Robert Geddes

Molecular and metabolic heterogeneity of liver glycogen.

On refeeding after starvation, the resynthesis of rabbit-liver glycogen proceeds inhomogeneously and over-produces material of low molecular weight. The fate of radioactivity incorporated into glycogen from D-glucose-14C can be explained if glycogen of high molecular weight is synthesised on a protein backbone. Confirmation of this view is given by the effect upon glycogen of reagents that break disulphide bonds; these cause loss of the polysaccharide of high molecular weight. Buoyant densities of glycogens are found to be independent of molecular weight and even of extensive degradation. It is concluded that glycogen synthesis proceeds by two routes; one results in the production of polysaccharide of high molecular weight which has a protein backbone capable of forming disulphide bonds, and another results in the production of polysaccharide of low molecular weight which has either no protein backbone or a protein backbone that is incapable of forming disulphide bridges. Apart from size, the two species are physicochemically indistinguishable.

The structure of liver glycogen

It has recently been shown [ 1 ] that proteinbound glycogen may be synthesized in some in vitro experiments and the implications of these experiments have been very clearly stated by Whelan [2]. Since isolated glycogen can be shown to be of very large molecular size up to IO9 daltons [3] and its constituent b-particles are relatively small (approx. 10’ daltons [3]) it seemed unlikely that the very high molecular weight glycogen were synthesized on a single protein backbone. The protein involved would have to be of considerably greater size than any so far reported. It was therefore decided to study the effect of disulphide bond-breaking reagents upon the size-distribution of glycogen molecules.

Post-mortem degradation of glycogen.

Although glycogen is the most extensively studied of the polysaccharides of animal tissue there has been no previous investigation of the effect of post-mortem changes on the distribution of molecular sizes of glycogen in tissue. Available data has described the changes in the total glycogen content [l-3] . Further, two recent papers [4,5], examined the structure of a glycogen isolated from human autopsy material “within 2 hr of death” ((51 , p. 1366). It was therefore of great importance for the continuing study of “native” glycogen [6] , to investigate the changes which occur in tissue glycogen after death both with respect to total amount and also with respect to size distribution.

Glycogen of high molecular weight from mammalian muscle

Glycogen of high molecular weight has been isolated from mammalian muscle, in contrast to the material of low molecular weight commonly described. The large polysaccharide is similar to liver glycogen in the structure of its individual beta-particles and also, partially, in the mode of assembly into the gross alpha-particles. The large particles may be disrupted by 2-mercaptoethanol, but not to the same extent as their liver counterparts.

Post mortem glycogenolysis is a combination of phosphorolysis and hydrolysis

1. Glycogen, glucose, lactate and glycogen phosphorylase concentrations and the activities of glycogen phosphorylase a and acid 1,4-alpha-glucosidase were measured at various times up to 120 min after death in the liver and skeletal muscle of Wistar and gsd/gsd (phosphorylase b kinase deficient) rats and Wistar rats treated with the acid alpha-glucosidase inhibitor acarbose. 2. In all tissues glycogen was degraded rapidly and was accompanied by an increase in tissue glucose and lactate concentrations and a lowering of tissue pH. In the liver of Wistar and acarbose-treated Wistar rats and in the skeletal muscle of all rats glycogen loss proceeded initially very rapidly before slowing. In the gsd/gsd rat liver glycogenolysis proceeded at a linear rate throughout the incubation period. Over 120 min 60, 20 and 50% of the hepatic glycogen store was degraded in the livers of Wistar, gsd/gsd and acarbose-treated Wistar rats, respectively. All 3 types of rat degraded skeletal muscle glycogen at the same rate and to the same extent (82% degraded over 2 hr). 3. In Wistar rat liver and skeletal muscle glycogen phosphorylase was activated soon after death and the activity of phosphorylase a remained well above the zero-time level at all later time points, even when the rate of glycogenolysis had slowed significantly. Liver and skeletal muscle acid alpha-glucosidase activities were unchanged after death. 4. The decreased rate and extent of hepatic glycogenolysis in both the gsd/gsd and acarbose-treated rats suggests that this process is a combination of phosphorolysis and hydrolysis. 5. Glycogen was purified from Wistar liver and skeletal muscle at various times post mortem and its structure investigated. Fine structural analysis revealed progressive shortening of the outer chains of the glycogen from both tissues, indicative of random, lysosomal hydrolysis. Analysis of molecular weight distributions showed inhomogeneity in the glycogen loss; in both tissues high molecular weight glycogen was preferentially degraded. This material is concentrated in lysosomes of both skeletal muscle and liver. These results are consistent with a role for lysosomal hydrolysis in glycogen degradation.

Ordered synthesis and degradation of liver glycogen involving 2-amino-2-deoxy-d-glucose

The incorporation of 2-amino-2-deoxy-D-glucose from precursor 2-amino-2-deoxy-D-galactose into liver glycogen has been shown to be a metabolically inhomogeneous process after starvation. The protein-to-polysaccharide ratio is also heterogeneous with respect to molecular size, and enhanced overall as compared to normal glycogen. The results are discussed from the viewpoint of a molecular order in the synthesis and degradation of liver glycogen.

Heterogeneity of glycogen synthesis upon refeeding following starvation.

1. Starvation of rats for 40 hr decreased the body weight, liver weight and blood glucose concentration. The hepatic and skeletal muscle glycogen concentrations were decreased by 95% (from 410 mumol/g tissue to 16 mumol/g tissue) and 55% (from 40 mumol/g tissue to 18.5 mumol/g tissue), respectively. 2. Fine structural analysis of glycogen purified from the liver and skeletal muscle of starved rats suggested that the glycogenolysis included a lysosomal component, in addition to the conventional phosphorolytic pathway. In support of this the hepatic acid alpha-glucosidase activity increased 1.8-fold following starvation. 3. Refeeding resulted in liver glycogen synthesis at a linear rate of 40 mumol/g tissue per hr over the first 13 hr of refeeding. The hepatic glycogen store were replenished by 8 hr of refeeding, but synthesis continued and the hepatic glycogen content peaked at 24 hr (approximately 670 mumol/g tissue). 4. Refeeding resulted in skeletal muscle glycogen synthesis at an initial rate of 40 mumol/g tissue per hr. The muscle glycogen store was replenished by 30 min of refeeding, but synthesis continued and the glycogen content peaked at 13 hr (approximately 50 mumol/g tissue). 5. Both liver and skeletal muscle glycogen synthesis were inhomogeneous with respect to molecular size; high molecular weight glycogen was initially synthesised at a faster rate than low molecular weight glycogen. These observations support suggestions that there is more than a single site of glycogen synthesis.

The structure of placental glycogen

Glycogen was purified from human term placenta and its structural features investigated. The beta-amylolysis limit and average chain lengths indicated that some degradation of the glycogen had occurred prior to its extraction. The sedimentation coefficient distribution of the purified glycogen showed that it contained a significant proportion of aggregated material. Diffusion coefficient measurements allowed calculation of the molecular weight distribution. The placental glycogen contained a significant proportion of high molecular weight material, although not as much as liver or skeletal muscle glycogens. Because the high molecular weight glycogen of liver and skeletal muscle is associated with the lysosome it is likely that this is also true of the large placental glycogen. Lysosomal glycogen is degraded hydrolytically to glucose and so placental glycogen may be involved in fetal glucose homeostasis.

Metabolic heterogeneity in rabbit brain glycogen

Glycogen has been carefully isolated from rabbit brain tissue and found to be of significantly greater molecular size (up to approx. 100 MDa) and heterogeneity than previously reported. The incorporation of radioisotope from glucose, pyruvate or acetate precursor has been shown to be non-uniform, being similar to the metabolic inhomogeneity observed in other tissues. Physicochemical studies have shown the gross hydrodynamic structure of the glycogen to be inhomogeneous and to differ significantly from that of liver glycogen.

Studies on native glycogen. 2. observations on metabolic inhomogeneity

Abstract 1. 1. Glycogen has been isolated from rabbit livers and fractionated both by conventional centrifugation and by zonal centrifugation. 2. 2. The presence of metabolically inhomogeneous material was shown both by the effect of starvation upon sedimentation coefficient distributions and by uneven incorporation of radioactive glucose into glycogen. 3. 3. The inhomogeneity appears to be a function of the synthesis but not the degradation of glycogen.