Effects of calcium loading and impaired energy production on metabolic and ultrastructural features of cell injury in cultured neonatal rat cardiac myocytes

We evaluated the contributions of calcium loading and impaired energy production to metabolic and ultrastructural manifestations of cell injury in a cultured neonatal rat ventriculocyte model. Direct calcium loading was produced by incubation in K(+)-free medium to inhibit the Na+,K(+)-ATPase and promote Na(+)-Ca2+ exchange, and inhibition of energy metabolism was produced by incubation with 30 microM iodoacetic acid (IAA). Measurements were made of total cell calcium, [3H] arachidonic acid (AA) release (an index of membrane phospholipid degradation), ATP, and ultrastructural features of cell damage. Inhibition of the Na(+),K(+) pump resulted in the rapid onset of cellular calcium loading, increased [3H]AA release, and moderate ATP reduction. After return to control medium for 24 hours, myocytes previously exposed to K(+)-free medium for 1 hour showed recovery of ATP level and little additional [3H]AA release. However, after 2 to 3 hours of calcium loading, the ATP level remained moderately depressed, residual [3H]AA release was greater, and a mixed population of relatively normal and severely damaged myocytes was observed by electron microscopy. IAA treatment for 1 hour resulted in moderate ATP reduction without calcium accumulation or [3H]AA release, whereas IAA treatment for 3 hours resulted in marked ATP reduction associated with calcium accumulation and [3H]AA release. Reversal experiments showed substantial recovery of ATP level after 1 hour of IAA exposure, and marked ATP depression and [3H]AA release associated with widespread irreversible injury after 3 hours. Thus, the data indicate that increased calcium accumulation itself can initiate accelerated membrane phospholipid degradation, but that progression to irreversible injury is influenced by other factors, including the magnitude of ATP depression associated with calcium loading.     

Association between inhibition of arachidonic acid release and prevention of calcium loading during ATP depletion in cultured rat cardiac myocytes.

The development of irreversible myocardial ischemic injury is associated with progressive degradation of membrane phospholipids, accumulation of arachidonate and other free fatty acids, and electrolyte derangements, including calcium accumulation. To study the relationship between arachidonate release and calcium loading during adenosine triphosphate (ATP) depletion in cardiac myocytes, the effects of two purported phospholipase inhibitors, mepacrine and U26,384, were evaluated. Cultured neonatal rat ventricular myocytes were pretreated for 90 minutes with 5 to 10 microM U26,384 (a steroidal diamine) or 10 to 50 microM mepacrine (an alkyl acridine) and then treated for 3 hours with 30 microM of the metabolic inhibitor, iodoacetic acid (IAA), with or without an additional dose of drug. IAA treatment resulted in a marked reduction in ATP level and a several-fold increase in free fatty acid radioactivity released from myocytes prelabeled with tritiated arachidonic acid (3H-AA). U26,384 produced substantial inhibition of the increased 3H-AA release, and was effective when given as a single pretreatment dose before IAA exposure or as continuous treatment before and during IAA exposure (for example, with 5 microM U26,384, the percentage of 3H-AA release versus IAA alone was 8% +/- 2% [SEM] [N = 15] for pretreatment only and 13% +/- 4% [N = 10] for continuous treatment). Mepacrine also resulted in significant reduction in 3H-AA release, but was more effective when given as continuous treatment (for example, with 50 microM mepacrine, the percentage of 3H-AA release versus IAA alone was 43% +/- 9% [N = 6] for pretreatment only and 22% +/- 7% [N = 9] for continuous treatment). More detailed analysis showed that U26,384 and mepacrine blocked the IAA-induced redistribution of 3H-AA into free fatty acids from other lipid species. Electron probe x-ray microanalysis of freeze-dried cryosections revealed marked electrolyte derangements in myocytes exposed to IAA, including a 24-fold increase in cellular Ca, a four fold increase in cellular Na, and a seven fold decrease in cellular K, and associated changes in cytoplasm and mitochondria. U26,384 treatment markedly reduced these electrolyte abnormalities, and maintained normal Ca levels in some protocols. Mepacrine treatment was less effective, but did produce normal Ca levels in 50% of myocytes. Prevention of IAA-induced cellular hypercontraction and blebbing also was observed. These data support the hypothesis that reduction of free fatty acid accumulation by inhibition of accelerated phospholipid degradation is associated with protection of myocytes from calcium loading and morphologic damage during inhibition of ene     

The Initial Phase of Myocardial Reperfusion Is Not Associated With Aggravation of Ischemic-Induced Ultrastructural Alterations in Isolated Rat Hearts Exposed to Prolonged Global Ischemia

The present study focuses on the qualitative and sequential development of myocardial ultrastructural changes during the first 10 min of reperfusion in isolated rat hearts exposed to 60 min of global ischemia. The frequency of and the association between ultrastructural changes were examined by semiquantitative morphometry using the micrograph as unit. In each micrograph the subcellular components of the myocytes (sarcolemma, mitochondria, myofilaments and nucleus) and the endothelial cells were evaluated and graded as slightly, moderately, or severely altered. Ischemia alone induced moderate to severe ultrastructural alterations. The myocytes revealed sarcolemmal disattachment or rupture. The myocytic mitochondria had a clear matrix with abundant broken cristae and amorphous matrix densities. The myofilamental pattern was irregular or even disrupted, and most nuclei had reduced density and showed margination of chromatin. The endothelium showed vacuolization, rupture of the plasma membrane, and extracellular accumulation of cellular debris. During the first 2 min of reperfusion severe ultrastructural alterations were partly reversed. After 10 min of reperfusion both the frequency and grade of myocardial ultrastructural alternations were similar to that observed after ischemia. Cristal adhesions occurred predominately during reperfusion and were associated with moderately and severely altered myocytic mitochondrial alterations. In conclusion, the results showed that ischemic-induced ultrastructural alterations were transiently improved upon reperfusion. With exception of the development of cristal adhesions, the acute phase of reperfusion was not associated with additional ultrastructural changes in isolated buffer-perfused rat hearts exposed to prolonged ischemia.     

低温存活猫肾亚细胞Ca2+浓度变化的X-射线微区分析

随着肾离体低温保存时间的延长，细胞内钙离子沉积而导致细胞损伤，影响肾脏整体功能的保存情况以及移植后肾脏的存活率，本地家猫肾脏离体后冲洗至灰白，然后置于改良Collins II保存液中低温存活，保存0，24，48，72h以后，应用Ca^2 细胞化学探针（Calcium cytochemical probe)及X－射线微区分析技术（X－ray microanalysis of microsections)检测肾小管上皮细胞亚细胞水平的钙离子浓度变化，肾脏经过不同时间体外存活以后，细胞核和内质网中钙离子浓度没有明显的变化，而线粒体和细胞溶质中钙离子浓度显著地呈现出线性升高，结果表明，随着肾脏保存时间延长，细胞溶质钙离子浓度升高源于细胞内储存的钙离子释放，正常生理条件下在细胞信息传递中充当“钙库”的线粒体和内质网在低温导致的细胞溶质内钙离子浓度上升中不表现出钙源特性。     

Altered calcium homeostasis in irreversibly injured P388D1 macrophages.

Sequestration of calcium by mitochondria is an important mechanism to maintain normal intracellular calcium homeostasis. Anoxic or toxic damage to these organelles has been postulated to disrupt intracellular calcium compartmentalization, leading to cell death. The authors examined the potential relationship between mitochondrial dysfunction, altered calcium homeostasis, and irreversible injury in a model system of silica-induced toxicity to P388D1 cells. Exposure to toxic silica particles, but not to nontoxic latex heads, disrupted mitochondrial membrane potential, increased membrane-associated calcium, elevated free cytosolic calcium, and killed 50% to 60% of the cell population after 6 to 8 hours. To test whether disruption of the mitochondrial membrane potential was sufficient to cause irreversible injury, P388D1 cells were exposed to either the proton ionophore, carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) or to the mitochondrial inhibitor, antimycin A. Over 90% of the treated cells showed depolarization of the mitochondrial membrane as indicated by the fluorescent probe rhodamine 123. Carbonyl cyanide p-trifluoromethoxyphenylbydrazone also caused an elevation in free cytosolic calcium as monitored by fura-2. However, even after 6 hours of exposure to these proton ionophores or mitochondrial inhibitors, P388D1 cells did not show increased chlorotetracycline (CTC)-induced fluorescence or loss of viability. P388D1 cells exposed to silica have been shown previously to lose 80% of their adenosine triphosphate (ATP) content. The effect of reduced ATP levels on intracellular calcium homeostasis and viability was assessed by exposing P338D1 cells to FCCP in the presence of sodium azide and 2-deoxyglucose, which reduced ATP content by more than 90%. Under these conditions, none of the cells were killed, and only 5.5% showed increased CTC-induced fluorescence after 6 hours. These data indicate that disruption of the mitochondrial membrane potential, even in combination with reduced ATP content, is not sufficient to kill P388D1 cells.     

The effects of ultraviolet C radiation on the ultrastructure of the liver cells of mole rats

The aim of this study was to elucidate the ultrastructural changes in the liver cells of mole rats (Spalax leucodon) exposed to ultraviolet radiation (UVR). Thirteen mole rats used in this study were caught from nature. They were divided into four groups. The first group was separated as a control and was not given any radiation. The rest were exposed to ultraviolet C (UVC) radiation for 7, 14, and 21 days. The electron microscopic examinations revealed that significant ultrastructural changes occurred in the liver tissue. These changes were the reduction in cytoplasmic organelles, dilatation in rough endoplasmic reticulum, impairment of nucleus membrane, and broadened and vacuolated mitochondria in the cytoplasm. Also, UVC radiation caused significant changes in liver enzymes of aspartate aminotransferase, alanine aminotransferase, alkaline phosphatase, and gama-glutamiltransferase values. After long-term exposure to radiation, some excessive ultrastructural changes occurred. These results indicated that longer exposure to UVR would cause more ultrastructural effects on the liver cells and liver enzymes.     

心肌不同缺血阶段超微结构改变及Ca^2^＋分布特点

观察了３３只家兔心肌不同缺血时间，再灌注３０ｍｉｎ后，心肌超微结构改变及Ｃａ＾２＾＋分布特点。缺血１５ｍｉｎ再灌注后，心肌结构接近正常，但肌纤维膜上Ｃａ＾２＾＋分布数量却低于正常心肌。缺血３０－４５ｍｉｎ，亚细胞结构发生了严重变性，大多数细胞肌纤维膜上Ｃａ＾２＾＋消失。再灌注后大量Ｃａ＾２＾＋以丛状形式沉积于线粒体内，称为不可逆损伤的边缘。缺血６０和７５ｍｉｎ与再灌注后，可见肌纤维膜断裂并完全失去     

Status epilepticus: the reversibility of calcium loading and acute neuronal pathological changes in the rat hippocampus

Light and electron microscopy (with the combined oxalate-pyroantimonate technique for the electron microscopic visualization of intracellular calcium) were used to compare the hippocampal pathology in rats killed immediately after 1.5-2 h of L-allylglycine-induced seizures with that in rats allowed 15-60 min of a seizure-free "recovery" period before perfusion fixation. Following 1.5 h of seizure activity, cellular pathology included astrocytic swelling and dark cell degeneration of pyramidal and polymorphic neurons. This was accompanied by a marked increase in the amount of calcium pyroantimonate deposits, particularly in swollen and disrupted mitochondria of CA1 and CA3 basal dendrites and in certain neuronal cell bodies in the CA1 and CA3 regions and the hilus. After a seizure-free period of between 30 and 60 min the hippocampi showed almost complete recovery except for a few remaining dark, shrunken cells. The majority of these were presumed to be interneurons. The ultrastructural changes were consistent with the observations by light microscopy. By 60 min, excess calcium deposits had disappeared except in the dark cells in which intracellular vacuoles retained deposits. We conclude that most of the pathological changes observed after 1.5 h of L-allylglycine induced status epilepticus, including the mitochondrial calcium "overload" are reversible. At 1 h after termination of status epilepticus apparently irreversible pathology (dark cell change, "ischaemic cell change") concerns predominantly the polymorphic neurons.     

镉对雄性大鼠颌下腺颗粒曲管细胞线粒体的损伤及雄激素保护作用

目的探讨小剂量氯化镉对颌下腺颗粒曲管（GCT）细胞线粒体的损伤及丙酸睾酮的保护作用。方法35只雄性Wistar大鼠分为3组：对照（C）组、镉（Cd）组和镉加丙酸睾酮（CA＋T）组。利用透射电镜作颌下腺GCT细胞线粒体的超微结构观察，并利用image-plus-pro全自动图像分析系统作线粒体损伤的定量研究。结果镉注射后24h,GCT细胞内出现不同程度的线粒体肿胀和（或）空泡化，胞质和线粒体内可见髓样结构，7～15d后上述改变明显加重，30d后细胞形态仍未恢复正常。Cd＋T组的超微结构损伤较相应CA组轻。CA组在镉注射后3～15d，Gcr细胞线粒体的各项指标与对照组相比均有显著差异（P〈0．05）。CA＋T组仅在镉注射后7d和15d，GCT细胞线粒体比表面显著低于对照组（P〈．05）。结论镉对GCT细胞线粒体的超微结构有损伤作用，补充雄激素对上述损伤有保护作用。     

Ultrastructure of cardiocyte degeneration and myocardial calcification in the dystrophic hamster

The myocardium of the Bio 14.6 cardiomyopathic hamster was examined with the electron microscope to identify cellular and organelle changes during the acute lesioning stage, a period typified by concomitant cardiocyte destruction and calcium elevation. Most cardiocytes retained their normal histologic and ultrastructural features, but scattered foci of altered and necrotic cells were observed in association with degenerative calcifying lesions. Prenecrotic alterations of myocytes included cellular edema; varying degrees of distension of sarcoplasmic reticulum and T-tubules; contraction bands and other myofibrillar abnormalities; mitochondrial clustering and hyperplasia; a wide spectrum of mitochondrial changes such as altered sizes, shapes, and cristal patterns, and increases in the number and size of osmiophilic matrix inclusions. Morphologic features consistent with substantial calcium excess were not observed in most altered but prenecrotic cells. Instead, calcium deposition within extruded mitochondria and upon degenerating organelle debris was observed only after cardiocyte disruption. Some calcifying cell remnants were phagocytized by macrophages, whereas large calcified plaques and other deposits remained in the interstitium. Mitochondrial calcification in vascular smooth muscle cells and fibroblasts was evident in highly calcified lesions. These observations suggest that most of the morphologically identifiable calcium deposition present in this cardiomyopathy results from secondary calcification subsequent to sarcolemmal disruption.     

Calcium overload in human giant cell myocarditis.

Myocardial calcium overload was observed in a patient with giant cell myocarditis. The myocardial calcium content estimated by atomic absorption spectrophotometry amounted to 120 mEq/kg dry weight, and the von Kossa stain disclosed multiple foci with patchy calcifications of myocardial fibres. Cytochemical examination of the ultrastructural calcium localisation using the phosphate-pyroantimonate method showed considerable variation in the subcellular calcium distribution. In normal myocytes calcium precipitates were confined to the inner leaflet of the sarcolemma, T-tubules, intercalated disks, and sporadically to mitochondria. In contrast, extensive calcification of mitochondria and loss of sarcolemmal calcium was evident in necrotic myocytes. A number of grossly normal myocytes also showed an increase of calcium precipitates in slightly swollen mitochondria. These findings suggest that myocardial calcium overload in this case started in viable myocytes and was not merely a secondary phenomenon occurring after cell death.     

Mitochondrial alterations in embryos exposed to B-hydroxybutyrate in whole embryo culture

The ketone body B-hydroxybutyrate (B-OHB) produces malformations and ultrastructural alterations in mitochondria of mouse embryos exposed for 24 hours to the compound in whole embryo culture. The present study was conducted to establish the time-course of the mitochondrial changes to determine whether the changes are reversible, and to relate these changes to the malformations produced by the compound. Since mitochondria also play a key role in the metabolism of ketone bodies, the capacity of the early somite embryo to metabolize B-OHB was investigated in an effort to link the morphological alterations in the mitochondria to a biochemical process. Early somite embryos were cultured 4, 8, or 24 hours in the presence of 32 mM DL-B-OHB and then cultured for an additional 24 hours in control serum. Finally, embryonic tissue during the teratogenic period was assessed for its capability to oxidize B-OHB using D-(3-14C)-B-OHB. The treated embryos showed progressive alterations in the mitochondria, beginning at 4 hours with a loss of matrix density and culminating at 24 hours with high-amplitude swelling, complete loss of matrix density, and disappearance of cristae. These alterations were reversible following removal of the embryos after 24 hours of exposure to B-OHB and culturing for an additional 24 hours in control serum. Metabolism studies demonstrated that the early somite embryo possesses a limited capacity to oxidatively metabolize B-OHB. The biochemical implications of these findings are discussed with respect to the possible role of ketone bodies in the mechanism of diabetes-induced congenital malformations.     

Energy dependence of contraction band formation in perfused hearts and isolated adult myocytes.

Aggregation of sarcomeres into contraction bands is a prominent feature of the oxygen paradox, the calcium paradox, and caffeine injury to calcium-free perfused hearts. For investigation of the mechanism of contraction banding, it was necessary to devise a method of evaluating the degree of sarcomere contraction and to define objectively a contraction band. Hearts with mechanical detachment of cells caused by hypocalcemic perfusion and isolated myocytes both allow unrestrained contracture of cells and permit direct optical measurements to quantitate the degree of cell contracture. With the use of the calcium paradox as a model of contraction band necrosis, it was found that cells with lengths of less than 37.3 mu could be considered as containing contraction bands. It was found that the mitochondrial inhibitors cyanide and amytal, as well as the uncoupler 2,4-dinitrophenol, allowed cell contracture but inhibited hypercontracture of sarcomeres into contraction bands during both the calcium paradox and caffeine injury to perfused hearts. However, when 2mM adenosine triphosphate (ATP) was included in the perfusion media, contraction band formation occurred despite the continued presence of cyanide or amytal. In isolated myocyte preparations the addition of the glycolytic inhibitor iodoacetate (IAA, 5 mM) and the mitochondrial inhibitor amytal (3 mM) caused relaxed rod-shaped cells (length/width ratio greater than 3:1) to contract into a stable population of square-shaped forms (length/width ratio less than 3:1), indicating an abrupt and severe decline in cellular ATP levels. Removal of amytal from the incubation medium in the presence of IAA produced a significant conversion of square-shaped cells into round-shaped cells containing contraction bands. Either IAA alone or amytal alone resulted in a mixed population of square and round cells. The results indicate that ATP is required for the formation of contraction bands in intact hearts and for the rounding of isolated myocytes. Formation of contraction bands appears to be an energy-dependent process requiring ATP.     

Effects of calcium depletion and calcium paradox on the ultrastructure of the frog heart

The alterations in the ultrastructure of the isolated perfused Rana ridibunda hearts that were subjected to prolonged calcium depletion and reperfusion with calcium containing medium are described using thin section electron microscopy. Deprivation of calcium resulted in broadened intercellular spaces and in mild cell swelling. Cell to cell contact was maintained throughout calcium depletion, while myofibrils and mitochondria remained intact. Reintroduction of calcium containing buffers to calcium depleted hearts resulted in an irreversible injury of the frog myocardial cells. The main characteristics of the reperfusion induced damage were contraction band formation, distortion and degradation of the myofibrils, extensive swelling of the mitochondria and formation of intramitochondrial electron dense deposits. Mitochondrial aggregation, intermitochondrial junctions, expulsion of the mitochondria to the sarcolemmal membrane and peripheral condensation of nuclear chromatin were also observed. Our results indicate that frog myocardial cells show a marked resistance even to a prolonged calcium depletion, retaining their integrity and their contact. However, the following reperfusion greatly alters the ultrastructure of frog myocardium and the observed alterations are typical of the irreversible damage induced in calcium overload situations.     

Application of stereological analysis of cell volume to isolated myocytes in culture with and without adrenergic innervation.

A three-dimensional analysis to evaluate structural changes in cultured cardiac myocytes following adrenergic innervation was performed using stereological techniques formerly limited to cells in tissue and organs. Cell volumes were calculated for two groups of cells at 96 hours in culture: isolated myocytes and myocytes innervated with adrenergic neurons. Relative and absolute volumes of the nucleus, cytoplasm, and cell were quantified by systematically sampling sections throughout the cell and by point count sampling techniques. Volumetric estimates were similarly determined for the mitochondria, sarcomeres, and other cellular components in the cytoplasm. Data were analyzed with ANOVA and randomized block design to control for variation among the cultures. Adrenergic innervation produced a 44% increase in cell volume, X +/- SEM, (3,344 +/- 196 microns3 to 4,816 +/- 400 microns3, P = 0.007). The absolute volume of mitochondria significantly increased after innervation (521 +/- 42 microns3 to 744 +/- 54 microns3, P less than 0.01). Absolute sarcomere volume did not change significantly (750 +/- 92 microns3 to 642 +/- 1061 microns3, P = 0.14). Other cellular components, defined as all cytoplasmic components except mitochondria and sarcomeres, significantly increased with innervation (1,739 +/- 166 microns3 to 3,097 +/- 338 microns3, P = 0.02). The relative volume of the nucleus and the cytoplasm in the cell remained unchanged following innervation. However, the relative volume of mitochondria decreased by 6%, the percent of the cytoplasm occupied by the sarcomeres decreased by 44%, and the volume occupied by the other cellular components increased by 22%. These findings support the use of stereological analysis as a means to quantify cell volumes of cultured myocytes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reversible Ultrastructural Alterations in the Myocytic Mitochondria of Isolated Rat Hearts Induced by Oxygen Radicals

The present study focuses on reversible mitochondrial ultra-structural alterations in myocardial myocytes that correspond or accompany reversible metabolic depression observed after oxygen radical exposure. The myocytic mitochondrial membranes and matrix of isolated Langendorff-perfused rat hearts were examined by semiquantitative morphometry using the electron micrograph as unit. The hearts were exposed to either standard perfusion (group A), 10 min of oxygen radicals together with superoxide dismutase and catalase followed by 35 min of recovery (group B), 10 min of oxygen radicals alone (group C), or 10 min of oxygen radicals followed by 35 min of recovery (group D). Mitochondrial ultrastructural alterations were detected in only a few micrographs in groups A and B. The frequency of micrographs with mitochondrial ultrastructural alterations was 69% in group C and 62% in group D. In the group exposed to 10 min of oxygen radicals without recovery (group C) condensed pentalaminar membranous profiles arranged in parallel, interpreted to be closely adhering cristae, were detected in the intracristal compartment of myocytic mitochondria in 50% of the micrographs. The cristal adhesions were associated with other mitochondrial ultrastructural changes. Cristal adhesions were not present in group A or B, and were rarely found in the group exposed to 10 min of oxygen radicals followed by 35 min of recovery (group D). Thus, the cristal adhesions appear to be reversible alterations caused by exposure to oxygen radicals.     

Calcium handling by the cat carotid body--a pyroantimonate study

Subcellular regulation mechanisms of calcium concentrations related to oxygen sensing in the carotid body are unclear. In the present study, we investigated the ultrastructural distribution patterns of calcium in carotid body cells and its changes evoked by hypoxia. Carotid bodies were dissected from anesthetized cats exposed in vivo to normoxic or acute hypoxic conditions. We used the oxalate-pyroantimonate technique that yields an electron-opaque calcium precipitate. X-ray microanalysis and appropriate controls confirmed the presence of calcium in the precipitate. Calcium precipitates were found in all types of cells in carotid body parenchyma: chemoreceptor cells, sustentacular cells, and nerve endings. In normoxic chemoreceptor cells, the precipitate was localized in dense core vesicles, mitochondria, and nuclei, but rarely in the cytoplasm. The most apparent effect of hypoxia was disappearance of the precipitate from dense core vesicles and was associated with its appearance in the cytoplasm. The amount of precipitate throughout the carotid body parenchyma was decreased overall due to hypoxia. These results indicate the involvement of subcellular calcium trafficking in hypoxia-sensing in the carotid body. The redistribution pattern of granular calcium deposits from organelles to the cytoplasm of chemoreceptor cells agrees with biochemical data of calcium release from intracellular stores during hypoxia.     

Histopathological and ultrastructural changes in the gills of Poecilia reticulatus induced by an organochlorine pesticide

After exposure to 1.2-3.0 ppb of DDT in an aquatic-terrestrial model ecosystem, the gills of guppies showed histopathological changes when examined by light and electron microscopy. The secondary lamellae of the gills were shortened and deformed and the epithelial cells were disoriented with regard to the pillar cell system. In many places erythrocytes were virtually absent from the blood laguna, which was filled with the flanges of pillar cells. The microfilament bundles in the pillar cell cytoplasm had disintegrated. The chloride cells were swollen and alterations had occurred in their mitochondria and nuclei. The changes did not resemble the typical non-specific pattern of pesticide poisoning, and were probably specific to DDT.     

Ultrastructural and biochemical aspects of liver mitochondria during recovery from ethanol-induced alterations. Experimental evidence of mitochondrial division.

To study the morphologic and biochemical changes occuring in liver mitochondria during recovery from ethanol-induced injury, rats fed a 6-month high-alcohol regimen plus a nutritionally adequate diet which did not induce fatty liver were compared with isocalorically fed controls. After this period the alcohol-fed animals displayed striking ultrastructural changes of liver mitochondria and a decreased respiratory activity with succinate or malate-glutamate as substrate. On the contrary, the respiratory rate with I-glycerophosphate was 50% increased. Regression changes were studied after alcohol was withdrawn from the diet. Enlarged mitochondria rapidly disappeared (in 24 hours), although a few megamitochondria were still present after 8 days of abstinence. A similar recovery was observed for the functional alterations. At the end of the experimental period, only a slight decrease of the maximal respiratory rate using malate-glutamate as a substrate was noted. The ultrastructural findings and the morphometric data suggest that the way in which mitochondrial normalization takes place is based on partition of these organelles.     

EARLY ULTRASTRUCTURAL CHANGES OF EPITHELIAL CELLS OF THE GLANDULAR STOMACH IN RAT INDUCED BY N-METHYL-N'-NITRO-N-NITROSOGUANIDINE

The early ultrastructural events that occur In the gastric epithelial cells of the glandular stomach of rat from 12 hours to 3 weeks after oral administration of N-methyl-N'-nitro-N-nitrosoguanidine were examined and compared with the X-irradiation effects on mouse gastric mucosa. The mucoid cells of the pyloric mucosa, particularly the surface and pit mucous cells exhibited the greatest ultrastructural alterations among the 6 types of gastric epithelial cells. The earliest changes of the mucoid cells were observed in the nuclei, and were characterized by the sequential development of first nucleolar enlargement, which consisted of the increase of both the fibrillar and granular components, followed by the occurrence of nucleolar segregation, reduction and clumping of the chromatin, and irregularity of the nuclear membrane. Significant degenerative changes of the cytoplasm in the mucoid cells could be observed after these nuclear alterations. Later, giant cell formation in the mucoid cells and mesenchymal cells, and the development of epithelial cells containing two cell specificity were found.
These ultrastructural alterations of the mucoid cells seem to represent the morphologic manifestations of biochemical interaction between N-methyl-N'-nitro-N-nitrosoguanidine and biological materials.