Morphometric analysis of hepatocytes from rats subjected to compound 48/80-induced anaphylactic shock

Morphometric and biochemical techniques were used to analyze hepatic glycogen, endoplasmic reticulum, and mitochondrial matrix granules in rats treated with compound 48/80 to induce an anaphylactic-like state of shock. Thirty minutes after insult there was a significant decrease in glycogen and mitochondrial matrix granules, an increase in rough endoplasmic reticulum (RER), and no change in smooth endoplasmic reticulum (SER). Less glycogen in experimental rats substantiated a previously described glycogenolytic response to compound 48/80. The decrease in matrix granules implies a loss and/or shift in intramitochondrial calcium as occurs in epinephrine-induced glycogenolysis in the rat. Since other glycogenolytic agents, e.g. glucagon, and starvation stimulate an increase in SER presumably from RER, the present morphological data suggest the increase in RER may precede proliferation of SER from RER.     

Hepatic microsomal alterations during Dipetalonema viteae infection in Mastomys natalensis

The multimammate rat, Mastomys natalensis was used as a model system to evaluate the chronic effects of infection by Dipetalonema viteae on hepatic mixed function oxidase activity. Total hepatic cytochrome P450 content and related total tissue mixed function oxidase activity were decreased to about 50% of control levels at patent phase of infection. The decrease in total tissue mixed function oxidase activity was due to a large decrease in cytochrome P450 concentration in the endoplasmic reticulum. Although the decrease in total liver monooxygenase activity in two substrates aniline and aminopyrine roughly paralleled the loss in cytochrome P450 content, several other microsomal enzyme markers not related to cytochrome P450 monooxygenation were elevated in proportion to total liver microsomal protein content. These results suggest that in M. natalensis during experimental filariasis, there is proliferation of hepatic cells with normal content of endoplasmic reticulum. Furthermore, there appears to be selective toxicity for hepatic cytochrome P450 and related monooxygenase activities. This may compromise the animal's ability to metabolize and dispose of other drugs to which the animals may be exposed in the course of infection.     

Changes in metabolism and hepatic ultrastructure induced by estradiol and testosterone in immature female Epinephelus akaara (Teleostei,Serranidae)

Summary Estradiol injections increase serum level of calcium, amino acid, glucose, protein, ammonia and creatinine in immature Epinephelus akaara, and also increase levels of total lipid, cholesterol, phospholipid and esterified fatty acids. Hepatic protein, glycogen and lipid concentrations also rise after estradiol treatment, and some hepatic enzymes participating in the metabolism of nitrogen, lipid and carbohydrate, show increased activity. Serum vitellogenin levels are increased. Testosterone treatment increases serum protein, total lipid, cholesterol, amino acid and ammonia levels, and also hepatic glycogen content, but in contrast to estradiol treatment, testosterone does not change serum vitellogenin, glucose, calcium, phospholipid, esterified fatty acid and creatinine levels, nor the hepatic lipid and protein content. A small number of hepatic enzymes shows an increased activity. Vitellogenic fish show biochemical changes similar to that of estradiol-treated fish, but are different from those of immature fish. Estradiol treatment induces ultrastructural changes in the hepatocytes of immature fish that are similar to those found in vitellogenic fish. These include a proliferation of rough endoplasmic reticulum and Golgi apparatus, and an increase in glycogen and lipid, all indicative of enhanced metabolic activity.     

Morphometric analysis of fetal rat hepatocytes cultured in monolayer or following gyratory shaking

The stereological technique was used to quantify glycogen areas and endoplasmic reticulum in fetal rat hepatocytes cultured for 24 hr in monolayer (monolayer cells) or following shaking by gyratory rotation (shaken cells). The volume density and volume per cell of glycogen areas decreased in order of freshly isolated hepatocytes, monolayer cells, and shaken cells. The surface density and area per cell of smooth endoplasmic reticulum increased in order of freshly isolated cells, monolayer cells, and shaken cells. The results show that the decrease of glycogen areas and proliferation of the smooth endoplasmic reticulum are more prominent in shaken cells than in monolayer cells. Prominent proliferation of the smooth endoplasmic reticulum in shaken cells may be due to the consumption of glycogen for energy release as a result of gyratory rotation.     

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.     

Hepatic functional and pathological changes of type 1 diabetic mice in growing and maturation time

To detect the changes in the liver function in both male and female OVE26 mice from young to adults for better understanding of type 1 diabetes‐induced hepatic changes, OVE26 mice and wild‐type FVB mice were raised in the same environment without any intervention, and then killed at 4, 12, 24 and 36 weeks for examining liver's general properties, including pathogenic and molecular changes. The influence of diabetes on the bodyweight of male and female mice was different. Both male and female OVE26 mice did not obtain serious liver injury or non‐alcoholic fatty liver disease, manifested by mild elevation of plasma alanine transaminase, and less liver lipid content along with significantly suppressed lipid synthesis. Uncontrolled diabetes also did not cause hepatic glycogen accumulation in OVE26 mice after 4 weeks. Oxidative stress test showed no change in lipid peroxidation, but increased protein oxidation. Changed endoplasmic reticulum stress and apoptosis along with increased antioxidant capacity was observed in OVE26 mice. In conclusion, uncontrolled type 1 diabetes did not cause hepatic lipid deposition most likely because of reduced lipids synthesis in response to insulin deficiency. Enhanced antioxidant capacity might not only prevent the occurrence of severe acute liver injury but also the self‐renewal, leading to liver dysfunction.     

Potentiating effects of methylxanthines on teratogenicity of mitomycin C in mice

A previous study demonstrated that caffeine strongly potentiated the teratogenic action of mitomycin C in mice. In the present study the effect of methylxanthines including caffeine, theophylline, theobromine (theobromine sodium salicylate), paraxanthine, and 1-methylxanthine was compared in order to analyze the structure-activity relationship. Jcl:ICR mice were injected IP with 3 mg/kg of mitomycin C, immediately followed by SC injection of each methylxanthine on day 11 of gestation. The doses of methylxanthines were calculated so that the mice received 50 mg/kg of caffeine or the equimolecular amount of the other methylxanthines. Fetuses were examined for external malformations on day 18 of gestation. Mitomycin C at 3 mg/kg and the methylxanthines at the doses used were not teratogenic. Combined administration of caffeine or theophylline with mitomycin C produced more than 80% of malformed fetuses. Although less effective than caffeine or theophylline, paraxanthine also significantly increased the incidence of malformed fetuses. Theobromine and 1-methylxanthine were virtually ineffective. From these findings, it is suggested that the methyl group at N-1 position of the xanthines is important for the enhancement but the N-1 methylation alone is ineffective unless accompanied with the substitution of the methyl moiety at the other position(s).     

Inhibitors in tea of intestinal absorption of phenylalanine in rats

This work studies the effect of tea extract on the mucosal and serosal transport of phenylalanine, and attempts to identify the active ingredient(s) therein by studying the effect of known tea constituents like theophylline, caffeine and tannic acid. Tea and all the constituents tested inhibited the mucosal uptake of phenylalanine. The serosal transport was unaffected by caffeine and tannic acid, but inhibited by theophylline and high concentrations of tea. The in vitro activity of the intestinal Na⁺-K⁺ ATPase was also assayed from a jejunal homogenate in presence of theophylline, caffeine, tannic acid and cAMP. All were found to inhibit significantly the enzyme. The in vitro activity of a purified Na⁺-K⁺ ATPase was however stimulated by theophylline and caffeine, and inhibited only by tannic acid. It was concluded that the inhibitory effect of tea is exerted mainly through its constituents which inhibit the Na⁺-K⁺ pump directly (tannic acid) or indirectly (theophylline and caffeine), possibly by elevating cAMP levels, dissipating thus the sodium gradient needed for the mucosal uptake of the amino acid.     

The sequential restoration of plasma metabolite levels,liver composition and liver structure in refed carp,Cyprinus carpio

Effect of realimentation was studied on the structure and function of liver tissue of carp,Cyprinus carpio. Yearling carp, after a 3-month starvation period, were renourished at a feeding rate of 1% body weight per day. Samples were taken at refeeding days 0, 1, 2, 5, 22 and 78. Analyses were made of blood metabolites, liver RNA, DNA, lipids, glycogen and protein and of liver enzyme activities. Additionally, liver cytology was examined by means of qualitative and quantitative electron microscopy. The early refeeding period (up to day 5) was characterized by a fast recovery of plasma metabolite concentrations (protein, total lipids, free fatty acids, glucose), a drastic augmentation of hepatic glycogen reserves, and a pronounced increase of total liver weight and liver-somatic index. Constant values of total hepatic DNA showed that liver weight augmentation was not due to cell proliferation, but to a pronounced enlargement of the existing hepatocytes. Major hunger-related structural modifications of carp hepatocytes such as enlarged mitochondria or prominence of the lysosomal compartment were reversed. A significant volume increase of cell nuclei, together with a particularly strong elevation of hepatic RNA concentrations during initial realimentation suggest an immediate stimulation of protein synthesis. Since the cisternae of the endoplasmic reticulum were not reconstituted during that early phase, protein synthesis may have been executed mainly by free ribosomes. With prolonged realimentation, the volume of the endoplasmic reticulum as well as total and relative contents of liver soluble protein continuously increased, whereas RNA concentrations decreased again. An enforcement of liver oxidative capacity was indicated by the augmentation of cellular number and volume of mitochondria. The activities of the enzymes glucose-6-phosphate dehydrogenase and malic enzyme, which convert excess energy into NADPH, increased steadily. Concomitantly, hepatic lipid accumulation was enhanced. In conclusion, liver metabolism during the early recovery phase seems to be dominated both by repair processes and by intensive protein and glycogen synthesis. The liver slows down these processes during prolonged refeeding and directs an increasing percentage of energy and metabolites toward the generation of reducing equivalents and lipid reserves.Abbreviations BW body weight - ER endoplasmic reticulum - FFA free fatty acids - G6PDH glucose-6-phosphate dehydrogenase - LSI liver somtic index - LW liver weight - ME malic enzyme Presented in part as poster abstract at the International Congress on Research in Aquaculture: Fundamental and Applied Aspects. Antibes, France, 6–10 October, 1991     

Intraluminal hydrogen peroxide induces a permeability change of the endoplasmic reticulum membrane

Gulonolactone treatment of mice resulted in the elevation of hepatic ascorbate and hydrogen peroxide levels accompanied by transient liver swelling and reversible dilatation of endoplasmic reticulum cisternae. Although a decrease in glutathione (reduced form)/total glutathione ratio was observed in microsomes, the redox state of luminal foldases remained unchanged and the signs of endoplasmic reticulum stress were absent. Increased permeability of the microsomal membrane to various compounds of low molecular weight was substantiated. It is assumed that Gulonolactone-dependent luminal hydrogen peroxide formation in the endoplasmic reticulum provokes a temporary increase in non-selective membrane permeability, which results in the dilation of the organelle and in enhanced transmembrane fluxes of small molecules.     

Mixed function oxidases from germinating castor bean endosperm

Homogenates from germinating castor bean endosperm were fractionated by sucrose density gradient centrifugation and examined for mixed function oxidase activity. Activity of cinnamic acid 4-hydroxylase and p-chloro-N-methylaniline N-demethylase was highest in the endoplasmic reticulum fraction. Activity of both enzymes is dependent on NADPH and on molecular oxygen; both activities are inhibited by carbon monoxide. When challenged with a number of potential inhibitors the enzymes responded in ways fairly typical of mixed function oxidases from other plants and animals. The N-demethylase appears to be specific for N-methylarylamines. In the absence of NADPH, cumene hydroperoxide is able to support N-demethylation. The mechanistic significance of this activity is discussed.     

Effect of cyclic AMP,theophylline and caffeine on the glucose repression of sporulation inSaccharomyces cerevisiae

Summary Repression of the sporulation ability ofSaccharomyces cerevisiae by glucose present in the presporulation medium was studied. Glucose lowered sporulation ability when added to the presporulation medium containing yeast extract but did not do so when added to the presporulation medium without glucose. The glucose-repressed sporulation ability was recovered by the addition of cyclic AMP, and theophylline or caffeine to the presporulation culture. Theophylline promoted the action of cyclic AMP, but caffeine did not. The effect of caffeine to reverse glucose repression was greater than that of cyclic AMP and theophylline.     

Action of cyclic nucleotide phosphodiesterase inhibitors on the acetylcholine potential

A study was made of the action of theophylline, isobutyrylmethylxanthine and caffeine on the sensitivity of mouse diaphragmatic muscle fibers to iontophoretically applied acetylcholine (ACh). It was shown that these substances at concentrations of 5 X 10(-4) -5 X 10(-3) M reduced the amplitude and increased the duration of the ACh potential as well as accelerated desensitization of the cholinoceptor at repetitive application of ACh. As regards the action on the ACh potential amplitude two phases which differed in the time-course of development and washing were recognized: rapid and slow. Addition of dibutyryl-cAMP (5 X 10(-4) M) after theophylline (10(-3) M) potentiated the latter's action on the ACh potential amplitude but did not influence its duration and the rate of desensitization. It is assumed that the action of phosphodiesterase inhibitors on the duration of the ACh potential and the rate of desensitization is not mediated by an elevation in the muscle cAMP content. Apparently, cAMP accumulation may be responsible but for the phase of a slow decrease in the ACh potential amplitude.     

Hormonal control of leydig cell differentiation

Summary The fine structure of the testicular interstitial cells of the 9-day-old mouse submitted to stimulation with human chorionic gonadotropin (HCG) is reported. As was previously described (Baillie 1964) the interstitial tissue of the prepubertal mouse testis is characterized by the presence of well differentiated epithelioid cells at a quiescent stage. They are characterized by large cytoplasmic depots of lipid droplets and glycogen particles in contrast to poorly developed membranous organelles. These cells are highly sensitive to the action of gonadotropins. Five daily injections of HCG cause their differentiation into cells with active secretory characteristics. The gonadotropin induces a marked depletion of the lipid droplets and glycogen content of the cytoplasm, concurrent with an unusual development of the membranes of the agranular endoplasmic reticulum. Golgi complexes and rough reticulum are prominent. Several changes also appear in the nucleus, especially in the nucleolus.The correlation of the present electron microscopic study of the interstitial cells under HCG stimulation with previous biochemical and physiological findings tentatively suggests that the immature Leydig cells exhibit the basic organization necessary for biosynthesis of steroid hormones.     

Methylxanthine effects on cyclic adenosine 3':5' monophosphate phosphodiesterase activity in preparations of neonatal rat cerebellum: modification by trifluoperazine

Paradoxically, caffeine was found to stimulate the activity of 3′:5′-cyclic AMP phosphodiesterase at substrate concentrations of 14μM, in cerebellar tissue from 10-day-old rats. Pretreatment with trifluoperazine, an inhibitor of calmodulin-dependent enzyme activation, converted the stimulatory effect of caffeine to the expected inhibitory action. Trifluoperazine pretreatment also increased the inhibitory action of theophylline on the cerebellar phosphodiesterase, but had no effect on the inhibitory action of 3-isobutyl-1-methylxanthine. It is suggested that caffeine and to a lesser extent theophylline in addition to their intrinsic phosphodiesterase inhibitory activity can also cause calmodulin dependent effects on cerebellar phosphodiesterase due to calcium mobilisation.     

Increased liver glycogen levels enhance exercise capacity in mice

Muscle glycogen depletion has been proposed as one of the main causes of fatigue during exercise. However, few studies have addressed the contribution of liver glycogen to exercise performance. Using a low-intensity running protocol, here, we analyzed exercise capacity in mice overexpressing protein targeting to glycogen (PTG) specifically in the liver (PTG^OE mice), which show a high concentration of glycogen in this organ. PTG^OE mice showed improved exercise capacity, as determined by the distance covered and time ran in an extenuating endurance exercise, compared with control mice. Moreover, fasting decreased exercise capacity in control mice but not in PTG^OE mice. After exercise, liver glycogen stores were totally depleted in control mice, but PTG^OE mice maintained significant glycogen levels even in fasting conditions. In addition, PTG^OE mice displayed an increased hepatic energy state after exercise compared with control mice. Exercise caused a reduction in the blood glucose concentration in control mice that was less pronounced in PTG^OE mice. No changes were found in the levels of blood lactate, plasma free fatty acids, or β-hydroxybutyrate. Plasma glucagon was elevated after exercise in control mice, but not in PTG^OE mice. Exercise-induced changes in skeletal muscle were similar in both genotypes. These results identify hepatic glycogen as a key regulator of endurance capacity in mice, an effect that may be exerted through the maintenance of blood glucose levels.     

Fine structure of hepatocytes from fasted and fed rats.

The fine structure of hepatocytes from rats maintained on a controlled feeding schedule are described. Liver samples were processed for electron microscopy, histochemistry and chemical determinations of glycogen at precise time-intervals following a 30-hour fast and a 2-hour meal. Hepatocytes from 30-hour-fasted rats with extremely low hepatic glycogen levels were devoid of glycogen particles. Centrilobular cells showed areas of the cytoplasm rich in vesicles of smooth endoplasmic reticulum (SER) while periportal hepatocytes contained less extensive regions of SER. Soon after feeding the fasted rats, glycogen particles appeared in regions of the cell rich in SER. Centrilobular hepatocytes contained numerous glycogen areas which were infiltrated with tubules of SER, while periportal cells showed dense glycogen deposits with SER restricted to the periphery of the masses of glycogen. Throughout glycogen deposition each glycogen particle was closely associated with membranes of SER until maximum glycogen deposition was achieved 12 hours after initiation of feeding. At this point SER was reduced to the lowest amounts of the time-periods studied. During stages of glycogen depletion SER proliferated and reached the highest concentration measured in this study. Tubules of SER were present throughout the glycogen masses of centrilobular hepatocytes, whereas in periportal cells the organelle was restricted to the periphery of the glycogen masses. It is concluded that SER is associated with glycogen particles in rat hepatocytes during both deposition and depletion of glycogen.