Identification of binding sites on protein targeting to glycogen for enzymes of glycogen metabolism

The activation of protein phosphastase-1 (PP1) by insulin plays a critical role in the regulation of glycogen metabolism. PTG is a PP1 glycogen-targeting protein, which also binds the PP1 substrates glycogen synthase, glycogen phosphorylase, and phosphorylase kinase (Printen, J. A., Brady, M. J., and Saltiel, A. R. (1997) Science 275, 1475-1478). Through a combination of deletion analysis and site-directed mutagenesis, the regions on PTG responsible for binding PP1 and its substrates have been delineated. Mutagenesis of Val-62 and Phe-64 in the highly conserved (K/R)VXF PP1-binding motif to alanine was sufficient to ablate PP1 binding to PTG. Phosphorylase kinase, glycogen synthase, and phosphorylase binding all mapped to the same C-terminal region of PTG. Mutagenesis of Asp-225 and Glu-228 to alanine completely blocked the interaction between PTG and these three enzymes, without affecting PP1 binding. Disruption of either PP1 or substrate binding to PTG blocked the stimulation of PP1 activity in vitro against phosphorylase, indicating that both binding sites may be important in PTG action. Transient overexpression of wild-type PTG in Chinese hamster ovary cells overexpressing the insulin receptor caused a 50-fold increase in glycogen levels. Expression of PTG mutants that do not bind PP1 had no effect on glycogen accumulation, indicating that PP1 targeting is essential for PTG function. Likewise, expression of the PTG mutants that do not bind PP1 substrates did not increase glycogen levels, indicating that PP1 targeting glycogen is not sufficient for the metabolic effects of PTG. These results cumulatively demonstrate that PTG serves as a molecular scaffold, allowing PP1 to recognize its substrates at the glycogen particle.     

Determination of glycogen and enzymes of glycogen metabolism in human hair follicles

The skin epithelium and its organelles use glycogen as well as glucose as source of energy. Therefore the characterisation of glycogen metabolism and the enzymes involved is important in the study of mechanisms regulating the normal or abnormal differentiation of skin organelles such as sebaceous glands and hair follicles.The present paper describes fluorimetric methods for the determination of glycogen and for the measurements of phosphorylase and phosphorylase kinase activity in one and the same lysate of minute tissue samples. The methods were tested for their suitability on freshly isolated human hair follicles and cultured hair follicle cells. The possible use of these techniques for studies on the pathophysiology of acne and hirsutism is discussed.     

Supercomputer analysis of purine and pyrimidine metabolism leading to DNA synthesis

A model-system is established to analyze purine and pyrimidine metabolism leading to DNA synthesis. The principal aim is to explore the flow and regulation of terminal deoxynucleoside triophosphates (dNTPs) in various input and parametric conditions. A series of flow equations are established, which are subsequently converted to differential equations. These are programmed (Fortran) and analyzed on a Cray X-MP/48 supercomputer. The pool concentrations are presented as a function of time in conditions in which various pertinent parameters of the system are modified. The system is formulated by 100 differential equations.     

Enzyme activity during the metabolism of glycogen

Summary Phosphorylase activities were investigated by histochemical and ultrastructural procedures in the electroreceptive sensory cells of the tuberous organ of Gnathonemus petersii.After incubation in G1P, G1P activated by AMP (Takeuchi and Kuriaki medium) or in G1P activated by ATP+MgSO₄ (Guha and Wegman medium) newly formed polysaccharides were analysed with the iodine and P.A.S. reactions under light microscopy and, under electron microscopy, with the periodic acid thiocarbohydrazide (TCH) silver proteinate (PATAg reaction, Thiery), The newly formed polysaccharides proved the presence of glycogen phosphorylase (2.4.1.1) activities and of their branching enzymes (2.4.1.18). When G1P was activated by ATP+MgSO₄, they appeared as glycogen particles with the same constitution as native glycogen. After incubation in G1P and in G1P activated by AMP they appeared as glycogen and polyglucose filaments too. In the latter case they were high concentrated. The results show that the phosphorylases are principally present in this sensory cell in their inactive form.     

Supercomputer analysis of purine and pyrimidine metabolism leading to DNA synthesis

A model-system is established to analyze purine and pyrimidine metabolism leading to DNA synthesis. The principal aim is to explore the flow and regulation of terminal deoxynucleoside triophosphates (dNTPs) in various input and parametric conditions. A series of flow equations are established, which are subsequently converted to differential equations. These are programmed (Fortran) and analyzed on a Cray chi-MP/48 supercomputer. The pool concentrations are presented as a function of time in conditions in which various pertinent parameters of the system are modified. The system is formulated by 100 differential equations.     

Analysis of the molecular pathophysiology of sleep disorders relevant to a disturbed biological clock

Genetic studies have revealed several clock gene variations/mutations involved in the manifestation of sleep disorders or interindividual differences in sleep–wake patterns, but only part of the genetic risk can be explained by the gene variations/mutations identified to date. Recent progress in research into circadian rhythm generation has provided efficient tools for eliciting the molecular basis of clock-relevant sleep disorders, complementing traditional genetic analysis. While the human master clock resides in the suprachiasmatic nucleus of the hypothalamus (central clock), peripheral tissue cells also generate self-sustained circadian oscillations of clock gene expression (peripheral clock), enabling estimation of individual human clock properties through a single collection of skin fibroblasts or venous blood cells. Some of the established cell lines exhibit autonomous circadian oscillations of clock gene expression, and introduction of clock gene variations into these cell lines by gene targeting makes it possible to investigate changes in the circadian phenotype induced by these variations/mutations without the need for generating transgenic animals. Estimation of human clock properties using peripheral tissue cells, in addition to genetic analysis, will facilitate comprehensive explication of the genetic risk of a variety of disorders relevant to biological clock disturbances, including sleep disorders, mood disorders, and metabolic diseases.     

Impaired myocardial autophagy linked to energy metabolism disorders

Autophagy represents an evolutionarily conserved catabolic mechanism that promotes cell survival by releasing energy substrates via degradation of cellular constituents and by eliminating defective organelles under conditions of stress, such as starvation and hypoxia. The link between enhanced autophagy and nutrient deprivation has been well established. For example, chronic myocardial ischemia, a condition of insufficient oxygen and nutrition, activates autophagy to degrade and recycle damaged cellular structures, thereby ameliorating cardiomyocyte injury.     

Impaired myocardial autophagy linked to energy metabolism disorders

Autophagy represents an evolutionarily conserved catabolic mechanism that promotes cell survival by releasing energy substrates via degradation of cellular constituents and by eliminating defective organelles under conditions of stress, such as starvation and hypoxia. The link between enhanced autophagy and nutrient deprivation has been well established. For example, chronic myocardial ischemia, a condition of insufficient oxygen and nutrition, activates autophagy to degrade and recycle damaged cellular structures, thereby ameliorating cardiomyocyte injury.     

The influence of lysosomes on glycogen metabolism.

Treatment of rabbit spermatozoa with 50mM-MgCl2 removes the plasma and the outer acrosomal membranes. Subsequent treatment with the detergents Hyamine 2389 and Triton X-100 solubilizes spermatozoal neuraminidase bound to the inner acrosomal membrane. The enzyme was further purified by DEAE-cellulose, Sephadex G-150 and Bio-Gel P-300 column chromato. The enzyme showed a single major band, with the possibility of some minor contaminants, on disc-gel electrophoresis. It had a specific activity of 0.37 micronmal of sialic acid released/min per mg with purified boar Cowper's-gland mucin as the substrate. The enzyme had marked specificity for 2 leads to 6'-linked sialic acid in glycoproteins. The Km of spermatozoal neuraminidase was 1.72 X 10(-6)M with Cowper's-gland mucin, 1.17 X 10(-5)M with fetuin and 8.8 X 10(-4)M with sialyl-lactose as a substrates. The Vmax. was 0.112 micronmol/min per mg with the Cowper's-gland mucin, 0.071 micronmol/min per mg with fetuin and 0.033 micronmol/min per mg with sialyl-lactose as substrate. The enzyme hydrolysed sheep submaxillary-gland mucin as readily as the Cowper's-gland mucin. The optimum of enzyme activity was at pH 5.0 on the Cowper's-gland mucin and at pH4.3 on sialyl-lactose. The enzyme activity was unaffected by 20mM-Na+ and-K+, but was inhibited by 20mM-Ca2+,-Mn2+,-Co2+ and -Cu2+. The enzyme was unstable in dilute solutions, but could be stored indefinitely freeze-dried at --20 degrees C.