Retention of glycogen in cryosubstituted mouse liver

A periodic acid-Schiff (PAS)-type reaction in which osmium-ammine was used as the reagent was carried out on ultrathin sections of mouse liver in order to study the extent to which glycogen is preserved. Comparisons were made between tissues that were, on the one hand, conventionally fixed and dehydrated and, on the other, those that were high-pressure frozen and cryosubstituted in acetone. A control was carried out for both groups using a routine uranyl acetate-lead citrate staining procedure. In the latter case, glycogen could be identified as electron-clear patches in the cytoplasm whereas after a PAS-type reaction, glycogen became darkly contrasted. In the case of conventionally fixed samples, glycogen appeared to display a certain amount of clumping separated by gaps whereas in cryosubstituted specimens it was denser and often showed elongated interconnecting structures. These results suggest that cryofixation and cryosubstitution provide better preservation of glycogen in mouse liver tissue compared with chemically fixed specimens. In addition, the fine structure of glycogen appears more homogeneous, showing less aggregation in cryo-treated liver samples.     

Some comments on the PAS reaction of glycogen

Synopsis The periodic acid-Schiff (PAS) reaction has been studied in sections of mouse liver using a self-assembled microspectrophotometer. Increased colour intensity was obtained up to 4 hr of oxidation with periodic acid and 2 hr treatment with Schiff's reagent. The oxidation curve showed an initial, steep increase in colouration with a levelling off afterwards, that could not be attributed to loss of aldehyde groups. The results obtained from carrying out the PAS reaction on sections pretreated with -amylase suggest that the reaction takes place in two phases in which the outer glucosyl groups of the glycogen molecule are oxidized more rapidly than the inner ones.     

Quantitative histochemical assessment of the heterogeneity of glycogen phosphorylase activity in liver parenchyma of fasted rats using the semipermeable membrane technique and the PAS reaction

Summary Glycogen phosphorylase (EC 2.4.1.1) has been demonstrated in sections of liver from rats starved for 24 h. The method is based on the measurement of the amount of glycogen formed after incubation in a gelled medium containing glucose 1-phosphate as substrate, using the semipermeable membrane technique. Glycogen was demonstrated with the periodic acid-Schiff (PAS) reaction.Phosphorylase activity appeared to be highest in periportal areas. The optimum substrate concentration for revealing activity of the enzyme was 60–120mm. After incubation in the absence of substrate, the staining intensity, as measured cytophotometrically as the mean integrated absorbance at 560 nm, was similar to that of an unincubated section.p-Chloromercuribenzoate, a non-specific inhibitor of glycogen phosphorylase activity, reduced the formation of final reaction product attributable to phosphorylase activity completely. The Michaelis constants (K _m ) of the enzyme in periportal and pericentral areas differed. This was probably due to the presence of thea form only in periportal areas and of thea andb forms in pericentral areas. The mean integrated absorbances in both the periportal and pericentral areas increased linearly with incubation time (4–16 min). A linear relationship was also found with section thickness (4–10 µm). The total activity of glycogen phosphorylase in the periportal areas was double the pericentral activity.It is concluded that the semipermeable membrane technique, combined with the PAS reaction for glycogen, can be used as a valid method for the demonstration and quantification of glycogen phosphorylase activity in livers from starved rats.     

Glycogen synthase from human and bovine polymorphonuclear leukocyte Immunochemical characterization and comparison to glycogen synthase from rat and rabbit muscle and liver cells

Glycogen synthase from human and bovine polymorphonuclear leukocytes was purified to homogeneity. Rabbit antisera were raised against the two glycogen synthases and used for immunochemical analysis. Western blotting analysis showed that the subunit of glycogen synthase in crude homogenates of human and bovine leukocytes in both cases has an M_r of 85 000. The existence of a cross-reactivity between the two enzymes and the corresponding antisera demonstrates immunological similarities between bovine and human leukocyte glycogen synthase. In addition, both antisera recognize glycogen synthase in crude cellular extracts from rabbit and rat liver and from skeletal muscle. Leukocyte glycogen synthase, therefore, cannot be classified as either muscle (M-type) or liver (L-type) glycogen synthase and our results do not support the proposed immunochemical distinction between M- and L-type glycogen synthase.     

Developmental regulation and ultrastructure of glycogen deposits during murine tooth morphogenesis

The distribution and ultrastructure of glycogen deposits were investigated in the murine tooth germ by histochemical periodic acid-Schiff (PAS) staining and transmission electron microscopy. Lower and upper first molars were examined in mouse embryos at embryonic days 11.5–17 (E11.5–E17) and in 2-day-old postnatal (P2) mice. The oral and dental epithelia and the mesenchymal cells were generally PAS-positive during tooth morphogenesis. PAS-negative cells were present at E13 in the distal tip of the tooth bud epithelium and in the contacting mesenchyme, and this complete lack of PAS reactivity continued in the dental papilla mesenchyme and inner enamel epithelium during the cap and bell stages. The lack of glycogen deposits in the interacting epithelium and mesenchyme during early morphogenesis may be associated with their demonstrated high signaling activities. Mesenchymal cells in the dental follicle consistently possessed small clusters or large pools of glycogen, which disappeared by P2. Since an intense PAS reaction was seen in mesenchymal cells at future bone sites, the glycogen in the dental follicle cells may be associated with their development into hard-tissue-forming cells. Ultrastructural observation of the enamel organ cells from the cap to early bell stages (E14–E15) revealed the occurrence of glycogen pools, which were associated with the Golgi apparatus and with vesicles having amorphous contents. Glycogen particles were also occasionally present inside vesicles or in the extracellular matrix. These may be associated with the exocytosis of glycosaminoglycan components into extracellular spaces and the formation of the stellate reticulum. Received: 9 November 1998 / Accepted: 17 January 1999     

Histochemistry of glycogen in the inner ear

Synopsis The effect of fixation and processing upon the morphological appearance of glycogen within the outer hair cells of the guinea-pig was investigated using two methods. In each method, tissue was fixed for 12 h in cold phosphate-buffered 4% paraformaldehyde and eventually dehydrated in ethanol, embedded in Epon 812, and cut into 4 m sections. In procedure A, after complete processing, the sections were tained using the periodic acid-Schiff reaction (PAS) or the periodic acid-thiocarbo-hydrazide-osmium tetroxide (PATCO) reaction which resulted in the appearance of listinct, coarse granules in the cytoplasm of the outer hair cells. Diastase digestion on one of the two matched sections after Epon removal and prior to staining, confirmed the granules to be glycogen. In procedure B, after primary fixation, the tissue was post-fixed in 1% osmium tetroxide and then processed exactly as in procedure A. Here, unless the Epon and osmium was remoyed, there was no staining of the outer hair cell cytoplasm. However, after Epon removal there was diffuse, grainy appearance of the outer hair cell cytoplasm which we considered to be due to glycogen although diastase confirmation was not possible. We have concluded that osmium tetroxide (1) inhibits PAS or PATCO staining, (2) prevents diastase digestion, and (3) prevents the appearance by light microscopy of distinct granules of glycogen.     

Glycogen rhythm in the embryonic liver of the goat

Summary The pieces of liver of 5×5 mm were fixed in different fixatives for varying periods, dehydrated and embedded in paraffin wax and sectioned at 6–8 micron in thickness. For staining purposes Best's carmine, periodic acid-Schiff and Bauer-Feulgen methods were used. The presence of glycogen in the different parts of the embryonic liver was confirmed by the diastase control which was run alongwith the undigested sections. The localization and distribution of glycogen was based in the visual analysis made. The amount of glycogen goes on increasing alongwith the morphological differentiation of the liver for final functioning of storage. The study supports the views of different authors based on the biochemical analysis, histochemically in a non-laboratory animal, the goat.     

Exercise-induced glycogen utilization by the respiratory muscles

Some controversy exists in the literature as to whether or not diaphragmatic glycogen is utilized during exercise. In this study male Sprague-Dawley rats were used to determine whether prolonged treadmill exercise would result in a significant reduction of glycogen concentration in the respiratory muscles. Untrained rats were run to exhaustion at a speed of 24 m/min, up a 10% grade. Run time averaged 48:30 min. After exercise a significant reduction in glycogen was observed in the diaphragm (43% of control), intercostals (43%), heart (39%), and plantaris (76%). In the diaphragm a significant reduction was shown in both types I and II fibers using the periodic acid-Schiff (PAS) stain for glycogen. These findings show that muscles with vastly different aerobic capacities utilize endogenous glycogen during moderately intense submaximal endurance exercise and that the costal diaphragm muscle is not an exception as has recently been suggested.     

Fiber type specific glycogen utilization in rat diaphragm during treadmill exercise

To examine the significance of endogenous stores of glycogen in specific fiber types (I, IIa, IIb) of the costal region of the diaphragm, adult male Wistar rats performed continuous running (25 m/min, 8 degrees grade) exercise for either 30 min or until fatigue. At 30 min of exercise, glycogen loss, as measured microphotometrically using the periodic acid-Schiff technique averaged between 73 and 80% (P less than 0.05) in the different fiber types. When exercise was performed to exhaustion, representing an additional 94 min, no further reduction in glycogen was observed in any fiber type. Biochemical determinations of glycogen from the diaphragm confirmed the extensive reduction in glycogen concentration with exercise. Large reductions (P less than 0.05) in glycogen were also noted in the soleus, plantaris, and vastus lateralis red. Although significant depletion (P less than 0.05) occurred in the vastus lateralis white, it was not as pronounced as in these other muscles. Repletion to preexercise glycogen concentration was complete by 4 h of recovery in all muscles except the vastus lateralis white. It is concluded that endogenous glycogen is a significant substrate in all muscles sampled regardless of fiber composition. In the case of the costal region of the diaphragm, the increased work of breathing resulting from heavy exercise leads to the recruitment of all fiber types, and each fiber type depends on glycogen as a substrate at least early in the exercise.     

Histochemical approach of cryobiopsy for glycogen distribution in living mouse livers under fasting and local circulation loss conditions

Soluble proteins and glycogen particles, which are easily lost upon conventional chemical fixation, have been reported to be better preserved in paraffin-embedded sections by ‘cryobiopsy’ combined with freeze-substitution fixation (FS). In this study, we examined the distribution of glycogen in living mouse livers under physiologic and pathologic conditions with periodic acid-Schiff (PAS) staining by cryobiopsy. The livers of the fully fed mice showed high PAS-staining intensity in the cytoplasm of all hepatocytes. The PAS-staining intensity gradually decreased away from hepatocytes around portal tracts, depending on treatments with different α-amylase concentrations. At 6 or 12 h after fasting, PAS-staining intensity markedly decreased in restricted areas of zone I near the portal tracts. The cryobiopsy was repeatedly performed not only on different mice, but also on individuals. Next, glycogen distributions were evaluated by temporarily clipping of liver tissues of anesthetized mice, followed by recovery of blood circulation. In the liver tissues in which blood was recirculated for 1 h after the 30 min anoxia, PAS staining was still observed in zone II and also in restricted areas of zone I far from the portal tracts. In PAS-unstained hepatocytes, the immunoglobulin-kappa light chain was not detected in the cytoplasm, indicating that cell membrane permeability was retained and that glycogen metabolism was related to the functional state of blood circulation. We propose that the level of consumption or production of glycogen particles could vary in zone I, depending on the distance from the portal tracts. Thus, cryobiopsy combined with FS enabled us to examine time-dependent changes in glycogen distribution in the liver tissues of living mice. This combination might be applicable to the clinical evaluation of human liver tissues.     

The activity of glycogen synthase phosphatase limits hepatic glycogen deposition in the adrenalectomized starved rat.

Hepatocytes from adrenalectomized 48 h-starved rats responded to increasing glucose concentrations with a progressively more complete inactivation of phosphorylase. Yet no activation of glycogen synthase occurred, even in a K+-rich medium. Protein phosphatase activities in crude liver preparations were assayed with purified substrates. Adrenalectomy plus starvation decreased synthase phosphatase activity by about 90%, but hardly affected phosphorylase phosphatase activity. Synthase b present in liver extracts from adrenalectomized starved rats was rapidly and completely converted into the a form on addition of liver extract from a normal fed rat. Glycogen synthesis can be slowly re-induced by administration of either glucose or cortisol to the deficient rats. In these conditions there was a close correspondence between the initial recovery of synthase phosphatase activity and the amount of synthase a present in the liver. The latter parameter was strictly correlated with the measured rate of glycogen synthesis in vivo. The decreased activity of synthase phosphatase emerges thus as the single factor that limits hepatic glycogen deposition in the adrenalectomized starved rat.     

The interaction of muscle glycogen phosphorylase b with glycogen

Interaction of muscle glycogen phosphorylase b (EC 2.4.1.1) with glycogen was studied by sedimentation, stopped-flow and temperature-jump methods. The equilibrium enzyme concentration was determined by sedimentation in an analytical ultracentrifuge equipped with absorption optics and a photoelectric scanning system. The maximum adsorption capacity of pig liver glycogen is 3.64 mumol dimeric glycogen phosphorylase b per g glycogen, which corresponds to 20 dimeric enzyme molecules per average glycogen molecule of Mr 5.5 X 10(6). Microscopic dissociation constants were determined for the enzyme-glycogen complex within the temperature range from 12.7 to 30.0 degrees C. Enzyme-glycogen complexing is accompanied by increasing light scattering and its increment depends linearly on the concentration of the binding sites on a glycogen particle that are occupied by the enzyme. Complex formation and relaxation kinetics are in accordance with the proposed bimolecular reaction scheme. The monomolecular dissociation rate constant of the complex increases as the temperature increases from 12.7 to 30.0 degrees C, whereas the bimolecular rate constant changes slightly and is about 10(8) M-1 X S-1. These data point to the possibility of diffusional control of the complex formation.     

In vitro activation of leukocyte glycogen synthetase

The activity of leukocyte glycogen synthetase in a freshly prepared homogenate is almost completely in the $\text{b}$ form. Incubation of the homogenate at 30°C caused a time dependent increase in the activity measured in the absence of G-6-P ($\text{b}$ to $\text{a}$ conversion). The K_a for G-6-P decreased from 0.7 to 0.01 mM. Freezing of the homogenate resulted in a complete loss of the capacity for activation. These results demonstrate that glycogen synthetase from leukocytes of normal human subjects can be converted $\text{in vitro}$ to a form, which is almost independent of G-6-P for activity.     

Granulation staining and cytochemistry of peripheral blood leucocytes in healthy carp (Cyprinus carpio L.) II: Monocytes

Granulation staining and cytochemistry of peripheral blood monocytes in healthy carp ( Cyprinus carpio L.) are described. Blood smears were stained for periodic acid-Schiff (PAS), peroxidase, oxidase, alkaline and acid phosphatase, α-naphthyl acetate esterase, α-naphthyl-butyrate esterase, naphthol-AS-chloroacetate esterase (AS-D), naphthol-AS-acetate esterase and β-glucuronidase. For representation of different granulations triazide-staining for eosinophil and neutrophil granules and aqueous methylere-blue staining for basophil granules were used. Lipids were shown by sudan-black-reaction. Monocytes showed only basophil granulation and weak lipid reaction. All tested enzymes were detected, with the exception of peroxidase. The PAS reaction for glycogen proof was negative.     

Dimedone as an Aldehyde Blocking Reagent to Facilitate the Histochemical Demonstration of Glycogen

The demonstration of glycogen by the periodic acid-Schiff technique can be clarified by the interposition of a short dimedone blockade after the periodic acid oxidation. This blocks the PAS reaction of the vast majority of materials, but a very much longer blockade is required to abolish the reaction of glycogen. The dimedone-PAS method is valuable in situations where the demonstration of glycogen is otherwise difficult because of the proximity of diastase-fast PAS positive materials. For this purpose dimedone is best used in alcoholic solution (5% in absolute alcohol for about 3 hr at 60°C), since an aqueous solution permits diffusion of the aldehydes produced from the oxidation of glycogen. A saturated aqueous solution, or a 5% solution in 80% alcohol, is much more rapid in its blocking action, however, and may be more satisfactory when dimedone is used simply as an aldehyde blocking reagent.     

Glycogen in pancreatic islets of steroid diabetic rats

Summary In the islets of the rat pancreas, steroid diabetes induced by triamcinolon-acetonid leads to degranulation of the B cells and glycogen infiltration. The glycogen cannot be satisfactorily detected using methods like the chromic acid technique according to Bauer, staining with Best's carmine, or the usually applied periodic acid-Schiff (PAS) reaction. Glycogen detection is improved, however, when lead tetraacetate is used in place of periodic acid as oxidizing agent. When combining the carbohydrate detection method with the peroxidase — antiperoxidase (PAP) method used for immunocytochemical detection of the various pancreatic islet hormones, paraffin sections reveal that glycogen is primarily localized in granulated B cells; the degranulated B cells also contain glycogen, though in smaller amounts. In contrast, the islet cells containing somatostatin, glucagon and pancreatic polypeptide are nearly free of glycogen.This study was supported by the Deutsche Forschungsgemeinschaft K1 426/2     

Observations on the histochemically demonstrable liver glycogen phosphorylase activity and native glycogen under different nutritional conditions

Summary In this study a histochemical demonstration of glycogen phosphorylase activity and native glycogen in the livers from normally fed, overfed and starved rats was performed.It was found that the amount and localization of phosphorylase activity well corresponded to the amount and localization of the native glycogen. A change of the glycogen content in the liver also resulted in a change of the histochemically demonstrable liver glycogen phosphorylase activity.It is concluded that the presence of tissue bound glycogen and undissolved glycogenphosphorylase complexes are necessary for positive histochemical demonstration of liver glycogen phosphorylase activity.This work was supported by a grant from the Finnish Veterinary Medical Foundation.     

A brachial glycogen body in the spinal cord of the domestic chicken.

When cervical segments 14 to 15 of the chicken spinal cord are cut transversely and studied by routine histological and histochemical methods, an onion-shaped region, filled with thread-like fibers, is seen to surround the ependymal cells of the central canal and to be bounded laterally by the neural elements of the spinal gray matter. This area is negative for succinic dehydrogenase, beta-hydroxybutyrate dehydrogenase and cholinesterase activity, but very strongly periodic acid-Schiff positive. Diastase controls show the positive material to be glycogen. Parasagittal sections through this cervical region and into the upper thoracic cord, show the glycogen-rich region to extend longitudinally throughout the region. Because of its location and histochemical characterization, which are similar to that of the ventral portion of the glycogen body, the term brachial glycogen body is proposed for this structure.     

Direct enzymatic procedure for the determination of liver glycogen

A method is proposed to measure glycogen content in liver homogenates without extraction and acid hydrolysis of tissue glycogen. Homogenates were treated with amyloglucosidase, which degrades glycogen to glucose, and the glucose was the determined enzymatically by the use of glucose oxidase and peroxidase. The method was shown to yield nearly complete (99%) recoveries of standard glycogen, while 5 hr of acid hydrolysis of standard glycogen were required to obtain comparable recoveries. When compared to an acid hydrolysis method for liver, amyloglucosidase degradation of rat liver glycogen and subsequent determination of glucose resulted in higher values for glycogen content. The amyloglucosidase, glucose oxidase: peroxidase method has the advantage of rapidity, whereas the traditional method consisting of extraction, precipitation, and acid hydrolysis is not only time consuming, but may also be subject to losses of glycogen in each step.     

Ultrastructural distribution of glycogen in pancreatic islets of steroid diabetic rats

In the islets of rat pancreas, steroid diabetes induced by triamcinolon-acetonid led to glycogen infiltration of B cells. Ultracytochemically, glycogen was detected within 24 hours after glucocorticoid administration using the periodic acid-silver proteinate method according to Maxwell (1978). Glycogen was primarily located in the cytoplasm of granulated B cells but could also be detected in the halo of the secretory granules of these cells. The amount of glycogen increased during the course of the 5 day experiment. The A, D, and PP cells were free of glycogen.