The role of the Golgi complex in the isolation and digestion of organelles

Autophagy in the liver: functions in health and disease

The concept of macroautophagy was established in 1963, soon after the discovery of lysosomes in rat liver. Over the 50 years since, studies of liver autophagy have produced many important findings. The liver is rich in lysosomes and possesses high levels of metabolic-stress-induced autophagy, which is precisely regulated by concentrations of hormones and amino acids. Liver autophagy provides starved cells with amino acids, glucose and free fatty acids for use in energy production and synthesis of new macromolecules, and also controls the quality and quantity of organelles such as mitochondria. Although the efforts of early investigators contributed markedly to our current knowledge of autophagy, the identification of autophagy-related genes represented a revolutionary breakthrough in our understanding of the physiological roles of autophagy in the liver. A growing body of evidence has shown that liver autophagy contributes to basic hepatic functions, including glycogenolysis, gluconeogenesis and β-oxidation, through selective turnover of specific cargos controlled by a series of transcription factors. In this Review, we outline the history of liver autophagy study, and then describe the roles of autophagy in hepatic metabolism under healthy and disease conditions, including the involvement of autophagy in α1-antitrypsin deficiency, NAFLD, hepatocellular carcinoma and viral hepatitis.

Mammalian Autophagy: How Does It Work?

Autophagy is a conserved intracellular pathway that delivers cytoplasmic contents to lysosomes for degradation via double-membrane autophagosomes. Autophagy substrates include organelles such as mitochondria, aggregate-prone proteins that cause neurodegeneration and various pathogens. Thus, this pathway appears to be relevant to the pathogenesis of diverse diseases, and its modulation may have therapeutic value. Here, we focus on the cell and molecular biology of mammalian autophagy and review the key proteins that regulate the process by discussing their roles and how these may be modulated by posttranslational modifications. We consider the membrane-trafficking events that impact autophagy and the questions relating to the sources of autophagosome membrane(s). Finally, we discuss data from structural studies and some of the insights these have provided.

Function of human WIPI proteins in autophagosomal rejuvenation of endomembranes?

Despite the availability of a large pool of experimental approaches and hypothetical considerations, the hunt for the enigmatic membrane origin of autophagosomes is still on. In mammalian cells proposed scenarios for the formation of the autophagosomal membrane include both de novo assembly, and rearrangements plus maturation of pre-existing membrane sections from the endoplasmic reticulum (ER), plasma membrane, Golgi or mitochondria. Earlier, we identified the human WD-repeat protein interacting with phosphoinositides (WIPI) family and showed that WIPI proteins function as essential phosphatidylinositol 3-phosphate (PtdIns3P) effectors at the nascent autophagosome. Interestingly, WIPI proteins localize to both pre-existing endomembranes and nascent autophagosomes. In this context, and on the basis of historical records on the formation of autophagosomes, we discuss with appropriate modesty an alternative perspective on the membrane origin of autophagosomes.

Metabolic contribution of hepatic autophagic proteolysis: old wine in new bottles

Pioneering work on autophagy was achieved soon after the discovery of lysosomes more than 50 years ago. Due to its prominent lysosomal activity and technical ease of handling, the liver has been at the center of continuous and vigorous investigations into autophagy. Many important discoveries, including suppression by insulin and plasma amino acids and stimulation by glucagon, have been made through in vivo and in vitro studies using perfused liver and cultured hepatocytes. The long-term controversy about the origin and nature of the autophagosome membrane has finally led to the conclusion of "phagophore," through extensive molecular cell biological approaches enlightened by the discovery of autophagy-essential ATG genes. Furthermore, recent studies using liver-specific autophagy-deficient mice have thrown light on the unique role of a selective substrate of autophagy, p62. The stabilized p62 accumulating in autophagy-deficient liver manipulates Nrf2-dependent transcription activation through specific binding to Keap1, which results in the elevated gene expression involved in detoxification. This is the first example of the dysregulation of gene expression under autophagy deficiency. Thus, basal liver autophagy makes a large contribution to the maintenance of cell homeostasis and health. Meanwhile, precise comparisons of wild-type and liver-specific autophagy-deficient mice under starvation conditions have revealed that amino acids released by autophagic degradation can be metabolized to produce glucose via gluconeogenesis for the maintenance of blood glucose, and can also be excreted to the circulation to supply serum amino acids. These results strongly confirm that induced liver autophagy plays a pivotal role in metabolic compensation. This article is part of a Special Issue entitled: Proteolysis 50 years after the discovery of lysosome.

Oncosuppressive functions of autophagy

Macroautophagy (herein referred to as autophagy) constitutes a phylogenetically old mechanism leading to the lysosomal degradation of cytoplasmic structures. At baseline levels, autophagy exerts homeostatic functions by ensuring the turnover of potentially harmful organelles and long-lived aggregate-prone proteins. Moreover, the autophagic flow can be dramatically upregulated in response to a plethora of stressful conditions, including glucose, amino acid, oxygen, or growth factor deprivation, accumulation of unfolded proteins in the endoplasmic reticulum, and invasion by intracellular pathogens. In some experimental settings, stress-induced autophagy has been shown to contribute to programmed cell death. Nevertheless, autophagy most often confers cytoprotection by providing cells with new metabolic substrates or by ridding them of noxious intracellular entities including protein aggregates and invading organisms. Thus, autophagy has been implicated in an ever-increasing number of human diseases including cancer. Autophagy inhibition accelerates the demise of tumor cells that are subjected to chemo- or radiotherapy, thereby constituting an interesting target for the development of anticancer strategies. However, several oncosuppressor proteins and oncoproteins have been recently shown to stimulate and inhibit the autophagic flow, respectively, suggesting that autophagy exerts bona fide tumor-suppressive functions. In this review, we will discuss the mechanisms by which autophagy may prevent oncogenesis.

Where do they come from? Insights into autophagosome formation

Autophagosomes (APs) are unique organelles that enwrap cytoplasmic components when necessary. APs then fuse with lysosomes and enclosed materials are degraded. Although approximately 30 autophagy-related genes (ATG) required for AP formation have been identified, fundamental questions on the membrane source or dynamics during the formation remain unresolved. Here, we present a comprehensive overview of the putative membrane sources identified to date.

Morpho-physiological analysis of the insect fat body: a review

The insect fat body is the main organ of the intermediate metabolism of insects. The majority of proteins of the haemolymph is synthesized in this tissue, which also presents the functions of lipids, carbohydrates and proteins storage. This tissue is also responsible for the synthesis of vitellogenins, proteins with an important role in the reproduction of the insects, being incorporated into the oocytes during vitellogenesis. The fat body consists of thin layers or strings, generally one or two cells thick, or small nodules suspended in the hemocele through connective tissues and trachea. Within a species, the structure of this tissue is more or less constant, but can have considerable differences between insects of different orders. In this way, this article makes a review about the main morpho-physiological features of the fat body cells of the insects, as well as a phylogenetic study of the fat body between basal and derived species of the Attini tribe ants.

Autophagy as an emerging dimension to adaptive and innate immunity

Autophagy is an evolutionary conserved cellular process during which cytoplasmic material is engulfed in double membrane vacuoles that then fuse with lysosomes, ultimately degrading their cargo. Emerging evidence, however, now suggests that autophagy can form part of our innate and adaptive immune defense programs. Recent studies have identified pattern recognition molecules as mediators of this process and shown that intracellular pathogens can interact with and even manipulate autophagy. Recent translational evidence has also implicated autophagy in the pathogenesis of several immune-mediated diseases, including Crohn disease. In this review, we present autophagy in the context of its role as an immune system component and effector and speculate on imminent and future research directions in this field.

Correlative light and electron microscopy

Autophagy is an intracellular degradative pathway that is essential for cellular homeostasis. Efficient autophagy ultimately relies on the ability of the cell to form autophagosomes, and the efficiency of lysosomal enzymes and lipid hydrolases contained within the autolysosome to degrade sequestered cytosolic material and organelles and recycle these nutrients back to the cytosol. Several assays and techniques to monitor autophagy are available, and these can be quantitative or qualitative, biochemical or morphological. Here we describe a method for monitoring the autophagic process that is based on morphology and the application of both light and electron microscopy, called correlative light and electron microscopy, or CLEM. CLEM provides an advance over either technique (light or electron microscopy) alone and can be performed on any cell or tissue sample, which can be grown or mounted on a gridded coverslip or support compatible with light microscopy. CLEM gives a broad low magnification overview of the cell, allowing an assessment of both spatial and temporal events, as well as providing high-resolution information about individual autophagosomes or single compartments.

Structural polarity and dynamics of male germline stem cells in an insect (milkweed bug Oncopeltus fasciatus)

Knowing the structure opens a door for a better understanding of function because there is no function without structure. Male germline stem cells (GSCs) of the milkweed bug (Oncopeltus fasciatus) exhibit a very extraordinary structure and a very special relationship with their niche, the apical cells. This structural relationship is strikingly different from that known in the fruit fly (Drosophila melanogaster) -- the most successful model system, which allowed deep insights into the signaling interactions between GSCs and niche. The complex structural polarity of male GSCs in the milkweed bug combined with their astonishing dynamics suggest that cell morphology and dynamics are causally related with the most important regulatory processes that take place between GSCs and niche and ensure maintenance, proliferation, and differentiation of GSCs in accordance with the temporal need of mature sperm. The intricate structure of the GSCs of the milkweed bug (and probably of some other insects, i.e., moths) is only accessible by electron microscopy. But, studying singular sections through the apical complex (i.e., GSCs and apical cells) is not sufficient to obtain a full picture of the GSCs; especially, the segregation of projection terminals is not tangible. Only serial sections and their overlay can establish whether membrane ingrowths merely constrict projections or whether a projection terminal is completely cut off. To sequence the GSC dynamics, it is necessary to include juvenile stages, when the processes start and the GSCs occur in small numbers. The fine structural analysis of segregating projection terminals suggests that these terminals undergo autophagocytosis. Autophagosomes can be labeled by markers. We demonstrated acid phosphatase and thiamine pyrophosphatase (TPPase). Both together are thought to identify autophagosomes. Using the appropriate substrate of the enzymes and cerium chloride, the precipitation of electron-dense cerium phosphate granules indicates the presence of enzymes and their location. Because the granules are very fine, they can be easily assigned to distinct cell organelles as the autophagosomes. Two methods, electron microscopy and immunocytochemistry, have pointed out a structural polarity and dynamics that are unprecedented for stem cells. We propose that these dynamics indicate a novel type of signal exchange and transduction between stem cells and their niche.

Endoplasmic reticulum and Golgi complex: Contributions to, and turnover by, autophagy

The degradation of cytoplasmic contents, especially organelles [mitochondria, peroxisomes, endoplasmic reticulum (ER), Golgi complex (GC)], cannot be accomplished solely by the cytosolic degradation machinery, of which the most prominent component is the proteasome. However, it is possible that such organelles (or portions thereof) can be degraded by the cell's autophagic machinery. In this manner, organelles can be either specifically or non-specifically targeted to the vacuole/lysosome for degradation. These processes can be triggered in response to different environmental cues. Here, we focus on two particular organelles, the ER and the GC, and their relationship with the autophagic process. Firstly, we briefly consider how these two organelles contribute to the synthesis and delivery of hydrolytic enzymes involved in autophagy as well as how they may potentially contribute to their own degradation by addressing the origin of the autophagic membrane. Secondly, we summarize the evidence for the turnover of these two organelles by autophagic processes in different organisms.

Starvation and ULK1-dependent cycling of mammalian Atg9 between the TGN and endosomes

Autophagy, fundamentally a lysosomal degradation pathway, functions in cells during normal growth and certain pathological conditions, including starvation, to maintain homeostasis. Autophagosomes are formed through a mechanism that is not well understood, despite the identification of many genes required for autophagy. We have studied the mammalian homologue of Atg9p, a multi-spanning transmembrane protein essential in yeast for autophagy, to gain a better understanding of the function of this ubiquitious protein. We show that both the N- and C-termini of mammalian Atg9 (mAtg9) are cytosolic, and predict that mAtg9 spans the membrane six times. We find that mAtg9 is located in the trans-Golgi network and late endosomes and colocalizes with TGN46, the cation-independent mannose-6-phosphate receptor, Rab7 and Rab9. Amino acid starvation or rapamycin treatment, which upregulates autophagy, causes a redistribution of mAtg9 from the TGN to peripheral, endosomal membranes, which are positive for the autophagosomal marker GFP-LC3. siRNA-mediated depletion of the putative mammalian homologue of Atg1p, ULK1, inhibits this starvation-induced redistribution. The redistribution of mAtg9 also requires PI 3-kinase activity, and is reversed after restoration of amino acids. We speculate that starvation-induced autophagy, which requires mAtg9, may rely on an alteration of the steady-state trafficking of mAtg9, in a Atg1-dependent manner.

1. Membrane origin for autophagy

Autophagy is a degradative transport route conserved among all eukaryotic organisms. During starvation, cytoplasmic components are randomly sequestered into large double-membrane vesicles called autophagosomes and delivered into the lysosome/vacuole where they are destroyed. Cells are able to modulate autophagy in response to their needs, and under certain circumstances, cargoes, such as aberrant protein aggregates, organelles, and bacteria can be selectively and exclusively incorporated into autophagosomes. As a result, this pathway plays an active role in many physiological processes, and it is induced in numerous pathological situations because of its ability to rapidly eliminate unwanted structures. Despite the advances in understanding the functions of autophagy and the identification of several factors, named Atg proteins that mediate it, the mechanism that leads to autophagosome formation is still a mystery. A major challenge in unveiling this process arises from the fact that the origin and the transport mode of the lipids employed to compose these structures is unknown. This compendium will review and analyze the current data about the possible membrane source(s) with a particular emphasis on the yeast Saccharomyces cerevisiae, the leading model organism for the study of autophagosome biogenesis, and on mammalian cells. The information acquired investigating the pathogens that subvert autophagy in order to replicate in the host cells will also be discussed because it could provide important hints for solving this mystery.

Role of the Apg12 conjugation system in mammalian autophagy

The Apg12 system is one of the ubiquitin-like protein conjugation systems conserved in eukaryotes. It was first discovered in yeast during systematic analyses of the apg mutants defective in autophagy, which is the intracellular bulk degradation system. Covalent attachment of Apg12-Apg5 is essential for autophagy. Enzymes catalyzing this conjugation reaction were also identified based on the apg mutant analyses. These are Apg7 and Apg10, corresponding to E1 and E2 enzymes, respectively. Studies using mammalian cells further revealed the function of the Apg12 system. The Apg12-Apg5 conjugate localizes to elongating autophagic isolation membranes. Apg12 conjugation of Apg5 is required for elongation of the isolation membrane to form a complete spherical autophagosome. Discovery of the Apg12 system has facilitated our understanding of the molecular mechanism of autophagosome formation.

Ultrastructural Effects of a Non-Steroidal Ecdysone Agonist, RH-5992, on the Sixth Instar Larva of the Spruce Budworm, Choristoneura fumiferana

Force feeding of RH-5992 (Tebufenozide), a non-steroidal ecdysone agonist to newly moulted sixth instar larvae of the spruce budworm, Choristoneura fumiferana, (Lepidoptera: Tortricidae) initiates a precocious, incomplete moult. Within 6h post treatment (pt) the larva stops feeding and remains quiescent. Around 12hpt, the head capsule slips partially revealing an untanned new head capsule that appears wrinkled and poorly formed. By 24hrpt, the head capsule slippage is pronounced and there is a mid-dorsal split of the old cuticle in the thoracic region but there is no ecdysis. The larva remains moribund in this state and ultimately dies of starvation and desiccation. The temporal sequence of the external and internal changes of the integument were studied using both scanning and transmission electron microscopy. Within 3hpt, there is hypertrophy of the Golgi complex indicating synthetic activity and soon after, large, putative ecdysial droplets are seen. Within 24h, a new cuticle that lacks the endocuticular lamellae is formed. The formation of the various cuticular components, the degradation of the old cuticle and changes in the organelles of the epidermal cells of the mesothoracic tergite are described. The difference between the natural moult and the one induced by RH-5992 are explained on the basis of molecular events that take place during the moulting cycle. The persistence of this ecdysone agonist in the tissues permits the expression of all the genes that are up-regulated by the presence of the natural hormone but those that are turned on in the absence of the hormone are not expressed.

Maturation and degeneration of the fat body in the Drosophila larva and pupa as revealed by morphometric analysis

Using morphometric and cytochemical techniques we have described changes taking place in the fat body cells during three different stages of development. The cell number remains constant at about 2200 cells during larval life and then decreases gradually and continuously throughout metamorphosis and the first 3 days of the adult stage until no more cells can be observed. Cell size increases rapidly during the larval period and decreases steadily during metamorphosis and adult stage. The size of the nuclei increases during the larval instars and decreases during the pupal interval. The change in nuclear size is correlated with the amount of DNA present throughout development implying the nuclear DNA is synthesized during the larval period and degraded gradually during metamorphosis. The cell size changes are due in large part to accumulation or loss of reserve substances: lipid droplets, glycogen deposits and protein granules. During metamorphosis the amount of lipid decreases slightly whereas glycogen experiences two loss cycles. The protein granules in the form of lysosomes continue to increase in amount during the first day of metamorphosis because of a short period of massive autophagy. Then the lysosomes decrease in amount throughout the remainder of metamorphosis. The lysosomes stain positively for lipofuscin.

Cytochemical studies on induced autophagocytosis in mouse exocrine pancreas

1. The origin of the limiting membranes of autophagic vacuoles (AVs) in mouse pancreatic acinar cells was studied in vinblastine-induced autophagocytosis. 2. The marker enzymes used were adenosine triphosphatase, lipase, inosine diphosphatase and thiamine pyrophosphatase. The following impregnation techniques were used: unbuffered osmium tetroxide impregnation, imidazole-buffered osmium tetroxide impregnation and uranyl-lead-copper impregnation. 3. Only a weak lipase activity was observed between the limiting membranes of a few AVs. The AV membranes were stained heavily with all impregnation techniques used. 4. The origin of AV membranes seems to be same in mouse liver and exocrine pancreas in vinblastine-induced autophagocytosis.

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.

Studies on vinblastine-induced autophagocytosis in mouse liver. V. A cytochemical study on the origin of membranes

The origin and the structure of the limiting membranes of autophagic vacuoles (AV) in mouse hepatocytes was studied using cytochemical techniques. Autophagocytosis was induced by an intraperitoneal injection of vinblastine (50 mg/kg). Imidazole-buffered osmium tetroxide impregnation was used as a marker for unsaturated fatty acids, and uranyl-lead-copper impregnation for the determination of possible connections of AV membranes with the other cellular membranes. AV membranes stained strongly with both techniques. The staining pattern of AV membranes differed from that of the other cellular membranes. AV's were frequently seen to fuse with vesicles containing very low density lipoprotein particles. No other connections of AV membranes with other cellular membranes were observed. The results suggest that if pre-existing cellular membranes are used in AV formation some kind of transformation must occur in these membranes during AV formation. The content of unsaturated fatty acids appears to be high in AV membranes.

Localized cell death in Drosophila imaginal wing disc epithelium caused by the mutation apterous-blot

Drosophila melanogaster carrying the mutation apterous-blot have blistered wings. Trypan blue stains a patch of dead cells localized to the wing pouch of imaginal discs and the same area shows acid phosphatase (AcPase) activity suggesting that the cell death is lysosomal. Autophagic vacuoles and other secondary lysosomes show AcPase activity within the disc epithelium and enzyme activity is found in fragments of dead cells which have been extruded basally. The cell death, although extensive and confined to the presumptive wing region, does not result in loss of adult structures.

Cellular autophagocytosis induced by X-irradiation and vinblastine. On the origin of the segregating membranes

Autophagocytosis was induced in cultured, human glial cells by X-irradiation or exposure to vinblastine sulphate. A transmission electron microscopic investigation of the origin of the segregating membranes in the autophagic process was performed by labelling of endocytotic vacuoles and lysosomes with electron-dense marker particles (native and cationized ferritin, colloidal gold and thorium dioxide). Cytochemical demonstration of the lysosomal marker enzyme acid phosphatase and serial sectioning of the cells were also carried out. The majority of newly formed, double-membrane bounded autophagic vacuoles were devoid of markers for both lysosomes and endocytotic vacuoles. Moreover, no evidence of origin from the endoplasmic reticulum was found and the segregating membranes of this type of autophagic vacuoles were, by process of elimination, considered likely to be derived from Golgi vacuoles or, possibly, assembled de novo. Autophagy also appeared to be effected through an alternative pathway involving a lysosomal wrapping or microautophagic mechanism.

Induced autophagocytosis in macrophages. Origin of the segregating membranes

Cultured mouse peritoneal macrophages were exposed for 48 h to a large and toxic dose of polyacrylamide microspheres (previously designed for use as a lysosomotropic carrier for the intracellular delivery of enzymes and other macromolecules). This treatment induced autophagocytosis in the macrophages, which contained abundant autophagic vacuoles at 24 h post exposure. Transmission electron microscopical studies including enzyme cytochemistry showed that the segregating membranes in autophagosome formation consisted of flattened, smooth-surfaced vacuoles with a granular matrix in which reaction product indicating acid phosphatase activity could be demonstrated. The autophagic vacuole formation was apparently effected by wrapping of a portion of the cytoplasm in a sheet formed by flattening and fusion of multiple small vacuoles with acid phosphatase activity in their matrices. The conclusion is drawn that the segregating membranes are derived from lysosomes or GERL structures in this particular system of induced autophagocytosis.

Previtellogenic development and vitellogenin synthesis in the fat body of a mosquito: an ultrastructural and immunocytochemical study

We describe two phases, previtellogenic and vitellogenic, in the activity of the trophocytes in the fat body of the mosquito Aedes aegypti. The previtellogenic phase, leading to trophocyte competence to synthesize vitellogenin (Vg), occurred during the first 3 days after eclosion. This phase was characterized by enlargement and activation of the nucleoli, proliferation of ribosomes and rough endoplasmic reticulum (RER), development of Golgi complexes, and extensive invaginations of the plasma membrane. During the vitellogenic phase, initiated by a blood meal, Vg was first detected, by immunofluorescence, 1 hr after feeding. The intensity of the immunoreaction increased for the next 24 hr, was declining at 30 hr, and had disappeared by 48 hr. Vg synthesis was characterized ultrastructurally by the enlargement of the RER and the formation of dense secretion granules in Golgi complexes. These secretion granules were two to three times larger at the peak of Vg synthesis than at the beginning. The granules discharged their contents by exocytosis. Two electron microscopical immunocytochemical methods, immunoferritin and peroxidase-antiperoxidase, confirmed this pathway of Vg processing. For the first 12 hr after feeding. Vg synthetic organelles proliferated and the active nucleoli were multilobed; thereafter, while Vg synthesis continued, the nucleoli began to regress into compact bodies. Termination of Vg synthesis was marked by autophagical degradation of Vg synthetic and processing organelles.

Lamellar bodies are the intracellular site of membrane turnover in insect fat body

Analysis of the time course of highly cationic ferritin uptake by fat body cells has shown that the tracer bound to the plasma membrane and was pinocytosed by coated vesicles. The first sites of intracellular accumulation were multivesicular bodies which became filled with ferritin between 30-60 min after cells were exposed to the tracer. At no time during the experiments were any parts of the Golgi complex labeled by the tracer. By 60 min, the ferritin was increasingly found in lamellar bodies. The different types of 'light' and 'dark' multivesicular bodies suggest that lamellar bodies form from multivesicular bodies as they fill with tracer. The occurrence of lamellar bodies in many different cell types suggests an important role in membrane dynamics.

X-ray micronalysis of copper and sulphur-containing granules in the fat body cells of homopteran insects

Regions of the fat body of larvae of Chaetophyes compacta and Pectinariophyes sp. (Machaerotidae, Homoptera) which are closely associated with mycetomes have been analysed by electron probe X-ray microanalysis. It is shown that cells in these regions contain electron probe X-ray microanalysis. It is shown that cells in these regions contain electron dense granules which are rich in copper and sulphur. These two elements occur in the atomic ratio of 3:2 respectively. It is conjectured that copper may be bound to a sulphur containing metallothionein and that the granules represent either the end products of copper detoxification or serve as copper stores for synthesis of enzymes and macromolecules by the mycetomal symbionts.

Intracellular degradation of newly synthesized collagen

The intracellular degradation of newly synthesized collagen is a cellular pathway that accounts for the destruction of 10-60% of collagen synthesized by a variety of cell types prior to secretion. This pathway can serve in a regulatory role to limit the secretion of defective molecules, and, in response to some extracellular mediators, regulates the amount and type of collagens secreted. In addition, this pathway may contribute to the pathogenesis of a variety of conditions affecting the extracellular matrix including fibrosis, diabetes mellitus, and scurvy.

Golgi complex beads in vertebrates and their relationship with clathrin coats

Addition of tannic acid to the primary glutaraldehyde fixative and the viewing of thin sections by stereo electron microscopy greatly simplifies the detection of vertebrate cell Golgi complex beads which are otherwise difficult to see since they do not stain with bismuth. These results confirm the generality of conclusions from experiments on arthropod beads which are easily observed because of their bismuth affinity. In vertebrate and arthropod cells, bead rings encircle the base of forming transition vesicles below the growing portion of the vesicle that is covered with a clathrin coat. Their unique position at such a sharp functional and structural boundary in intercompartmental transport suggests that the bead rings may specify a select region of rough endoplasmic reticulum devoid of ribosomes where clathrin coats can induce transition vesicle formation and prevent intermixing of the elements of a returning transition vesicle.

Lead staining in the Golgi complex

Lead ions at similar concentrations to those used for Gomori type phosphatase localization stain some parts of the vacuolar system, particularly compartments of the Golgi complex (GC) and isolation envelopes (im) in a characteristic way in both vertebrates and invertebrates. After fixation in 2.5% glutaraldehyde, lead citrate in acetate or aspartate buffer (pH 5.5-7.2) leaves the contents of GC cisternal compartments with a fine particulate stippling. In the fat body of Calpodes ethlius and in mouse pancreas the staining is faint but definite without further enhancement of contrast, although it is easily overlooked after section staining. The distribution of lead stain differs from that of the lead phosphate precipitated after Gomori type acid phosphatase reactions. Whereas lead stain may be in all GC and im compartments, acid phosphatase is restricted to the innermost saccules and nearby vacuoles. The compartment specific staining by led also differs from the generalized staining in all compartments given by uranyl. Thus the contents of luminal membrane surfaces of some parts of the vacuolar system can be characterized by their ability to bind lead. In cells where protein synthesis has been blocked by cycloheximide, secretory vesicles are absent and the RER and GC from the generalized staining in all compartments given by uranyl. Thus the contents of luminal membrane surfaces of some parts of the vacuolar system can be characterized by their ability to bind lead. In cells where protein synthesis has been blocked by cycloheximide, secretory vesicles are absent and the RER and GC from the generalized staining in all compartments given by uranyl. Thus the contents of luminal membrane surfaces of some parts of the vacuolar system can be characterized by their ability to bind lead. In cells where protein synthesis has been blocked by cycloheximide, secretory vesicles are absent and the RER and GC cisternae are devoid of uranyl stainable material. However, lead staining and acid phosphatase activity in the GC continue. We presume that they mark the environment within these cisternae rather than the proteins passing through them. This environment is itself not static. Several observations suggest that the function of cisternae that is detectable by lead staining is temporally discontinuous and related to a stage of maturation or development. Only early stage ims stain: the staining ceases by the beginning of autophagy after hydrolytic enzymes are presumed to have been added. Condensing vacuoles cease to stain as the central core crystallizes out. Stain may be absent from one or two GC saccules at any position in the stack as though the phase of lead staining (or lack or it) can move progressively through the system. We conclude that in studies characterizing components of the vacuolar system it is necessary to separate those that mark transient occupants of a compartment from those that mark the compartment itself. Both may vary temporally independently from one another.

Cell death: questions for histochemists concerning the causes of the various cytological changes

The question of cell death is accessible to study by histochemists and many questions remain to be resolved. From a physiological point of view, the most important are the causal relationships. (1) At what phase in cell death is the synthesis of RNA disrupted and at what phase is the rate of degradation of RNA increased? (2) Does the disruption of synthesis result from a direct genetic command, or does it result indirectly from gradual deterioration of energy resources or optimal ionic conditions? (3) What properties, presumably of the substrate organelles, marks them for specific absorption into autophagic vacuoles? (4) What proteases and other hydrolases operate currently undetected in the cytoplasm? How are they controlled and regulated? (5) Why does the physiologically dying cell shrink and appear more dense? To what extent is a cell in this state able to regulate any metabolic parameter? The advent of newer, more sensitive and quantitative techniques, and greater attention to the controls and causes as opposed to the phenomena, should help to resolve these questions.

Studies on vinblastine-induced autophagocytosis in mouse liver. II. Origin of membranes and acquisition of acid phosphatase

The origin of the membranes of autophagic vacuoles (AV) and acquisition of acid phosphatase into AV's were studied in vinblastine-induced autophagocytosis (VBL, 50 mg/kg, i.p.) in mouse hepatocytes. Using unbuffered OsO4, very intense staining was observed in the outer cisternae of the Golgi apparatus and also frequently in the cavity between the double membranes obviously destined to form AV's as well as in the cavity between the double membranes of newly formed AV's. There may occur a transformation process in the membranes limiting an AV analogous to that observed at the Golgi cisternae. The transformation of the outer AV membrane occurs independently of fusion with lysosomes. Inosine diphosphatase activity was localized within the cisternae and on the membranes of the endoplasmic recticulum and occasionally within the innermost cisterna of the Golgi apparatus. The results together with the unbuffered OsO4-staining pattern suggest that the membranes of most AV's are derived from the transformed smooth surfaced cisternae of the endoplasmic reticulum which do not have inosine diphosphatase activity. Acid phosphatase activity was localized in lysosomes, occasionally within the innermost cisternae of the Golgi apparatus, between the double membranes of a few newly formed AV's and within most older single membranes of a few newly formed AV's and within most older single membrane-limited AV's. VBL did not prevent the fusion of lysosomes with AV's.

Fine structural and histochemical studies on salivary glands of Peripatoides novae-zealandiae (Onychophora) with special reference to acid phosphatase distribution

The Onychophora feed on small arthropods and produce saliva when ingesting prey. Although saliva undoubtedly helps to liquefy the food its constituents have not yet been fully described. The salivary glands, two long tubes of glandularepithelium, are known to secrete a powerful protease, however, besides other enzymes and mucus. In Peripatoides novae-zealandiae there are protein-secreting cells of three types, referred to here as columnar, cuboidal and modified cells, and mucus cells. The anterior two-thirds of the gland show most cell diversity, while the posterior regionconsists mainly of columnar cells. These are the most numerous elements overall and they probably secrete salivary protease. In thick resin sections the granules of all protein-secreting cells stain strongly with methylene blue. Those of columnar cells are markedly uneven in size and accumulate distally, eventually filling the cytoplasm. More proximal Golgi regions may be discernible. Mucus cells are all of one type and their secretion droplets are stained lightly by methylene blue. The electron microscope shows that distal microvilli, desmosomes and septate junctions are common to all gland cells. In columnar cells, secretory material is contributed by Golgi complexes and by rough endoplasmic reticulum. Early secretory vacuoles containing dense material are seen in the concavity of Golgi regions. They are precursors to larger condensing vacuoles whose contents have a more flocculent appearance, and which may attain 3--4 micrometers in diameter. These evolve into secretory granules, usually of uneven texture, which are up to 2.5 micrometers in diameter. Histochemical tests for acid phosphatase show moderate amounts of enzyme throughout the gland. In whole mounts and sections the strongest reaction is in a band of cuboidal cells along the anterior median border. Columnar cells show a diffuse cytoplasmic reaction towards the base and sometimes distal to the nucleus, and mucus cells may also react strongly round the nucleus. Cytoplasm near the lumen shows little reaction. The secretory granules do not appear to contain active enzyme. Under the electron microscope a positive reaction for acid phosphatase is seen in lysosomal derivatives near the base and lateral periphery of gland cells. These bodies are probably outophagic vacuoles and they may contain membranous whorls and possibly old secretion granules. Acid phosphatase is involved also in the eleboration of new secretory granules in both columnar and mucus cells. Dense reaction products is found in a system of interconnected tubules and cisternae near the innermost face of the Golgi complex, which is interpreted as GERL. Acid phosphatase is present in the peripheral zone of adjacent early secretory vacuoles, and interconnections occur between GERL and secretory vacuoles. It is suggested that GERL tubules containing the enzyme may fuse with early secretory vacuoles and release acid phosphatase at their periphery...

Regression of the larval opisthonephros during metamorphosis of the sea lamprey, Petromyzon marinus L

The opisthonephric kidney of larval anadromous sea lamprey, Petromyzon marinus L., undergoes a programmed regression during metamorphosis. Degeneration is initiated in the anterior end of each kidney and progresses posteriorly until the kidneys are reduced to short, pigmented strands by the end of metamorphosis. The first sign of degeneration in both the epithelium of the renal corpuscles and the tubules is a folding of the basal lamina. Autolysis then occurs throughout the entire epithelium of the nephron with the gradual accumulation of larger and greater numbers of acid phosphatase-containing autophagic vacuoles, cytosomes, and myelin figures. Cytoplasmic debris and electron-dense material accumulates in the tubular lumina and in the urinary space. Although no definitive evidence is provided for the method of removal of the tubular epithelium, macrophages play a large part in the phagocytosis of the components of the renal corpuscle. Mesangial cells appear to engulf debris from the capillaries while a second type of macrophage is involved in the destruction of podocytes and parietal epithelial cells. The method of programmed degeneration of the renal corpuscle closely resembles descriptions of the mammalian renal corpuscle in diseased conditions. The sole surviving element of the degeneration of the entire nephron epithelium is a pleated basal lamina. The regressing larval opisthonephros has potential as an alternative system for studying a normal developmental pattern such as tissue regression.

Morphology of the granular secretory glands in skin of poison-dart frogs (Dendrobatidae)

The granular glands of nine species of dendrobatid frogs were examined using light and electron microscopy. The glands are surrounded by a discontinuous layer of smooth muscle cells. Within the glands proper the secretory cells form a true syncytium. Multiple flattened nuclei lie at the periphery of the gland. The peripheral cytoplasm also contains mitochondria, rough surfaced endoplasmic reticulum, the Golgi apparatus, and an abundance of smooth endoplasmic reticulum. Centrally, most of the gland is filled with membrane-bound granules surrounded by amorphous cytoplasm. Few other organelles are found in this region. Early in the secretory cycle, the central part of the gland is filled with flocculent material which appears to be progressively partitioned off by membranes to form the droplet anlage. As granules form, the structure of the contents becomes progressively more vesicular. Dense vesicles, which bud off from the Golgi apparatus, fuse with the granular membrane during the development of granules, and might contain enzymes involved in toxin synthesis. The granules at this point resemble multivesicular bodies. Their structure is similar in all species of dendrobatid frogs even though the different frogs secrete substances of different chemical structure and toxicity.