Studies on the cytophysiology of the fat body of the American silkmoth

Summary A developmental study at the electron microscopic level was conducted of the fat body cells of Hyalophora cecropia (L.). During the last larval instar the fat body increases in volume and the cells exhibit a well developed rough endoplasmic reticulum and protein bodies of diverse sizes. In the pupal fat body, the protein bodies appear to be enclosed by a double membrane and contain glycogen granules, ribosomes and mitochondrion-like structures. In addition, there are large lipid globules, cytolysomes and rough endoplasmic reticulum. The ultrastructure of the protein bodies suggests the development of large bodies by fusion of smaller protein bodies. Changes in fat body cell ultrastructure were followed during adult development and cytological evidence was obtained for the depletion of protein, glycogen and lipid in the female during this period. The female adult fat body cell contains free ribosomes, protein bodies, many mitochondria, a few lipid globules and glycogen granules. The male moth fat body cells have many mitochondria, a few glycogen granules, essentially no protein bodies, but an abundance of large lipid globules.Studies on the influence of egg maturation on the morphology of the fat body of Hyalophora gloveri (L.) revealed that ovariectomy of pupae yielded adults having more fat body than normal females, and that the fat body cells of the ovariectomized animals contained more glycogen, lipid and protein. Male pupae receiving ovarian implants developed into adults containing eggs and possessed more fat body than normal females but less than normal males. Very few glycogen granules were found in the fat body cells of normal males or males with implanted ovaries.Supported by grant AM-02818 from the National Institutes of Health.We thank Dr. James Oschman for his helpful suggestions and constructive criticisms.     

Autophagy of metabolically inert substances injected into fibroblasts in culture

We have examined the morphologic characteristics of fibroblasts cultured from the beige mouse, a genetic variant phenotypically similar to human Chediak-Higashi syndrome (CHS). These cultured fibroblasts are characterized by large, amorphous dense body inclusions in their cytoplasm, often as large as the cell nucleus. Using time-lapse video phase-contrast microscopy, we have observed the formation of these large dense bodies through fusion of relatively normal-appearing lysosomes in the beige mouse fibroblast. After formation of these large inclusions, cells occasionally extruded the contents of these structures through apparent fusion with the plasma membrane and rapid exocytosis. Fibroblasts cultured from normal black mice showed no evidence of fusion between lysosomes or exocytosis of lysosomes. However, the uptake of extracellular medium through macropinocytosis, subsequent actions of lysosomes on these macropinosomes through saltatory motion, cellular migration and ruffling activity appeared normal in beige mouse fibroblasts. Immunocytochemical localization of α₂-macroglobulin, a normal serum protein commonly incorporated into lysosomes in cultured fibroblasts by receptor-mediated endocytosis, showed that the large dense bodies contained α₂-macroglobulin, in keeping with their lysosomal origin. This suggested further that receptor-mediated endocytosis in these cells was relatively normal. In addition, light and electron microscopic cytochemistry showed these large inclusions to be acid-phosphatase positive, further characterizing them as lysosomal. The electron microscopic appearance of these dense inclusions was consistent with their origin through repeated fusion of lysosomes. It is suggested that a primary defect in this disease may be the ability of mature lysosomal membranes to fuse, unlike normal lysosomal membranes, indicating perhaps an alteration in some specific component of the lysosomal membranes in CHS.     

Genetic Depletion of the Malin E3 Ubiquitin Ligase in Mice Leads to Lafora Bodies and the Accumulation of Insoluble Laforin

Approximately 90% of cases of Lafora disease, a fatal teenage-onset progressive myoclonus epilepsy, are caused by mutations in either the EPM2A or the EPM2B genes that encode, respectively, a glycogen phosphatase called laforin and an E3 ubiquitin ligase called malin. Lafora disease is characterized by the formation of Lafora bodies, insoluble deposits containing poorly branched glycogen or polyglucosan, in many tissues including skeletal muscle, liver, and brain. Disruption of the Epm2b gene in mice resulted in viable animals that, by 3 months of age, accumulated Lafora bodies in the brain and to a lesser extent in heart and skeletal muscle. Analysis of muscle and brain of the Epm2b^−/− mice by Western blotting indicated no effect on the levels of glycogen synthase, PTG (type 1 phosphatase-targeting subunit), or debranching enzyme, making it unlikely that these proteins are targeted for destruction by malin, as has been proposed. Total laforin protein was increased in the brain of Epm2b^−/− mice and, most notably, was redistributed from the soluble, low speed supernatant to the insoluble low speed pellet, which now contained 90% of the total laforin. This result correlated with elevated insolubility of glycogen and glycogen synthase. Because up-regulation of laforin cannot explain Lafora body formation, we conclude that malin functions to maintain laforin associated with soluble glycogen and that its absence causes sequestration of laforin to an insoluble polysaccharide fraction where it is functionally inert.     

Calmodulin-dependent glycogen synthase kinase: Identification in liver of normal and phosphorylase kinase-deficient rats

We have purified a calmodulin-dependent glycogen synthase kinase from livers of normal and phosphorylase kinase-deficient (gsd/gsd) rats. No differences between normal and gsd/gsd rats were apparent in either (a) the ability of liver extracts to phosphorylate exogenous glycogen synthase in a Ca²⁺- and calmodulin-dependent manner or (b) the purification of the calmodulin-dependent synthase kinase. Although extracts from rat liver, when compared to rabbit liver extracts, had a significantly reduced ability to phosphorylate exogenous synthase, the calmodulin-dependent synthase kinase could be purified from rat liver using a protocol identical to that described for rabbit liver. Moreover, the synthase kinase purified from rat liver had properties very similar to those of the rabbit liver enzyme. The enzyme was completely dependent on calmodulin for activity against glycogen synthase, was unable to phosphorylate phosphorylase b, catalyzed the rapid incorporation of 0.4 mol phosphate/mol of glycogen synthase subunit, selectively phosphorylated sites 1b and 2 in the glycogen synthase molecule, had a Stokes' radius of about 70 Å, and appeared to be composed of subunits of M_r 56,000 and 57,000. These observations led us to conclude that (1) calmodulin-dependent glycogen synthase kinase is distinct from other kinases previously described and (2) the rat liver kinase and the rabbit liver kinase are very similar enzymes.     

Accumulation of Free Oligosaccharides and Tissue Damage in Cytosolic α-Mannosidase (Man2c1)-deficient Mice

Free Man_7–9GlcNAc₂ is released during the biosynthesis pathway of N-linked glycans or from misfolded glycoproteins during the endoplasmic reticulum-associated degradation process and are reduced to Man₅GlcNAc in the cytosol. In this form, free oligosaccharides can be transferred into the lysosomes to be degraded completely. α-Mannosidase (MAN2C1) is the enzyme responsible for the partial demannosylation occurring in the cytosol. It has been demonstrated that the inhibition of MAN2C1 expression induces accumulation of Man_8–9GlcNAc oligosaccharides and apoptosis in vitro. We investigated the consequences caused by the lack of cytosolic α-mannosidase activity in vivo by the generation of Man2c1-deficient mice. Increased amounts of Man_8–9GlcNAc oligosaccharides were recognized in all analyzed KO tissues. Histological analysis of the CNS revealed neuronal and glial degeneration with formation of multiple vacuoles in deep neocortical layers and major telencephalic white matter tracts. Enterocytes of the small intestine accumulate mannose-containing saccharides and glycogen particles in their apical cytoplasm as well as large clear vacuoles in retronuclear position. Liver tissue is characterized by groups of hepatocytes with increased content of mannosyl compounds and glycogen, some of them undergoing degeneration by hydropic swelling. In addition, lectin screening showed the presence of mannose-containing saccharides in the epithelium of proximal kidney tubules, whereas scattered glomeruli appeared collapsed or featured signs of fibrosis along Bowman''s capsule. Except for a moderate enrichment of mannosyl compounds and glycogen, heterozygous mice were normal, arguing against possible toxic effects of truncated Man2c1. These findings confirm the key role played by Man2c1 in the catabolism of free oligosaccharides.     

Electron microscope studies of Fasciola hepatica. XI. Autophagy and parenchymal cell function

An electron microscope study of the function of parenchymal cells in Fasciola hepatica in relation to glycogen storage and metabolism was undertaken.Although no evidence of a relationship between morphological changes in parenchymal cells and glycogen was apparent, a correlation between glycogen depletion and autophagy was observed. The autophagic process started with the synthesis and “budding off” of membranes by mitochondria to form small vesicles (M bodies), either of a simple type (limited by a single membrane) or a complex type (limited by two or more membranes). These M bodies fused to form narrow, smooth cisternae (SCM), which wrapped around areas of cytoplasm containing glycogen; this process gave rise to β bodies. The β bodies (autophagosomes) were at first irregular in shape and limited by two or more membranes separated by a space of varied width. Older β bodies became more smooth and oval in outline and were limited by a single membrane due to membrane fusion. Primary lysosomes synthesized by the GER-GA system united with the late β bodies and formed secondary lysosomes (autolysosomes). Following the addition of these lysosomal hydrolases, the glycogen content of the autolysosomes was reduced and eventually disappeared. This resulted in the develpment of residual bodies containing unhydrolysed material in the form of dense granules, tubules, and myelin figures in a matrix of varied density.It was concluded that at least some glycogen in the parenchymal cells of F. hepatica is mobilized by autophagy. All the morphological structures observed in the experimental material were also present in controls, although in fewer numbers, and it is believed that autophagy is a normal process in this fluke.     

Muscle Glycogen Remodeling and Glycogen Phosphate Metabolism following Exhaustive Exercise of Wild Type and Laforin Knockout Mice

Glycogen, the repository of glucose in many cell types, contains small amounts of covalent phosphate, of uncertain function and poorly understood metabolism. Loss-of-function mutations in the laforin gene cause the fatal neurodegenerative disorder, Lafora disease, characterized by increased glycogen phosphorylation and the formation of abnormal deposits of glycogen-like material called Lafora bodies. It is generally accepted that the phosphate is removed by the laforin phosphatase. To study the dynamics of skeletal muscle glycogen phosphorylation in vivo under physiological conditions, mice were subjected to glycogen-depleting exercise and then monitored while they resynthesized glycogen. Depletion of glycogen by exercise was associated with a substantial reduction in total glycogen phosphate and the newly resynthesized glycogen was less branched and less phosphorylated. Branching returned to normal on a time frame of days, whereas phosphorylation remained suppressed over a longer period of time. We observed no change in markers of autophagy. Exercise of 3-month-old laforin knock-out mice caused a similar depletion of glycogen but no loss of glycogen phosphate. Furthermore, remodeling of glycogen to restore the basal branching pattern was delayed in the knock-out animals. From these results, we infer that 1) laforin is responsible for glycogen dephosphorylation during exercise and acts during the cytosolic degradation of glycogen, 2) excess glycogen phosphorylation in the absence of laforin delays the normal remodeling of the branching structure, and 3) the accumulation of glycogen phosphate is a relatively slow process involving multiple cycles of glycogen synthesis-degradation, consistent with the slow onset of the symptoms of Lafora disease.     

Long-term acrylamide intoxication induces atrophy of dorsal root ganglion A-cells and of myelinated sensory axons

We have examined the effects of acrylamide on primary sensory nerve cell bodies and their myelinated axons in chronic acrylamide intoxication. The numbers and sizes of dorsal root ganglion cell bodies (L5) and myelinated nerve fibers were estimated with sterelogical techniques in severely disabled rats which had been treated with 33.3 mg/kg acrylamide twice a week for 7.5 weeks. There was no loss of dorsal root ganglion cells or myelinated nerve fibers in the roots, the sciatic nerve, sural nerve, and a tibial nerve branch. The mean perikaryal volume of A-cells was reduced by 20% (2P < 0.001) from 50000 μm³ in controls (CV = 0.13) to 40000 μm³ (0.12), whereas B-cell volume was unchanged. All size-frequency distribution curves of myelinated axon area of peripheral nerves and sensory roots were shifted to the left towards smaller values in rats exposed to acrylamide. In the L5 sensory root 3 mm from the ganglion, there was a significant reduction of mean cross sectional area of myelinated axons by 14% (2P < 0.05) from 7.6 μm² (0.11) in controls to 6.5 μm² (0.13) in intoxicated rats. The mean cross sectional area of myelinated sural nerve axons was reduced by 22% (2P < 0.001) from 8.6 μm² (0.08) in controls to 6.7 μm² (0.17) in intoxicated rats. We conclude that chronic intoxication with acrylamide leads to selective atrophy of type A dorsal root ganglion cell bodies and simultaneous atrophy along their peripheral axons, whereas neuronal B-cell bodies and motor axons are spared. It is suggested that the neuronal atrophy might well represent a defect of neurofilament synthesis and transport.     

Regulation of glycogen metabolism in the adrenal gland. IV. The effect of insulin on glycogen synthetase, phosphorylase, and related metabolites

Previous studies have indicated that the glycogen content of adrenal glands of fasted rats can be depleted by insulin per se (Bindstein, E., Piras, R., and Piras, M. M., Endocrinology88, 223, 1971). In order to establish the mechanism of action of this hormone in the adrenal gland, the effect of insulin has been now investigated on glycogen synthetase (UDP-glucose: α-1,4 glucan α-4-glueosyl-transferase, EC 2.4.1.11), glycogen phosphorylase (α-1,4 glucan: orthophosphate glucosyl-transferase, EC 2.4.1.1) and metabolites related to these enzymes.Approximately 40% of total adrenal glycogen phosphorylase of fasted rats is in the active form, which increases to 75% 1 hr after insulin treatment (75 mU/100 g body wt). This conversion occurs without apparent large changes of 3′-5′ cyclic AMP. Concomitantly with the enzymatic change, the levels of glucose-6-P, UDP-glucose and P_i suffer alterations which favor an increased phosphorolytic activity during the first hour of insulin treatment. Glycogen synthetase, which did not change during this period, is converted to the glucose-6-P independent form during the 2–3 hr of treatment. This conversion is preceded by an increased glycogen synthetase phosphatase activity, which seems to follow an inverse relationship with the glycogen level.The results obtained suggest that the effect of insulin on the adrenal gland of fasted rats is glycogenolytic, that is, opposite to that described for this hormone in other normal tissues. The glycogen depletion, on the other hand, seems to set in motion the mechanism for glycogen synthetase activation, with the subsequent glycogen resynthesis.     

Selective damage in striatum and hippocampus with in vitro anoxia

An in vitro model of anoxia-induced brain damage was utilized to help elucidate the biochemical basis of cell damage due to reduced oxygen availability. Previous studies suggest that anoxia-induced damage may vary presynaptically, post-synaptically or in the cell body. Thus, the consequences of an anoxic treatment incubation were examined with hippocampal slices, which contain cholinergic nerve terminals but not cell bodies, and with slices from whole striatum or its subregions, which contain both cholinergic cell bodies and nerve terminals. Slices were preincubated with either oxygen or nitrogen (treatment incubation) and the persistent effects of this treatment on [¹⁴C]acetylcholine and¹⁴CO₂ production from [U-¹⁴C]glucose were assessed in a subsequent incubation under optimal conditions (test incubation). An anoxic treatment incubation reduced the subsequent test incubation production of CO₂ about 40% in the hippocampus and striatum, The anoxic treatment incubation diminished ACh production by 46% in the striatum, but only minimally affected that in the hippocampus. Anoxic treatment incubations of synaptosomes did not alter test-incubation ACh synthesis or CO₂ production. Omission of calcium from the anoxic treatment incubation increased striatal ACh synthesis by 88% and CO₂ production in both regions. These results suggest that anoxia produces persistent changes in postsynaptic processes or cell bodies (in this model cholinergic ones) that differ from those in nerve terminals and that calcium is important in the production of these deficits.     

Glucose Metabolism in Rat Retinal Pigment Epithelium

The retinal pigment epithelium (RPE) is the major transport pathway for exchange of metabolites and ions between choroidal blood supply and the neural retina. To gain insight into the mechanisms controlling glucose metabolism in RPE and its possible relationship to retinopathy, we studied the influence of different glucose concentrations on glycogen and lactate levels and CO₂ production in RPE from normal and streptozotocin-treated diabetic rats. Incubation of normal RPE in the absence of glucose caused a decrease in lactate production and glycogen content. In normal RPE, increasing glucose concentrations from 5.6 mM to 30 mM caused a four-fold increase in glucose accumulation and CO₂ yield, as well as reduction in lactate and glycogen production. In RPE from diabetic rats glucose accumulation did not increase in the presence of high glucose substrate, but it showed a four- and a seven-fold increase in CO₂ production through the mitochondrial and pentose phosphate pathways, respectively. We found high glycogen levels in RPE which can be used as an energy reserve for RPE itself and/or neural retina. Findings further show that the RPE possesses a high oxidative capacity. The large increase in glucose shunting to the pentose phosphate pathway in diabetic retina exposed to high glucose suggests a need for reducing capacity, consistent with increased oxidative stress.     

Cytophotometric analysis of glycogen,protein and DNA of a glycogen-storing rat hepatoma (N13) cell line

This study examines the behavior of glycogenstoring rat hepatoma (N13) in vitro using cytophotometric techniques. A significant increase in glycogen is observed in these cells after 30 min incubation in a buffered solution containing 0.1 mM glucose, that is 80 times lower than the physiological glucose concentration in rat blood. N13 hepatoma cells grow exponentially in culture using RPMI 1640 tissue culture medium supplemented with 10% fetal bovine serum. During the first day in culture these cells store a large amount of glycogen and this increase is also observed in serum-free cultures. In more prolonged cultures the amount of glycogen per cell gradually becomes lower, although the culturing conditions are maintained. Similar variations of protein are also observed during the initial period of culture. DNA distribution does not show significant changes, although in serum-free cultures an increase in the proportion of cells in S and G₂/M phases is observed. The addition of glucagon, epinephrine and cyclic AMP derivatives to serum-free cultures does not impede the storage of glycogen. Nevertheless, addition of either 2 mM N⁶,O²-dibutyryl cyclic AMP or 0.1 mM 8-(4-chlorophenylthio)-cyclic AMP blocks the cell cycle at G₀/G₁ and glycogen content does not decrease after the first day in culture. We believe that this cell line offers an appropriated model to study glycogen metabolism and its involvement in the neoplastic process.     

Segregation of Ferritin in Glomerular Protein Absorption Droplets

Ferritin was used as a tracer to study the mechanism by which proteins are segregated into droplets by the visceral epithelium of glomerular capillaries. In glomeruli from both normal and aminonucleoside-nephrotic rats ferritin molecules introduced into the general circulation penetrated the endothelial openings and were seen at various levels in the basement membrane. Striking differences between nephrotic and controls were seen only in the amount of ferritin incorporated into the epithelium. In normal animals, a few ferritin molecules were seen in small invaginations of the cell membrane limiting the foot processes, within minute vesicles in the epithelium, or within occasional large vacuoles and dense bodies. In nephrotics, epithelial pinocytosis was marked, and numerous ferritin molecules were seen within membrane invaginations and in small cytoplasmic vesicles at all time points. After longer intervals, the concentration of ferritin increased in vacuoles and particularly within the dense bodies or within structures with a morphology intermediate between that of vacuoles and dense bodies. In nephrotic animals cleft-like cavities or sinuses were frequently encountered along the epithelial cell surface facing the urinary spaces. Some of these sinuses contained material resembling that filling the dense bodies except that it appeared less compact. The findings suggest that ferritin molecules—and presumably other proteins which penetrate the basement membrane—are picked up by the epithelium in pinocytotic vesicles and transported via the small vesicles to larger vacuoles which are subsequently transformed into dense bodies by progressive condensation. The content of the dense bodies may then undergo partial digestion and be extruded into the urinary spaces where it disperses. The activity of the glomerular epithelium in the incorporation and segregation of protein is similar in normal and nephrotic animals, except that the rate is considerably higher in nephrosis where the permeability of the glomerular basement membrane is greatly increased.     

Analysis of carbohydrate storage granules in the diazotrophic cyanobacterium Cyanothece sp. PCC 7822

The unicellular diazotrophic cyanobacteria of the genus Cyanothece demonstrate oscillations in nitrogenase activity and H₂ production when grown under 12 h light–12 h dark cycles. We established that Cyanothece sp. PCC 7822 allows for the construction of knock-out mutants and our objective was to improve the growth characteristics of this strain and to identify the nature of the intracellular storage granules. We report the physiological and morphological effects of reduction in nitrate and phosphate concentrations in BG-11 media on this strain. We developed a series of BG-11-derived growth media and monitored batch culture growth, nitrogenase activity and nitrogenase-mediated hydrogen production, culture synchronicity, and intracellular storage content. Reduction in NaNO₃ and K₂HPO₄ concentrations from 17.6 and 0.23 to 4.41 and 0.06 mM, respectively, improved growth characteristics such as cell size and uniformity, and enhanced the rate of cell division. Cells grown in this low NP BG-11 were less complex, a parameter that related to the composition of the intracellular storage granules. Cells grown in low NP BG-11 had less polyphosphate, fewer polyhydroxybutyrate granules and many smaller granules became evident. Biochemical analysis and transmission electron microscopy using the histocytochemical PATO technique demonstrated that these small granules contained glycogen. The glycogen levels and the number of granules per cell correlated nicely with a 2.3 to 3.3-fold change from the minimum at L0 to the maximum at D0. The differences in granule morphology and enzymes between Cyanothece ATCC 51142 and Cyanothece PCC 7822 provide insights into the formation of large starch-like granules in some cyanobacteria.     

Production and stabilization of cells of Bacillus popilliae and Bacillus lentimorbus

Bacillus popilliae and B. lentimorbus grew most rapidly and to the greatest extent in aerated cultures at 30 to 32 C with oxygen absorption rates of 1 mmole of O₂ per min per liter, or above. The control of pH also increased the maximal populations attained. Media were developed which consistently produced cell populations of about 10⁹ within 24 to 48 hr in aerated cultures of these two species. The acetic acid produced in highly aerated cultures was shown not to be responsible for the rapid loss of cell viability in stationary phase cultures. However, H₂O₂ was very lethal to cells of B. popilliae, and this species is known to have the capacity to produce it. Stationary-phase cells were partially stabilized by reducing the availability of oxygen after 24 hr of incubation on a shaker, and the addition of low levels of glucose further stabilized the cells. The most stable cells were those produced in a medium in which 4% Trypticase (BBL) and 0.1% barbituric acid were incorporated. A high percentage of these cells contained refractile bodies visible under a phase microscope. Although these bodies were not heat-resistant and lacked other characteristics of endospores, cells in cultures containing them had reasonably high viability for extended periods, as compared with those in control cultures.     

Accumulation,mobilization and turn-over of glycogen in the blue-green bacterium Anacystis nidulans

1. Accumulation of glycogen up to a constant amount per cell was observed during the post-exponential phase of growth, in the presence of an excess of a utilizable carbon source. Cell multiplication was reproducibly controlled by growth of the organism in a nitrogen-limiting medium under photoautotrophic conditions (presence of light, air plus CO₂).
2. Temporary starvation, i.e. by removal of light or by the addition to an illuminated culture of DCMU, 3-(3′,4′-dichlorophenyl)-1,1′-dimethylurea, a specific inhibitor of photosystem II, lead to a mobilization of glycogen in the cell. Furthermore, Anacystis nidulans, having accumulated glycogen by virtue of preculture under nitrogen-limiting conditions, will resume cell division when the culture medium is complemented with a nitrogen source. The ability of the organism to use glycogen as an endogenous carbon source for growth was observed by addition of a nitrogen source to nitrogen-starving cells and simultaneous removal of CO₂.
3. During the period of constant amount of glycogen per cell the reserve polysaccharide was subject to turnover as demonstrated with a pulse chase-labelling technique. The demonstration of a turnover—for the first time with a bacterial species—indicated a strict balance in the relative rate of synthesis and degradation.

     

De novo synthesis of Escherichia coli glycogen is due to primer associated with glycogen synthase and activation by branching enzyme.

Previous reports have demonstrated the incorporation of glucose from ADP-glucose into methanol-insoluble and TCA-insoluble fractions in cell extracts of Escherichia coli in the absence of added primer α-glucan. This activity is reduced 6- to 76-fold in cell extracts of three independently isolated glycogen synthase-deficient mutants of E. coli B. Homogeneous preparations of E. coli B glycogen synthase catalyze incorporation of glucose into both methanol- and TCA-insoluble fractions in the absence of added primer. Since glycogen synthase catalyzes these reactions, it is not necessary to propose a protein acceptor glucose or a unique ADP-glucose-glycosyl transferase to catalyze formation of the glucoprotein in E. coli cell extracts to explain glucose incorporation into TCA-insoluble material (R. Barengo et al. (1975) FEBS Lett.53, 274–278). The incorporation of glucose into methanol-and TCA-insoluble fractions is stimulated by 0.25 m citrate and by branching enzyme. Citrate reduces the K_m for the primer, glycogen, about 11- to 15-fold. Branching enzyme can also reduce the concentration of primer required for incorporation of glucose into methanol-insoluble material. The simultaneous presence of both 0.25 m citrate and branching enzyme enables the glycogen synthase reaction rate to proceed at 30% the maximal velocity at a primer concentration of 1 μg/ml. Incorporation of glucose into methanol- or TCA-insoluble material in the absence of primer is completely inhibited by adding α-amylase. Furthermore, incorporation into methanol- or TCA-insoluble material is reduced 13- to 16-fold relative to the reaction occurring in the presence of primer when glycogen synthase is pretreated with glucoamylase and α-amylase. Previous results show that homogeneous preparations of glycogen synthase contain glucan. Heat-denatured glucogen synthase can act as a primer for the glycogen phosphorylase and glycogen synthase reactions. Both the TCA- and methanol-insoluble products form I₂-glucan complexes with wavelength maxima of about 580–590 nm and 610–615 nm, respectively, suggesting that they are mainly linear chain glucans. The products are completely solubilized with α-amylase. The TCA-insoluble product is not solubilized by pronase treatment. The above results strongly suggest that previous reports on formation of glucoprotein primer for glycogen synthesis or on de novo glycogen synthesis in various similar systems is due to endogenous glucan associated with glycogen synthase rather than formation of glucoprotein which then acts as primer for glycogen synthesis.