may prove beneficial in the treatment of these disorders.     

Regulation of synthase phosphatase and phosphorylase phosphatase in rat liver.

Using substrates purified from liver, the apparent Km values of synthase phosphatase ([UDPglucose--glycogen glucosyltransferase-D]phosphohydrolase, EC 3.1.3.42) and phosphorylase phosphatase (phosphorylase a phosphohydrolase, EC 3.1.3.17) were found to be 0.7 and 60 units/ml respectively. The maximal velocity of phosphorylase phosphatase was more than a 100 times that of synthase phosphatase. In adrenalectomized, fasted animals there was a complete loss of synthase phosphatase but only a slight decrease in phosphorylase phosphatase when activity was measured using endogenous substrates in a concentrated liver extract. When assayed under optimal conditions with purified substrates, both activities were present but had decreased to very low levels. Mixing experiments indicated that synthase D present in the extract of adrenalectomized fasted animals was altered such that it was no longer a substrate for synthase phosphatase from normal rats. Phosphorylase a substrate on the other hand was unaltered and readily converted. When glucose was given in vivo, no change in percent of synthase in the I form was seen in adrenalectomized rats but the percent of phosphorylase in the a form was reduced. Precipitation of protein from an extract of normal fed rats with ethanol produced a large activation of phosphorylase phosphatase activity with no corresponding increase in synthase phosphatase activity. Despite the low phosphorylase phosphatase present in extracts of adrenalectomized fasted animals, ethanol precipitation increased activity to the same high level as obtained in the normal fed rats. Synthase phosphatase and phosphorylase phosphatase activities were also decreased in normal fasted, diabetic fed and fasted, and adrenalectomized fed rats. Both enzymes recovered in the same manner temporally after oral glucose administration to adrenalectomized, fasted rats. These results suggest an integrated regulatory mechanism for the two phosphatase.