Lysosomes in anterior pituitary corticotrophs of the rat. A combined immunocytochemical and enzyme cytochemical study

E600 resistant non-specific esterase activity or acid phosphatase activity were localized in corticotrophic cells identified by postembedding immunocytochemistry (PAP of protein A-immunogold techniques). The lysosomal system of this cell type consists of dense bodies, of a population of small lysosomes mostly situated at the cell periphery in the vicinity of secretory granules as well as of tubular structures. These latter were located either in the central part of the cytoplasm and probably belonged to the Golgi apparatus or at the cell periphery, partly in the extensions. Small lysosomes occurred to be in continuity with enzyme-containing tubules. In a few structures lysosomal enzyme activity and ACTH immunoreactivity overlapped. Some autophagic vacuoles seemed to contain secretory granule matrix. It is suggested that the concept of crinophagy can be extended to the corticotrophs, though the lysosomal system may be involved in the specific function of this cell type by other mechanisms as well.     

LYSOSOMAL PACKAGING IN DIFFERENTIATING AND DEGENERATING ANURAN LATERAL MOTOR COLUMN NEURONS

The role of the Golgi apparatus and the Golgi-endoplasmic reticulum-lysosome complex (GERL) in the genesis of lysosomes was examined in differentiating and degenerating motor neurons of anuran larvae. Acid phosphatase, aryl sulfatase, and thiolacetic acid esterase were utilized as marker enzymes for the lysosomal system, while nucleoside diphosphatase and thiamine pyrophosphatase labeled the inner saccule(s) of the Golgi apparatus. Reduced osmium tetroxide was routinely deposited in the outer Golgi saccule regardless of the state of neuronal maturation. In all young neurons, the disposition of acid hydrolase reaction product paralleled the formation of GERL, with no lytic activity in the Golgi apparatus per se. Hypertrophy of the Golgi apparatus and GERL was observed in the early phases of degeneration, and both organelles apparently exhibit extensive hydrolytic activity. Dense bodies, autophagic vacuoles, and primary lysosomes were found arising from GERL, while the Golgi apparatus may produce primary lysosomal granules during regression. On the other hand, in differentiating neurons, hydrolytic activity was restricted to GERL and an occasional dense body and autophagic vacuole. These studies illustrate a parallelism between the development of GERL and genesis of primary and secondary lysosomes during neuronal cytodifferentiation, and implicate GERL and possibly the Golgi apparatus in lysosomal packaging in degenerating neurons.     

Intracisternal granules in the adipokinetic cells of locusts are not degraded and apparently function as supplementary stores of secretory material

The intracisternal granules in locust adipokinetic cells appear to represent accumulations of secretory material within cisternae of the rough endoplasmic reticulum. An important question is whether these granules are destined for degradation or represent stores of (pro)hormones. Two strategies were used to answer this question. First, cytochemistry was applied to elucidate the properties of intracisternal granules. The endocytic tracers horseradish peroxidase and wheat-germ agglutinin-conjugated horseradish peroxidase were used to facilitate the identification of endocytic, autophagic, and lysosomal organelles, which may be involved in the degradation of intracisternal granules. No intracisternal granules could be found within autophagosomes, and granules fused with endocytic and lysosomal organelles were not observed, nor could tracer be found within the granules. The lysosomal enzyme acid phosphatase was absent from the granules. Second, biochemical analysis of the content of intracisternal granules revealed that these granules contain prohormones as well as hormones. Prohormones were present in relatively higher amounts compared with ordinary secretory granules. Since the intracisternal granules in locust adipokinetic cells are not degraded and contain intact (pro)hormones it is concluded that they function as supplementary stores of secretory material.     

Isolation of autophagic vacuoles from rat liver: morphological and biochemical characterization

The induction of autophagy caused by vinblastine (VBL) has been found to be concomitant with a stimulation of proteolysis in a mitochondrial- lysosomal (ML) fraction from the rat liver (Marzella and Glaumann, 1980, Lab. Invest., 42: 8-17. Marzella and Glaumann, 1980, Lab. Invest., 42:18-27). In this fraction the enhanced proteolysis is associated with a threefold increase in the relative fractional volume of autophagic vacuoles (AVs). In an attempt to isolate the AVs, we subfractionated the ML suspension at different intervals after the induction of autophagy by VBL by centrifugation on a discontinuous Metrizamide gradient ranging from 50% to 15%. The material banding at the 24 to 20% and the 20 to 15% interphases was collected. Morphological analysis reveals that 3 h after induction of autophagy these fractions consist predominantly (approximately 90%) of intact autophagic vacuoles. These autophagic vacuoles contain cytosol, mitochondria, portions of endoplasmic reticulum, and occasional very low density lipoprotein, particles either free or in Golgi apparatus derivatives, in particular secretory granules. The sequestered materials show ultrastructural signs of ongoing degradation. In addition to containing typical autophagic vacuoles, the isolated fractions consist of lysosomes lacking morphologically recognizable cellular components. Contamination from nonlysosomal material is only a few percent as judged from morphometric analysis. Typical lysosomal "marker" enzymes are enriched 15-fold, whereas the proteolytic activity is enriched 10- to 20-fold in the isolated AV fraction as compared to the homogenate. Initially, the yield of nonlysosomal mitochondrial and microsomal enzyme activities increases in parallel with the induction of autophagy but, later on, decreases with advanced degradation of the sequestered cell organelles. Therefore, in the case of AVs the presence of nonlysosomal marker enzymes cannot be used for calculation of fraction purity, since newly sequestered organelles are enzymatically active. Isolated autophagic vacuoles show proteolytic activity when incubated in vitro. The comparatively high phospholipid/protein ratio (0.5) of the AV fraction suggests that phospholipids are degraded more slow than proteins. Is it concluded that AVs can be isolated into a pure fraction and are the subcellular site of enhanced protein degradation in the rat liver after induction of autophagy.     

Diversity of signaling controls of macroautophagy in mammalian cells

Macroautophagy is a major lysosomal catabolic process conserved from yeast to human. The formation of autophagic vacuoles is stimulated by a variety of intracellular and extracellular stress situations including amino acid starvation, aggregation of misfolded proteins, and accumulation of damaged organelles. Several signaling pathways control the formation of autophagic vacuoles. As some of them are engaged in the control of protein synthesis or cell survival this suggests that macroautophagy is intimately associated with the execution of cell proliferation and cell death programs. Whether or not these different signaling pathways converge to a unique point to trigger the formation of autophagic vacuole remains an open question.     

Lysosomal involvement in the removal of clofibrate-induced rat liver peroxisomes. A biochemical and morphological analysis

Peroxisomal proliferators induce in rodents hepatic hyperplasia and hypertrophy; the significant increase in the peroxisomal population is accompanied by specific and reversible induction of some peroxisomal enzymes. In suckling rats born from clofibrate-treated mothers, a massive removal of proliferated organelles occurs within 3 days of recovery. In the present paper we examined the early stages of the recovery period in liver of male rats treated with clofibrate for 5 days. The lysosomal involvement in the removal of drug-induced peroxisomes was investigated under physiological conditions, ie in the absence of inhibitors of the autophagic process. Biochemical results indicate that peroxisomal β-oxidation, but not catalase activity, returns to the control values within the examined period. Total acid phosphatase activity is not affected by clofibrate treatment, but following fractionation on a linear density gradient the lysosomal marker enzyme activity is shifted towards lower density values, particularly at day 1 and 2 of recovery. This class of organelles possibly represents lysosomes involved in active autophagic processes. Acid phosphatase cytochemistry shows an increase of lysosome number at day 1 of recovery. Combination of acid phosphatase cytochemistry either with catalase cytochemistry or with catalase immunogold labelling allows to reveal organelles containing both marker enzymes. These results strongly support the involvement of autophagic processes in the removal of proliferated peroxisomes.     

大鼠睾丸间质细胞的自体吞噬活动

本文结合超微结构和细胞化学观察,研究大鼠睾丸间质细胞(Leydig细胞)中溶酶体的结??构与功能。观察结果表明,大鼠睾丸间质细胞中高尔基体非常发达,在高尔基体的成熟面存在着CMP酶阳性反应的GERL系统,说明这种细胞有不断产生溶酶体的能力。细胞化学结果也证实在睾丸间质细胞有较多的初级和次级溶酶体。睾丸间质细胞不仅有较多的溶酶体,而且还有相当数量的自噬小体,存在着活跃的自体吞噬活动。自噬小体的界膜来源于特化的光面内质网或高尔基体膜囊,包围的内容物主要是光面内质网和少量线粒体。当自噬小体与溶酶体融合后即成为自体吞噬泡,由于酶的消化作用,自体吞噬泡内的细胞器有一系列形态变化。根据CMP酶细胞化学反应,可以区分自噬小体和自体吞噬泡,后者是一种次级溶酶体,呈CMP酶阳性反应。睾丸间质细胞是分泌雄性激素的内分泌细胞,其光面内质网和线粒体在类固醇激素分泌中起重要作用,自体吞噬活动的结果是去除部分内质网和线粒体,可能在细胞水平上起着对雄性激素分泌的调节作用。     

Atypical Granules in the Eyes of the White Mutant of Drosophila melanogaster Are Lysosome-Related Organelles

In the pigment cells of the white mutant of Drosophila melanogaster, as described earlier, two types of abnormal granules are found by conventional electron microscopy. However, both types of abnormal granules, in addition to those in pigment cell invaginations, are also present in the cytoplasm of the photoreceptor cells. Three enzymes (acid phosphatase, peroxidase, and tyrosinase) are localized within the eyes of wild type and white mutant Drosophila melanogaster by electron microscopy. Peroxidase activity is present in lamellar bodies close to the rhabdomeral microvilli of both fly types. However the organelles containing peroxidase activity are 6-fold more frequent in the wild type than in the mutant. Acid phosphatase is present in lamellar bodies between and at the bases of the rhabdomeral microvilli of the wild type, as well as in ommochrome granules of the photoreceptor cells. In the white mutant, however, acid phosphatase was located in electron lucent vacuoles in the cytoplasm of the receptor cells. These acid phosphatase-positive vacuoles also contained both types of abnormal granules. The latter result indicates that abnormal granules in the receptor cells originate from lysosomal degradation and that targeting of lysosomal enzymes is altered in the white mutant. Due to the tyrosinase activity in the hemolymph of flies, the extracellular spaces are electron dense after DOPA incubation. Since some abnormal granules within the photoreceptor cells are not surrounded by an extracellular space, they can be assumed to originate within the photoreceptor cells.     

Lysosomes in the cessation of vitellogenin secretion by the mosquito fat body; selective degradation of Golgi complexes and secretory granules

A massive and selective degradation of Golgi complexes, secretory granules, and RER is the mechanism responsible for the rapid termination of Vg secretion by trophocytes of the mosquito fat body. These cells are involved in an intensive synthesis of a glycoprotein, vitellogenin (Vg), which is accumulated by developing oocytes as yolk protein. Previously, assays for lysosomal enzymes have demonstrated that the cessation of Vg synthesis is characterized by a sharp increase in lysosomal activity; and fluorescent microscopy has shown that, during this intense lysosomal activity, Vg concentrates in lysosomes. In this report, electron microscopy combined with cytochemistry for lysosomal enzymes and localization of Vg with colloidal gold immunocytochemistry has shown that this lysosomal activity is directed towards selective degradation of Vg and organelles associated with its synthesis and secretion. Three organelles undergo lysosomal breakdown: the Golgi complex, Vg-containing secretory granules, and RER. The degradation of Golgi complexes occurs in two steps similar to that for RER: first, the organelle is sequestered by double isolation membranes, and the resulting pre-lysosome then fuses with a primary or secondary lysosome. In contrast, mature Vg-containing secretory granules fuse with lysosomes directly. This combination of crino- and autophagy is a specific, highly intense, and precisely timed event.     

Lysosomal behavior during lateral motor column neurogenesis

Modulations in the total and free activities of acid phosphatase, acid protease, aryl sulfatase, and β-glucuronidase reveal that maximum lysosomal activity accompanies histogenetic cell death within the lateral motor column (LMC) of Rana pipiens larvae. LMC neurogenesis is separable into three distinct periods. In the first, hydrolytic activity remains low through the initial half of the period only to exhibit an exponential rise in the latter half. This increase in acid hydrolase activity continues well into the period of histogenetic cell death (Period 2). At this juncture, lysosomal activity (total and free) reaches a maximum. Subsequently, hydrolytic activity declines with the cessation of neuronal death (Period 3). Activation experiments indicate that lysosomal granules isolated during the cell death period are extremely sensitive to a variety of procedures which disrupt membranes, whereas preparations from younger or older larvae are more stable. Alterations in lysosomal properties are discussed in terms of our present knowledge on lysosomal packaging, activation, and heterogeneity during the course of neural maturation.     

Isolation and characterization of autophagic vacuoles from rat kidney cortex

The number of autophagic vacuoles in the proximal tubule cells of the rat kidney increased considerably after 3 h of vinblastine treatment. This increase was paralleled by stimulated proteolysis in an homogenate prepared from the cortex. We have taken advantage of this expansion in autophagic vacuoles in an effort to isolate these organelles from rat kidney cortex on a discontinuous Metrizamide gradient. Autophagic vacuoles have recently been purified from liver but not from other tissues. The purity of the isolated fraction was 95% of which 55% consisted of typical intact autophagic vacuoles containing sequestered organelles and 45% of other types of secondary lysosome. On plane section many of these displayed one or several intramatrical vesicles or flap like processes forming apparent vesicles at the pole of the organelles, which occasionally contained pinocytosed membranous material. These lysosomes were designated microautophagic vacuoles. It is suggested that the microautophagic vacuoles could be the morphological expression of uptake into lysosomes of small portions of cytosol. The isolated autophagic vacuole fraction was enriched in lysosomal enzymes (acid phosphatase and cathepsin D activities) and displayed high proteolytic rates, especially at acid pH.     

Amino acid control of autophagic sequestration and protein degradation in isolated rat hepatocytes

Sequestration of the inert cytosolic marker [14C]sucrose by sedimentable organelles was measured in isolated rat hepatocytes made transiently permeable to sucrose by means of electropermeabilization. Lysosomal integrity, protein degradation, autophagic sequestration, and other cellular functions were not significantly impaired by the electric treatment. Hepatocytes sequestered sucrose at an initial rate of approximately 10%/h, which is threefold higher than the estimated rate of autophagic-lysosomal protein degradation. Almost one-third would appear to represent mitochondrial fluid uptake; the rest was nearly completely and specifically inhibited by 3-methyladenine (3MA) and can be regarded as autophagic sequestration. A complete amino acid mixture was somewhat less inhibitory than 3MA, and partially antagonized the effect of the latter. This paradoxical effect, taken together with the high sequestration rate, may suggest heterogeneity as well as selectivity in autophagic sequestration. There was no detectable recycling of sequestered [14C]sucrose between organelles and cytosol. Studies of individual amino acids revealed histidine as the most effective sequestration inhibitor. Leucine may have a regulatory function, as indicated by its unique additive/synergistic effect, and a combination of Leu + His was as effective as the complete amino acid mixture. Asparagine inhibited sequestration only 20%, i.e., its very strong effect on overall (long-lived) protein degradation must partially be due to post-sequestrational inhibition. The lysosomal (amine-sensitive) degradation of short-lived protein was incompletely inhibited by 3MA, indicating a contribution from nonautophagic processes like crinophagy and endocytic membrane influx. The ability of an amino acid mixture to specifically antagonize the inhibition of short-lived protein degradation by AsN + GIN (but not by 3MA) may suggest complex amino acid interactions at the level of fusion between lysosomes and other vesicles in addition to the equally complex interactions at the level of autophagic sequestration.     

Coexistence of acid phosphatase and acid mucosubstance in the nucleoid of human blood platelet granules

Summary Fine structural localization of acid phosphatase and acid mucosubstance in the human blood platelet has shown that these two components coexist in the platelet granules. Within the granules acid phosphatase activity and acid mucosubstance both appear confined to the nucleoid region. Additionally, heavy acid phosphatase activity filled occasional small cytoplasmic bodies as well as elongated irregular cell organelles which latter appeared to correspond with atypical granules in morphologic preparations. A complex of mucosubstance with nonenzymatic protein, sequestering the lysosomal enzyme, or a complex of mucosubstance with the enzyme reversibly inactivating it, might explain the cytochemical latency of acid phosphatase in certain lysosomes and the masked dialyzed iron affinity in these sites after glutaraldehyde fixation.     

Autophagy and acid phosphatase activity in the corpora allata of adult mated females of Diploptera punctata

The corpora allata exbibit cycles of synchronous cell growth and atrophy during ovarian cycles in adult females of the cockroach Diploptera punctata. In the present report, the process of synchronous autophagy of organelles which results in cellular atrophy was investigated. In general, unwanted organelles were sequentially sequestered by several different mechanisms and then targeted for destruction. Autophagy was initiated on day 4 when corpus allatum cells were largest and most actively synthesizing juvenile hormone. The first sign of the initiation of autophagy was aggregation of ribosomes in an isolation membrane. By day 5, many organelles were isolated in the autophagic vacuoles. The ribosomecontaining vacuoles were wrapped by flattened stacks of Golgi cisternae to form conspicuous whorl-like autophagosomes. This is a previously undescribed type of autophagic vacuole with the entire complex of Golgi cisternae forming part of the autophagic membranes. Smooth endoplasmic reticulum was wrapped into membranous autophagic vacuoles with concentric arrays of doubel membranes. Plasma membrane was invaginated and then isolated in a multivesicular body. These three different types of isolated vacuoles did not show acid phosphatase activity as indicated by histochemical staining with -glycerophosphate as substrate. Subsequently, these autophagosomes fused with each other and with 1° or 2° lysosomes to form giant autophagolysosomes. Some mitochondria appeared to have coalesced directly into autophagolysosomes. Golgi complexes were evident during this period; they actively participated in making lysosomal enzymes. Cytoskeletons were frequently observed in the vicinity of autophagic vacuoles and were presumably involved in the transport of the vacuoles. As a result of lysosomal degradation lipofuscins and dense bodies were frequently observed by days 9–12 indicating atrophy of corpus allatum cells. Structural parameters, especially those present early in autophagy, such as the isolation membrane, ribosome-containing vacuoles and whorl-like autophagosomes, can be used to search for potential growth regulators responsible for the induction of autophagy, of the corpora allata, and the subsequent termination in juvenile hormone synthesis.     

Lysine suppresses protein degradation through autophagic–lysosomal system in C2C12 myotubes

Muscle mass is determined between protein synthesis and protein degradation. Reduction of muscle mass leads to bedridden condition and attenuation of resistance to diseases. Moreover, bedridden condition leads to additional muscle loss due to disuse muscle atrophy. In our previous study (Sato et al. 2013), we showed that administered lysine (Lys), one of essential amino acid, suppressed protein degradation in skeletal muscle. In this study, we investigated that the mechanism of the suppressive effects of Lys on skeletal muscle proteolysis in C2C12 cell line. C2C12 myotubes were incubated in the serum-free medium containing 10 mM Lys or 20 mM Lys, and myofibrillar protein degradation was determined by the rates of 3-methylhistidine (MeHis) release from the cells. The mammalian target of rapamycin (mTOR) activity from the phosphorylation levels of p70-ribosormal protein S6 kinase 1 and eIF4E-binding protein 1 and the autophagic–lysosomal system activity from the ratio of LC3-II/I in C2C12 myotubes stimulated by 10 mM Lys for 0–3 h were measured. The rates of MeHis release were markedly reduced by addition of Lys. The autophagic–lysosomal system activity was inhibited upon 30 min of Lys supplementation. The activity of mTOR was significantly increased upon 30 min of Lys supplementation. The suppressive effect of Lys on the proteolysis by the autophagic–lysosomal system was maintained partially when mTOR activity was inhibited by 100 nM rapamycin, suggesting that some regulator other than mTOR signaling, for example, Akt, might also suppress the autophagic–lysosomal system. From these results, we suggested that Lys suppressed the activity of the autophagic–lysosomal system in part through activation of mTOR and reduced myofibrillar protein degradation in C2C12 myotubes.     

Tetrandrine blocks autophagic flux and induces apoptosis via energetic impairment in cancer cells

Lysosomes are acidic organelles that have a crucial role in degrading intracellular macromolecules and organelles during the final stage of autophagy. Tetrandrine (Tet), a bisbenzylisoquinoline alkaloid, was reported as an autophagy activator. Here, in contrast with previous studies, we show that Tet is a potent lysosomal deacidification agent and is able to block autophagic flux in the degradation stage. Single-agent Tet induces significant apoptosis both in vitro and in xenograft models. In the presence of Tet, apoptosis was preceded by a robust accumulation of autophagosomes and an increased level of microtubule-associated protein 1 light chain 3, type II (LC3-II). However, Tet increased the level of sequestosome 1 and decreased the turnover of LC3, indicating the blockade of autophagic flux in the degradation stage. As blockade of autophagic flux decreases the recycling of cellular fuels, Tet reduces the uptake of glucose in cancer cells. These effects lead to insufficient substrates for tricarboxylic acid (TCA) cycle and impaired oxidative phosphorylation. Blunting autophagosome formation using 3-methyladenine or genetic knockdown of Beclin-1 failed to rescue cells upon Tet treatment. By contrast, addition of methyl pyruvate to supplement TCA substrates protected Tet-treated tumor cells. These results demonstrate that energetic impairment is required in Tet-induced apoptosis. Tet, as a potent lysosomal inhibitor, is translatable to the treatment of malignant tumor patients.     

Neuronal pigmented autophagic vacuoles: lipofuscin, neuromelanin, and ceroid as macroautophagic responses during aging and disease

The most striking morphologic change in neurons during normal aging is the accumulation of autophagic vacuoles filled with lipofuscin or neuromelanin pigments. These organelles are similar to those containing the ceroid pigments associated with neurologic disorders, particularly in diseases caused by lysosomal dysfunction. The pigments arise from incompletely degraded proteins and lipids principally derived from the breakdown of mitochondria or products of oxidized catecholamines. Pigmented autophagic vacuoles may eventually occupy a major portion of the neuronal cell body volume because of resistance of the pigments to lysosomal degradation and/or inadequate fusion of the vacuoles with lysosomes. Although the formation of autophagic vacuoles via macroautophagy protects the neuron from cellular stress, accumulation of pigmented autophagic vacuoles may eventually interfere with normal degradative pathways and endocytic/secretory tasks such as appropriate response to growth factors.     

In exocrine pancreas, the basolateral endocytic pathway converges with the autophagic pathway immediately after the early endosome

Intracisternal granules (ICGs) are insoluble aggregates of pancreatic digestive enzymes and proenzymes that develop within the lumen of the rough endoplasmic reticulum of exocrine pancreatic cells, especially in guinea pigs. These ICGs are eliminated by autophagy. By morphological criteria, we identified three distinct and sequential classes of autophagic compartments, which we refer to as phagophores, Type I autophagic vacuoles, and Type II autophagic vacuoles. Lobules of guinea pig pancreas were incubated in media containing HRP for periods of 5-120 min to determine the relationship between the endocytic and autophagic pathways. Incubations with HRP of 15 min or less labeled early endosomes at the cell periphery that were not involved in autophagy of ICGs, but after these short incubations none of the autophagic compartments were HRP positive. After 30-min incubation with HRP, early endosomes at the cell periphery, late endosomes in the pericentriolar region, and, in addition, Type I autophagic vacuoles containing ICGs were all labeled by the tracer. Type II autophagic vacuoles were not labeled after 30-min incubation with HRP but were labeled after incubations of 60-120 min. Phagophores did not receive HRP even after 120 min incubations. We concluded that the autophagic and endocytic pathways converge immediately after the early endosome level and that Type I autophagic vacuoles precede Type II autophagic vacuoles on the endocytic pathway. We studied the distribution of acid phosphatase, lysosomal proteases and cation-independent-mannose-6-phosphate receptor (CI-M6PR) in the three classes of autophagic compartments by histochemical and immunocytochemical methods. Phagophores, the earliest autophagic compartment, contained none of these markers. Type I autophagic vacuoles contained acid phosphatase but, at most, only very low levels of cathepsin D and CI-M6PR. Type II autophagic vacuoles, by contrast, are enriched for acid phosphatase, cathepsin D, and other lysosomal enzymes, and they are also enriched for CI-M6PR. Moreover, soluble fragments of bovine CI-M6PR conjugated to colloidal gold particles heavily labeled Type II but not Type I autophagic vacuoles, and this labeling was specifically blocked by mannose-6-phosphate. This indicates that the lysosomal enzymes present in Type II autophagic vacuoles carry mannose-6-phosphate monoester residues. Using 3-C2, 4-dinitroanilino-3'-amino-N-methyldipropylamine (DAMP), we showed that Type II autophagic vacuoles are acidic. We interpret these findings as indicating that Type II autophagic vacuoles are a prelysosomal compartment in which the already combined endocytic and autophagic pathways meet the delivery pathway of lysosomal enzymes.     

Autophagy is disrupted in a knock-in mouse model of juvenile neuronal ceroid lipofuscinosis

Juvenile neuronal ceroid lipofuscinosis is caused by mutation of a novel, endosomal/lysosomal membrane protein encoded by CLN3. The observation that the mitochondrial ATPase subunit c protein accumulates in this disease suggests that autophagy, a pathway that regulates mitochondrial turnover, may be disrupted. To test this hypothesis, we examined the autophagic pathway in Cln3(Deltaex7/8) knock-in mice and CbCln3(Deltaex7/8) cerebellar cells, accurate genetic models of juvenile neuronal ceroid lipofuscinosis. In homozygous knock-in mice, we found that the autophagy marker LC3-II was increased, and mammalian target of rapamycin was down-regulated. Moreover, isolated autophagic vacuoles and lysosomes from homozygous knock-in mice were less mature in their ultrastructural morphology than the wild-type organelles, and subunit c accumulated in autophagic vacuoles. Intriguingly, we also observed subunit c accumulation in autophagic vacuoles in normal aging mice. Upon further investigation of the autophagic pathway in homozygous knock-in cerebellar cells, we found that LC3-positive vesicles were altered and overlap of endocytic and lysosomal dyes was reduced when autophagy was stimulated, compared with wildtype cells. Surprisingly, however, stimulation of autophagy did not significantly impact cell survival, but inhibition of autophagy led to cell death. Together these observations suggest that autophagy is disrupted in juvenile neuronal ceroid lipofuscinosis, likely at the level of autophagic vacuolar maturation, and that activation of autophagy may be a prosurvival feedback response in the disease process.     

Ultrastructural localization of lysosomal enzymes in the egg cortex of Brachydanio

The localization of acid phosphatase (E.C. 3.1.3.2), inorganic trimetaphosphatase (E.C. 3.6.1.2), and aryl sulfatase (E.C. 3.1.6.1) in the cortex of unactivated and activated eggs of Brachydanio was examined by ultrastructural cytochemistry. Using a lead capture method, activity for all three acid hydrolases was demonstrated in organelles of the cortex before and after egg activation. Acid phosphatase (AcPase) reaction product was consistently present in primary lysosomes, secondary lysosomes, multivesicular bodies, and yolk bodies. AcPase activity was absent from mitochondria, profiles of the endoplasmic reticulum, coated pits of exocytosed cortical granules, and coated vesicles. Although most cortical granules of the mature, unactivated egg were unreactive for this enzyme, a few showed AcPase reaction product. It is not clear whether the AcPase-positive granules might be an immature form of cortical granules or a subpopulation of these organelles with lysosomal properties. Most cisternae of the Golgi apparatus did not stain for AcPase; however, reaction product was occasionally localized in a single cisterna as well as several small vesicles at the inner face of the Golgi. The intensity of the reaction product and the pattern of distribution of trimetaphosphatase (Tm-Pase) activity was very similar to that of AcPase. However, TmPase was never observed in cortical granules. Cortices of unactivated and activated eggs showed less overall aryl sulfatase (ArSase) activity when compared with AcPase and TmPase. The presence of ArSase reaction product in lysosomes and multivesicular bodies confirmed the acid hydrolytic nature of these organelles. AcPase and TmPase, and to a lesser extent ArSase, are adequate markers of a cortical lysosomal system in the danio egg.(ABSTRACT TRUNCATED AT 250 WORDS)