The effects of insulin replacement and withdrawal on hepatic ultrastructure and biochemistry

This study examines the early hepatic biochemical and ultrastructural responses to insulin replacement in streptozotocin-diabetic rats and insulin withdrawal from insulin-maintained diabetic rats. Insulin administration rapidly lowered plasma glucose and the elevated glucose-6-phosphatase (G-6-Pase) specific activity of the diabetic rats. However, hepatic glycogen did not increase until after 3 hr of insulin treatment. Hepatic ultrastructure responded to insulin replacement after the decline in glucose and G-6-Pase. This was seen in periportal hepatocytes as a reduction in the close association between smooth endoplasmic reticulum (SER) and glycogen particles in the diabetic animals. The treated rats showed hepatic SER restricted to the periphery of glycogen masses, as is characteristic of these cells from normal rats, in many cells by 6 hr and all cells by 18 hr. Insulin withdrawal from insulin-treated diabetic rats elicited nearly a total reversal of the above events. Plasma insulin declined to a value half that of the normal rats by 6 hr after withdrawal; concurrently, plasma glucose rose sharply to hyperglycemic values as hepatic glycogen content dropped. Following the rise in plasma glucose and fall in glycogen content, G-6-Pase specific activity increased and by 16 hr reached the high values characteristic of the diabetic animal. Hepatic ultrastructure was also changed as evidenced by an intrusion of elements of the SER into the dense glycogen masses; the result was dispersed glycogen closely associated with SER as seen in the diabetic animal. It is concluded that the hepatic response to insulin replacement in diabetic animals and diabetic onset in insulin-withdrawn animals is rapid and occurs through defined stages.     

Lobular and cellular patterns of early hepatic glycogen deposition in the rat as observed by light and electron microscopic radioautography after injection of 3H-galactose

Very low hepatic glycogen levels are achieved by overnight fasting of adrenalectomized (ADX) rats. Subsequent injection of dexamethasone (DEX), a synthetic glucocorticoid, stimulates marked increases in glycogen synthesis. Using this system and injecting 3H-galactose as a glycogen precursor 1 hr prior to sacrifice, the intralobular and intracellular patterns of labeled glycogen deposition were studied by light (LM) and electron (EM) microscopic radioautography. LM radioautography revealed that 1 hr after DEX treatment, labeling patterns for both periportal and centrilobular hepatocytes resembled those in rats with no DEX treatment: 18% of the hepatocytes were unlabeled, and 82% showed light labeling. Two hours after treatment with DEX, 14% of the hepatocytes remained unlabeled, and 78% were lightly labeled; however, 8% of the cells, located randomly throughout the lobule, were intensely labeled. An increased number of heavily labeled cells (26%) appeared 3 hr after DEX treatment; and by 5 hr 91% of the hepatocytes were intensely labeled. Label over the periportal cells at this time was aggregated, whereas centrilobular cells displayed dispersed label. EM radioautographs showed that 2 to 3 hr after DEX injection initial labeling of hepatocytes, regardless of their intralobular location, occurred over foci of smooth endoplasmic reticulum (SER) and small electron-dense particles of presumptive glycogen, and in areas of SER and distinct glycogen particles. After 5 hrs of treatment with DEX, the intracellular distribution of label reflected the glycogen patterns characteristic of periportal or centrilobular regions.     

SERGE, the subcellular site of initial hepatic glycogen deposition in the rat: a radioautographic and cytochemical study

Hormonal control of hepatic glycogen and blood glucose levels is one of the major homeostatic mechanisms in mammals: glycogen is synthesized when portal glucose concentration is sufficiently elevated and degraded when glucose levels are low. We have studied initial events of hepatic glycogen synthesis by injecting the synthetic glucocorticoid dexamethasone (DEX) into adrenalectomized rats fasted overnight. Hepatic glycogen levels are very low in adrenalectomized rats, and DEX causes rapid deposition of the complex carbohydrate. Investigation of the process of glycogen deposition was performed by light and electron microscopic (EM) radioautography using [3H]galactose as a glycogen precursor. Rats injected with DEX for 2-3 h and [3H]galactose one hour before being killed displayed an increasing number of intensely labeled hepatocytes. EM radioautography revealed silver grains over small (+/- 1 micron) ovoid or round areas of the cytosome that were rich in smooth endoplasmic reticulum (SER) and contained a high concentration of small dense particles. These distinct areas or foci of SER and presumptive glycogen (SERGE) were most numerous during initial periods of glycogen synthesis. After longer exposure to DEX (4-5 h) more typical deposits of cytoplasmic glycogen were evident in the SERGE regions. Several criteria indicated that the SERGE foci contained glycogen or presumptive glycogen: resemblance of the largest dense particles to beta-glycogen particles in EM; association of 3H-carbohydrate with the foci; removal of particles and label with alpha-amylase; and positive reaction with periodic acid-chromic acid-silver methenamine. The concentration of SER in the small foci and the association of newly formed glycogen particles with elements of SER suggest a role for this organelle in the initial synthesis of glycogen.     

Observations on the role of smooth endoplasmic reticulum in glucocorticoid-induced hepatic glycogen deposition

We have studied by quantitative electron microscopy the relationship of specific hepatic cellular organelles to glycogen synthesis using dexamethasone, a potent synthetic glucocorticoid, to induce glycogen deposition in livers of adrenalectomized rats. Chemical and ultrastructural glycogen determinations revealed that the livers of fasted adrenalectomized rats had very low glycogen levels. Dexamethasone caused a time-related increase in hepatic glycogen which was the result of increases in the number of hepatocytes depositing glycogen and the amount of glycogen in each cell. The surface density of smooth endoplasmic reticulum (SER) in centrilobular and periportal hepatocytes also increased after treatment with dexamethasone; this increase preceded glycogen deposition. The newly deposited glycogen was spatially associated with membranes of SER, and a continued increase in SER surface density was correlated temporally with the increasing glycogen volume density. In both centrilobular and periportal hepatocytes, the suface density of rough endoplasmic reticulum (RER) initially decreased after dexamethasone administration but later increased. These data support the hypothesis that dexamethasone-induced enhancement of SER is functionally associated with the increase in glycogen, and that although the initial increase in SER may occur through transformation of RER to SER, later increases in SER require synthesis of new membranes.     

Regulation of glycogen synthesis from glucose and gluconeogenic precursors by insulin in periportal and perivenous rat hepatocytes.

Glycogen synthesis in hepatocyte cultures is dependent on: (1) the nutritional state of the donor rat, (2) the acinar origin of the hepatocytes, (3) the concentrations of glucose and gluconeogenic precursors, and (4) insulin. High concentrations of glucose (15-25 mM) and gluconeogenic precursors (10 mM-lactate and 1 mM-pyruvate) had a synergistic effect on glycogen deposition in both periportal and perivenous hepatocytes. When hepatocytes were challenged with glucose, lactate and pyruvate in the absence of insulin, glycogen was deposited at a linear rate for 2 h and then reached a plateau. However, in the presence of insulin, the initial rate of glycogen deposition was increased (20-40%) and glycogen deposition continued for more than 4 h. Consequently, insulin had a more marked effect on the glycogen accumulated in the cell after 4 h (100-200% increase) than on the initial rate of glycogen deposition. Glycogen accumulation in hepatocyte cultures prepared from rats that were fasted for 24 h and then re-fed for 3 h before liver perfusion was 2-fold higher than in hepatocytes from rats fed ad libitum and 4-fold higher than in hepatocytes from fasted rats. The incorporation of [14C]lactate into glycogen was 2-4-fold higher in periportal than in perivenous hepatocytes in both the absence and the presence of insulin, whereas the incorporation of [14C]glucose into glycogen was similar in periportal and perivenous hepatocytes in the absence of insulin, but higher in perivenous hepatocytes in the presence of insulin. Rates of glycogen deposition in the combined presence of glucose and gluconeogenic precursors were similar in periportal and perivenous hepatocytes, whereas in the presence of glucose alone, rates of glycogen deposition paralleled the incorporation of [14C]glucose into glycogen and were higher in perivenous hepatocytes in the presence of insulin. It is concluded that periportal and perivenous hepatocytes utilize different substrates for glycogen synthesis, but differences between the two cell populations in the relative utilization of glucose and gluconeogenic precursors are dependent on the presence of insulin and on the nutritional state of the rat.     

Association of glycogen synthase phosphatase and phosphorylase phosphatase activities with membranes of hepatic smooth endoplasmic reticulum

A detailed investigation was conducted to determine the precise subcellular localization of the rate-limiting enzymes of hepatic glycogen metabolism (glycogen synthase and phosphorylase) and their regulatory enzymes (synthase phosphatase and phosphorylase phosphatase). Rat liver was homogenized and fractionated to produce soluble, rough and smooth microsomal fractions. Enzyme assays of the fractions were performed, and the results showed that glycogen synthase and phosphorylase were located in the soluble fraction of the livers. Synthase phosphatase and phosphorylase phosphatase activities were also present in soluble fractions, but were clearly identified in both rough and smooth microsomal fractions. It is suggested that the location of smooth endoplasmic reticulum (SER) within the cytosome forms a microenvironment within hepatocytes that establishes conditions necessary for glycogen synthesis (and degradation). Thus the location of SER in the cell determines regions of the hepatocyte that are rich in glycogen particles. Furthermore, the demonstration of the association of synthase phosphatase and phosphorylase phosphatase with membranes of SER may account for the close morphological association of SER with glycogen particles (i.e., disposition of SER membranes brings the membrane-bound regulatory enzymes in close contact with their substrates).     

The influence of buffers during fixation on the appearance of smooth endoplasmic reticulum and glycogen in hepatocytes of normal and glycogen-depleted rats

Summary Liver tissue of normal and glycogen depleted rats was prepared for transmission electron microscopy by perfusion fixation and subsequent osmication in the presence of various buffers, dehydration in aethanol and embedding in epon. The use of Na/K-phosphate or Nacacodylate to buffer glutaraldehyde led to similar appearance and distribution of SER. When Na-cacodylate was used during osmication, more SER membranes were retained but less accumulations of glycogen were found than after osmication in the presence of Na/K-phosphate. Fixation with s-collidine buffered osmium led to an easily recognisable network of SER comprising wide tubules whereas glycogen was hindered to be stained. Veronal acetate or Na-cacodylate supplemented with sucrose resulted in marked dilation and disintegration of SER. A similar effect was obtained when Na/K-phosphate or Na-cacodylate was used in hyposmolar concentration as buffer for glutaraldehyde. Liver of fasted rats or glucagon-treated rats after perfusion with Na/K-phosphate buffered glutaraldehyde and osmication in the presence of Na/K-phosphate or Na-cacodylate comprised glycogen-depleted hepatocytes which contained abundant SER membranes occupying the entire space between other organelles even in samples harvested 3 h after glucagon administration. The diversity in appearance and distribution of SER and glycogen granules, which depends to a large extend on the buffer used, suggests that SER membranes may not be sufficiently stabilized during aldehyde fixation and osmication. We thus consider it likely that large accumulations of glycogen granules are the consequence of disintegration of SER membranes during processing rather than they represent the morphologic substrate of physiological degradation of SER membranes in the course of glycogen synthesis and deposition.     

Stereological analysis of hepatic fine structure in the Fischer 344 rat. Influence of sublobular location and animal age

Stereological analysis of hepatic fine structure in Fischer 344 male rats at 1, 6, 10, 16, 20, 25, and 30 mo of age revealed differences in the amounts and distributions of hepatocellular organelles as a function of sublobular location or animal age. Between 1 and 16 mo of age, both the centrolobular and periportal hepatocytes increased in volume by 65 and 35%, respectively. Subsequently, the cell volumes declined until the hepatocytes of 30-mo-old rats approached the size of those found in the youngest animals. Regardless of animal age, the centrolobular cells were consistently larger than the corresponding periportal hepatocytes. The cytoplasmic and ground substance compartments reflected similar changes in their volumes, although there was no significant alteration in the nuclear volume. The volumes of the mitochondrial and microbody compartments increased and decreased concomitant with the changes in average hepatocyte size. Both lobular zones in the 30-mo-old rats contained significantly smaller relative volumes of mitochondria than similar parenchyma in 16-mo-old animals. The volume density of the dense bodies (lysosomes) increased markedly in both lobular zones between 1 and 30 mo of age, confirming reports of an age-dependent increase in this organelle. The surface area of the endoplasmic reticulum in the centrolobular and periportal hepatocytes reached its maximum level in the 10-mo-old rats and subsequently declined to amounts which approximated those measured in the 1-mo-old animals. This age-related loss of intracellular membrane is attributable to a significant reduction in the surface area of the smooth-surfaced endoplasmic reticulum (SER) in animals beyond 16 mo of age. The amount of rough-surfaced endoplasmic reticulum (RER) in the periportal parenchymal cells was unaffected by aging, but the centrolobular hepatocytes of 30-mo-old animals contained 90% more RER than similar cells in the youngest rats. The centrolobular parenchyma contained more SER and the portal zones more RER throughout the age span studied. These quantitative data suggest that (a) certain hepatic fine structural parameters undergo marked changes as a function of animal age, (b) there exists a gradient in hepatocellular fine structure across the entire liver lobule, and (c) there are remarkable similarities in hepatocyte ultrastructure between very young and senescent animals, including cell size and the amount of SER.     

Zonal heterogeneity of peroxisome proliferation and morphology in rat liver after gemfibrozil treatment

The effect of gemfibrozil on the fine structure of peroxisomes across the rat liver lobule was investigated by light and electron microscopy using the alkaline diaminobenzidine (DAB) medium for the visualization of catalase peroxidatic activity. The oral administration of gemfibrozil for 2 weeks induces a striking heterogeneity in the lobular distribution of peroxisomes. The size and shape of peroxisomes, variety of matrix modifications, catalase content, and position within the cell, are functions of the zonal localization of the hepatocytes. The largest and most numerous peroxisomes were found in the centrilobular region indicating that these cells are most sensitive to peroxisome proliferation. On the other hand, the greatest variety of peroxisome shapes and matrix alterations (tubules and plates) was seen more peripherally in the mid-zonal and periportal regions. The larger, round centrilobular peroxisomes stained less intensely than the elongated peroxisomes found more peripherally, indicating a discrepancy between peroxisome size and catalase content. A distinct population of small irregularly shaped peroxisomes, lacking matrix specializations and containing variable catalase content, was found in the mid-zonal region. Peroxisomes in the centrilobular region were located within areas of the cell containing SER and glycogen while those in the more peripheral region were relegated to areas of the cytoplasm separate from RER and SER. In addition to modifications of peroxisomes, gemfibrozil treatment resulted in a proliferation and formation of whorled configurations of SER. This was particularly evident in the mid-zonal region, where single peroxisomal profiles could be seen surrounded by whorls of SER membranes. The results suggest that rat liver hepatocytes of the centrilobular region are the most sensitive to peroxisome proliferation and those of the periportal area are most susceptible to peroxisome matrix alterations after gemfibrozil treatment.     

The influence of buffers during fixation on the appearance of smooth endoplasmic reticulum and glycogen in hepatocytes of normal and glycogen-depleted rats.

Liver tissue of normal and glycogen depleted rats was prepared for transmission electron microscopy by perfusion fixation and subsequent osmication in the presence of various buffers, dehydration in aethanol and embedding in epon. The use of Na/K-phosphate or Na-cacodylate to buffer glutaraldehyde led to similar appearance and distribution of SER. When Na-cacodylate was used during osmication, more SER membranes were retained but less accumulations of glycogen were found than after osmication in the presence of Na/K-phosphate. Fixation with s-collidine buffered osmium led to an easily recognisable network of SER comprising wide tubules whereas glycogen was hindered to be stained. Veronal acetate or Na-cacodylate supplemented with sucrose resulted in marked dilation and disintegration of SER. A similar effect was obtained when Na/K-phosphate or Na-cacodylate was used in hyposmolar concentration as buffer for glutaraldehyde. Liver of fasted rats or glucagon-treated rats after perfusion with Na/K-phosphate buffered glutaraldehyde and osmication in the presence of Na/K-phosphate or Na-cacodylate comprised glycogen-depleted hepatocytes which contained abundant SER membranes occupying the entire space between other organelles even in samples harvested 3 h after glucagon administration. The diversity in appearance and distribution of SER and glycogen granules, which depends to a large extend on the buffer used, suggests that SER membranes may not be sufficiently stabilized during aldehyde fixation and osmication. We thus consider it likely that large accumulations of glycogen granules are the consequence of disintegration of SER membranes during processing rather than they represent the morphologic substrate of physiological degradation of SER membranes in the course of glycogen synthesis and deposition.     

Studies on gluconeogenesis and ketogenesis in isolated hepatocytes from alloxan diabetic rats.

Gluconeogenesis and ketogenesis were studied in isolated hepatocytes obtained from normal and alloxan diabetic rats. Insulin treatment maintained near-normal blood glucose levels and caused an increase in glycogen deposition. The third day after insulin withdrawal the rats displayed a diabetic syndrome marked by progressive hyperglycemia and glycogen depletion. Net glucose production in liver cells isolated from alloxan diabetic rats progressively increased with time up to 72 hr after the last in vivo insulin injection. Maximal glucose production was observed at 72 hr with 10 mM alanine, lactate, pyruvate, or fructose. Glucose production decreased at 96 hr. The same pattern was observed with the incorporation of labeled bicarbonate into glucose. Ketogenesis in liver cells and hepatic lipid content also peaked at 72 hr.     

Glucokinase overexpression restores glucose utilization and storage in cultured hepatocytes from male Zucker diabetic fatty rats.

Zucker diabetic fatty rats develop type 2 diabetes concomitantly with peripheral insulin resistance. Hepatocytes from these rats and their control lean counterparts have been cultured, and a number of key parameters of glucose metabolism have been determined. Glucokinase activity was 4.5-fold lower in hepatocytes from diabetic rats than in hepatocytes from healthy ones. In contrast, hexokinase activity was about 2-fold higher in hepatocytes from diabetic animals than in healthy ones. Glucose-6-phosphatase activity was not significantly different. Despite the altered ratios of glucokinase to hexokinase activity, intracellular glucose 6-phosphate concentrations were similar in the two types of cells when they where incubated with 1-25 mM glucose. However, glycogen levels and glycogen synthase activity ratio were lower in hepatocytes from diabetic animals. Total pyruvate kinase activity and its activity ratio as well as fructose 2,6-bisphosphate concentration and lactate production were also lower in cells from diabetic animals. All of these data indicate that glucose metabolism is clearly impaired in hepatocytes from Zucker diabetic fatty rats. Glucokinase overexpression using adenovirus restored glucose metabolism in diabetic hepatocytes. In glucokinase-overexpressing cells, glucose 6-phosphate levels increased. Moreover, glycogen deposition was greatly enhanced due to the activation of glycogen synthase. Pyruvate kinase was also activated, and fructose-2,6-bisphosphate concentration and lactate production were increased in glucokinase-overexpressing diabetic hepatocytes. Overexpression of hexokinase I did not increase glycogen deposition. In conclusion, hepatocytes from Zucker diabetic fatty rats showed depressed glycogen and glycolytic metabolism, but glucokinase overexpression improved their glucose utilization and storage.     

Effect of ischemia-reperfusion on the heterogeneous lobular distribution pattern of glycogen content and glucose-6-phosphatase activity in human liver allograft.

In order to examine glucose metabolism in liver grafts after cold ischemia and reperfusion, the heterogeneous lobular distribution pattern of glycogen content and glucose-6-phosphatase activity was studied using histochemical methods. The characteristic heterogeneous lobular distribution pattern of glycogen and glucose-6-phosphatase was maintained after preservation and reperfusion. However, it appeared that glycogen content decreased in both periportal and centrilobular hepatocytes after reperfusion. The glycogen decrease was higher in periportal hepatocytes. Glucose-6-phosphatase activity was maintained after reperfusion in most of the cases in periportal hepatocytes. In centrilobular hepatocytes, more cases showed a decrease in enzyme activity. It is suggested that ischemia-reperfusion mainly affects the glycogen content in both periportal and centrilobular hepatocytes and that centrilobular glucose-6-phosphatase activity is more sensitive to ischemia-reperfusion injury than periportal hepatocytes.     

Stimulation of glycogen synthesis by proglycosyn (LY177507) by isolated hepatocytes of normal and streptozotocin diabetic rats

The phenacylimidazolium compound LY177507 was shown by Harris et al. (Harris, R. A., Yamanuchi, K., Roach, P. J., Yen, T. T., Dominiani, S. J., and Stephens, T. W. (1989) J. Biol. Chem. 264, 14674-14680) to stimulate glycogen synthesis greatly in isolated rat hepatocytes. We extended studies with this compound, designated proglycosyn (Yamaguchi, K., Stephens, T. W., Chikadar, K., Depaoli-Roach, A., And Harris, R. A. (1991) Diabetes 40, (Suppl. 1) 102 (abstr.] employing hepatocytes from normal and streptozotocin diabetic rats. Proglycosyn is more effective than amino acids in stimulating glycogen synthesis. In cells incubated with glucose, lactate, or dihydroxyacetone the effect of glutamine and proglycosyn was synergistic. In cells incubated with glucose plus lactate, or glucose plus dihydroxyacetone, the stimulation by the two agonists was additive. Proglycosyn diverted the gluconeogenic flux from glucose to glycogen. The maximal rates of glycogen deposition attained in the presence of glutamine and proglycosyn from cells incubated with glucose plus lactate, or glucose plus dihydroxyacetone, where about 80 and 110 mumols/h/g of liver, respectively. Proglycosyn depressed glycogenolysis in hepatocytes of fed rats and stimulated glycogen synthesis from lactate and dihydroxyacetone. The incorporation of [U-14C]glucose and [U-14C]lactate in these cells occurred in the presence of glycogen breakdown or exceeded net production, indicating the occurrence of recycling of glycogen in hepatocytes of fed rats. Hepatocytes from fasted streptozotocin diabetic rats contained high levels of glycogen. Glycogenolysis was markedly depressed by proglycosyn. Glycogen synthesis from lactate and dihydroxyacetone in these cells was stimulated by glutamine and proglycosyn in a fashion similar to that in cells from fasted control rats, and the rates of glycogen synthesis were similar in cells of control and diabetic rats. With glucose as sole substrate, glutamine did not stimulate glycogen synthesis. When both agonists were present, there was a marked synergism and substantial glycogen formation. Streptozotocin diabetic rats prior to the onset of cachexia have a normal capacity for glycogen synthesis.     

The effect of ischemia on glycogen phosphorylase activity in rat liver: a quantitative histochemical study

The effects of ischemia in vitro for 0-60 min at 37 degrees C on glycogen phosphorylase activity in rat liver have been studied under different feeding conditions. Glycogen phosphorylase activity was demonstrated with a recently developed quantitative histochemical method using a semipermeable membrane and the PAS-reaction. The cytophotometrically measured glycogen phosphorylase activity in livers from 24 h-fasted rats was approximately five times the activity in livers from normally fed rats. The activity in periportal areas was about 1.5 times higher than the activity in pericentral areas in livers from starved rats, but more or less evenly distributed in livers from fed rats. Enzyme activity in pericentral areas of livers from 24 h-fasted rats started to decrease after 20 min of ischemia. After 50-60 min of ischemia, the activity was decreased to approximately 25% of the control activity. Livers from normally fed rats showed unchanged activity in periportal and pericentral areas after 10-60 min of ischemia. It has been assumed that the activation of the enzyme was disturbed by ischemia, possibly as a consequence of plasma membrane damage.     

An assessment of the importance of intralysosomal and of alpha-amylolytic glycogenolysis in the liver of normal rats and of rats with a glycogen-storage disease

Mechanisms of glycogenolysis have been investigated in a comparative study with Wistar rats and gsd rats, which maintain a high glycogen concentration in the liver as a result of a genetic deficiency of phosphorylase kinase. In Wistar hepatocytes the rate of glycogenolysis, as modulated by glucagon and by glucose, was proportional to the concentration of phosphorylase a. In suspensions of gsd hepatocytes the rate of glycogenolysis was far too high as compared with the low level of phosphorylase a; in addition, only a minor fraction of the glycogen lost was recovered as glucose and lactate, owing to the accumulation of oligosaccharides. When the gsd hepatocytes were incubated in the presence of an inhibitor of alpha-amylase (BAY e 4609) glycogenolysis and the formation of oligosaccharides virtually ceased; the production of glucose plus lactate, already modest in the absence of BAY e 4609, was further decreased by 40%, owing to the suppression of a pathway for glucose production by the successive actions of alpha-amylase and alpha-glucosidase. Evidence was obtained that gsd hepatocytes are more fragile, and that amylolysis of glycogen occurred in damaged cells and/or in the extracellular medium. This may even occur in vivo, since quick-frozen liver samples from anesthetized gsd rats contained severalfold higher concentrations of oligosaccharides than did similar samples from Wistar rats. However, administration of a hepatotoxic agent (CCl4) caused hepatic glycogen depletion in Wistar rats, but not in gsd rats. The administration of phloridzin and of vinblastine, which have been proposed to induce glycogenolysis in the lysosomal system, did not decrease the hepatic glycogen level in gsd rats. Taken together, the data indicate that only the phosphorolytic degradation of glycogen is metabolically important, and that alpha-amylolysis is an indication of an increased fragility of gsd hepatocytes, which becomes prominent when these cells are incubated in vitro.     

Quantitative analysis of the pathways of glycogen repletion in periportal and perivenous hepatocytes in vivo.

In order to examine the pathways of hepatic glycogen repletion in the periportal and perivenous zones of the liver, [1-13C]glucose (99% enriched) was infused intraduodenally into conscious, 24-h fasted rats for 3 h. The liver was then quickly perfused in situ, and the cytoplasmic contents of the periportal and perivenous hepatocytes were selectively sampled by modification of the dual-digitonin-pulse technique (Quistorff, B., and Grunnet, N. (1987) Biochem. J. 243, 87-95). The 13C isotopic enrichment at each carbon position of the glucosyl units of hepatic glycogen was determined by 13C NMR and that of the C-1 position by gas chromatography-mass spectroscopy. From comparison of hepatic glycogen repleted by direct incorporation of plasma glucose (glucose----glucose-6-P----glucose-1-P----UDP-glucose----glycogen) was calculated to be 29% in the periportal zone and 35% in the perivenous zone, assuming equal glycogen synthetic rates within the two zones. Thus, the majority of glycogen is derived by an indirect route (glucose--------3-carbon unit--------glucose --------UDP-glucose--------glycogen) in both the periportal zone and in the perivenous zone. In conclusion, in a 24-h fasted rat there does not appear to be a major difference between the periportal and perivenous hepatocytes in the percent of glycogen synthesized by the direct pathway following a glucose load.     

The metabolic zonation of glycogen synthesis in rat liver after fasting and refeeding.

The quantitative analysis of total glycogen and two fractions of the glycogen content was made by means of cytophotometry in hepatocytes with respect to the portal and central zones of the liver lobule after 48 hr starvation and 15, 30, 60, 120 min after refeeding using the Magiscan image analyzer. It was shown that glycogen content was minimal after 48 hr starvation, although a few cells of the central zone contained a noticeable glycogen quantity. Glycogen synthesis initiation was observed after 15 min refeeding. Glycogen synthesis has been characterized by an increasing glycogen content in the portal zone of the liver lobule compared to the pericentral zone, and this difference increased with time. The distinctive morphological changes were observed in the total glycogen content as well as fractions with different optical density in the process of glycogen synthesis after starvation of rats.     

Glycogen synthesis by hepatocytes from diabetic rats.

Hepatocytes prepared from streptozotocin- and alloxan-diabetic rats starved for 24 h contain 0.5--2% wet wt. of glycogen. Glycogen synthesis in the hepatocytes from such rats, after prior depletion of the glycogen by glucagon injection, was studied. As distinct from cells from normal animals, there was no glycogen synthesis from glucose as sole substrate, even at concentrations of 60 mM. When supplied with glucose, a gluconeogenic precursor (lactate, dihydroxyacetone or fructose), and with glutamine there was concurrent synthesis of glucose and of glycogen. Without glutamine there was little or no glycogen synthesis. The rate of glycogen formation was in the same range as for cells from control rats. Glutamine addition markedly activated glycogen synthase in cells of starved diabetic rats, but there was no effect on phosphorylase. We obtained very little synthesis of glycogen with hepatocytes from fed diabetic rats, whereas with normal animals, synthesis by such cells equals or exceeds that obtained from starved rats. The conversion of synthase b (inactive) into the active form was studied in rat liver homogenates. The activation of the synthase in cells from starved diabetic rats is somewhat less than that from normal animals, but that from fed diabetic rats is markedly decreased compared with that in livers of fed control animals or that of starved diabetic animals.     

Different immunolocalizations of cathepsins B, H, and L in the liver

Different localizations of cathepsin B, H, and L in normal rat liver were revealed immunohistochemically with anticathepsin Fab'-horseradish peroxidase conjugates. Staining of cathepsin B was strong in the periportal sinusoids, possibly in Kupffer cells; and weaker in panlobular hepatocytes. Staining of cathepsin H was strong in panlobular hepatocytes, especially in the periphery of the cytoplasm, possibly representing the peribiliary dense bodies; and weaker in periportal sinusoidal cells, possibly Kupffer cells. Staining of cathepsin L was strongest in centrilobular hepatocytes and weaker in periportal sinusoidal cells, possibly Kupffer cells. These findings, revealed for the first time in the present study, show that the histologic and intracellular localizations of the three cathepsins are different, suggesting that they have different roles in degradation of exogenous and endogenous proteins.