Autophagic and apoptotic features during programmed cell death in the fat body of the tobacco hornworm (Manduca sexta)

Two major pathways of programmed cell death (PCD)--the apoptotic and the autophagic cell death--were investigated in the decomposition process of the larval fat body during the 5th larval stage of Manduca sexta. Several basic aspects of apoptotic and autophagic cell death were analyzed by morphological and biochemical methods in order to disclose whether these mechanisms do have shared common regulatory steps. Morphological examination revealed the definite autophagic wave started on day 4 followed by DNA fragmentation as demonstrated by agarose gel electrophoresis and TUNEL assay. By the end of the wandering period the cells were filled with autophagic vacuoles and protein granules of heterophagic origin and the vast majority of the nuclei were TUNEL-positive. No evidence was found of other aspects of apoptosis, e.g. activation of executioner caspases. Close correlation was disclosed between the onset of autophagy and the nuclear accumulation of the ubiquitin-proteasome system.

Ultramorphology and histochemistry of fat body cells from last Instar larval of the Pachycondyla (=Neoponera) villosa (Fabricius) (Formicidae: Ponerinae)

The fat body cells of Pachycondyla (=Neoponera) villosa are disposed in a single layer between the cuticle and the digestive tract, forming a group of cells enclosed by a thin membrane. Histological studies have revealed three different cellular types: trophocyte (more abundant), urate, (located among the trophocytes), and oenocyte (the scarcest), usually observed laying near the cuticle. Histochemically, the trophocytes showed a positive reaction for basic proteins in the nucleus and cytoplasm, as well as a strong positive reaction in the cytoplasmic granules. The test for carbohydrates showed a strong positive reaction throughout the cytoplasm, while the test for lipids was positive for the cytoplasmic vesicles. The urate cells showed a positive reaction for basic proteins in the nucleus and in the areas of the cytoplasm surrounding the vesicles. These cells did not react to the PAS test or to Sudan Black B. The oenocytes showed a weak positive reaction to PAS and a strong positive reaction to Sudan Black B and Mercuric-bromophenol Blue.

Discovery of a granulovirus of Pandemis pyrusana (Lepidoptera: Tortricidae), a leafroller pest of apples in Washington

Pandemis pyrusana (Kearfott) is an important leafroller pest of apples in Washington. Surveys for natural enemies discovered a pathogen infecting Pandemis leafrollers in an apple orchard in central Washington. The pathogen was propagated in the laboratory and light microscopy using an azan stain demonstrated that it infected fat body, epidermis, and tracheal matrix cells. The virus was identified morphologically as a granulovirus using electron microscopy and designated PpGV. Rates of infection were determined for each generation in an apple orchard for three years. Infection rates were variable and ranged from 2.6 to 67% of individuals collected from each generation.

Venom of Euplectrus separatae causes hyperlipidemia by lysis of host fat body cells

Although the lepidopteran larva Pseudaletia separata is attacked by the gregarious ectoparasitoid Euplectrus separatae, it continues to feed and grow. Lipid concentration in the hemolymph of the parasitized host was higher than that of the nonparasitized host from 3 to 8 days after parasitization. Artificial injection of parasitoid venom also elevated lipid concentration in the host hemolymph. One day after venom injection the host's fat body contained many lipid particles, but most of the lipid particles disappeared 7 days later. Light microscopy and transmission electron microscopy showed the lipid particles leaving the fat body cells as a result of the lysis of the fat body cells. These results suggest that the venom elevated the lipid concentration in the host hemolymph by provoking the release of lipid particles from the fat body. Though most of the lipid particles were freely floating in the host hemolymph, a portion of the released lipid particles were phagocytized by hemocytes. The amount of lipid that was loaded to lipophorin in the hemolymph of the venom-injected host was measured, but it was not sufficient to explain the high lipid titer in the hemolymph of parasitized and venom-injected host larvae. The fact that parasitoid larva consumed many hemocytes as evidenced by their presence in the midgut supported the hypothesis that the parasitoid larvae fed on the host hemolymph containing the free lipid particles, the hemocytes phagocytizing the lipid particles, and the lipid-loaded lipophorin. The possibility of the venom contribution to the disruption of the intercellular matrix was examined. The venom showed high activity of matrix metalloproteinase (MMP), especially when it was mixed with the hemolymph of non-parasitized 5th instar larvae. We suggest that the MMP in the venom was activated by some components of the host hemolymph. On the other hand, the venom mixed with hemolymph could not decompose gelatin on zymography, suggesting that the venom-MMP is a different type from gelatinase. Activity of phospholipases A(2), B, C and hyaluronidase were measured with agar plates. High activities of phospholipase B and hyaluronidase were detected. These results suggest that the venom-MMP initially attacked the specific site of the intercellular-matrix of the fat body, and then the hyaluronidase and the phospholipase B cause lysis of the fat body cell, allowing lipid particles to be released into the host hemolymph.

The Drosophila homolog of Aut1 is essential for autophagy and development

The Drosophila homolog of yeast Aut1, CG6877/Draut1, is a ubiquitously expressed cytosolic protein. Draut1 loss of function was achieved by expression of an inverted repeat transgene inducing RNA interference. The effect is temperature-dependent and resembles an allelic series as described by Fortier, E. and Belote, J.M. (Genesis 26 (2000) 240-244). Draut1 loss of function larvae are unable to induce autophagy and heterophagy in fat body cells before pupariation and die during metamorphosis. To our knowledge, this is the first report of a multicellular animal lacking the function of a gene participating in the protein conjugation systems of autophagy.

Intranuclear virus-like particles of a Drosophila hybrid

Intranuclear virus-like particles (VLPs) have been observed in different cell lines and adult tissues of Drosophila. In the present study, intranuclear VLPs have been found in larval tissues (salivary glands, midgut, fat body) as well as in adult tissues (midgut, genitals, fat body) of a rare interspecific hybrid (D. mauritiana x D. melanogaster) called 'mame'. The intranuclear VLPs were round or slightly elliptical with a diameter of 30 nm, and they were found mainly in highly organised clusters, forming large crystalline arrays, near the nucleolus and the polycene chromosomes. These particles were never observed in the cytoplasm of any mame's tissue. A few VLPs were also seen in the corresponding tissues of D. melanogaster, but they were never observed in any tissue of D. mauritiana. There is the intriguing possibility that these VLPs are related to transposable elements and probably contribute to the speciation process, in an unknown, so far, manner.

Ferritin in iron containing granules from the fat body of the honeybees Apis mellifera and Scaptotrigona postica

It is already known that the behaviour of the honeybee Apis mellifera is influenced by the Earth's magnetic field. Recently it has been proposed that iron-rich granules found inside the fat body cells of this honeybee had small magnetite crystals that were responsible for this behaviour. In the present work, we studied the iron containing granules from queens of two species of honeybees (A. mellifera and Scaptotrigona postica) by electron microscopy methods in order to clarify this point. The granules were found inside rough endoplasmic reticulum cisternae. Energy dispersive X-ray analysis of granules from A. mellifera showed the presence of iron, phosphorus and calcium. The same analysis performed on the granules of S. postica also indicated the presence of these elements along with the additional element magnesium. The granules of A. mellifera were composed of apoferritin-like particles in the periphery while in the core, clusters of organised particles resembling holoferritin were seen. The larger and more mineralised granules of S. postica presented structures resembling ferritin cores in the periphery, and smaller electron dense particles inside the bulk. Electron spectroscopic images of the granules from A. mellifera showed that iron, oxygen and phosphorus were co-localised in the ferritin-like deposits. These results indicate that the iron-rich granules of these honeybees are formed by accumulation of ferritin and its degraded forms together with elements present inside the rough endoplasmic reticulum, such as phosphorus, calcium and magnesium. It is suggested that the high level of phosphate in the milieu would prevent the crystallisation of iron oxides in these structures, making very unlikely their participation in magnetoreception mechanisms. They are most probably involved in iron homeostasis.

Cysteine proprotease colocalizes with vitellogenin in compound granules of the cockroach fat body

A cysteine proprotease has been identified in developing embryos of the cockroach Blattella germanica and found to be a maternally encoded gene product that is transferred endocytically to the oocyte. The present study aims at establishing how this maternally derived proprotease is synthesized, packaged, and secreted during vitellogenesis. To this end, proprotease was localized immunocytochemically in the fat body of postmating females and its localization compared with that of vitellogenin over the same developmental periods. Fat bodies in cockroaches are comprised of two different cell types: trophocytes and bacteriocytes. Data show that proprotease and vitellogenin come to colocalize in compound granules of the fat body trophocytes. While synthesis of vitellogenin can be traced back to granules resulting from the coalescence of Golgi-derived vesicles in the trophocyte cytoplasm, proprotease appears to be localized predominantly on the cytolysosomes of both trophocytes and bacteriocytes. When probed with an anti-proprotease antiserum, bacteria are also positively labeled, regardless of whether they are segregated inside the cytolysosomes or free in the bacteriocyte cytoplasm. Since vitellogenin and proprotease colocalize within the same cell organelle, it is assumed that Golgi-derived vesicles, which contain vitellogenin, may fuse with cytolysosomes bearing proprotease to yield compound secretory granules. To account for the present observations, the origin and role of proprotease are discussed in relation to the turnover of bacteria in the fat body and to the requirements of endosymbiosis.

Ergastoplasmic paracrystalline inclusion bodies in the adipose gonadal envelope and fat body of the glow worm, Lampyris noctiluca (Insecta, Coleoptera)

The gonads of glow worm larvae are enveloped by adipose tissue which represents a specialized fat body. The adipose gonadal envelope, and also to a lesser extent the fat body cells, contain tubular paracrystalline inclusion bodies (PIBs). Cells of other tissues are devoid of such inclusions. The PIBs form in the cisternae of rough ER. In young larvae PIB formation is sparse, but at advanced larval stages PIBs often occur as bundles in stacks of ergastoplasm. Typically, a PIB within a cisterna consists of four to seven parallel tubules. The outer diameter of a tubule is ca 28.8 nm and the width of the tubule lumen ca 12.2 nm. The "wall" of a tubule contains globular protein subunits of ca 8.3 nm diameter; the subunits are arranged helically. Since the adipose gonadal envelope progresses through a cytological differentiation process during differentiation and maturation of the gonads, the increased number of PIBs may indicate enhanced metabolic activity of the tissue related to nutrition of the growing gonads.

Ultrastructural features of the fat body and oenocytes of Rhinocricus padbergi Verhoeff (Diplopoda, Spirobolida)

The fat body of the diplopod Rhinocricus padbergi is located in two preferential areas of its body: a) immediately below the tegument, denominated parietal, and b) filling the body cavity, close to the viscera, mainly the ovaries and alimentary canal, denominated perivisceral. Ultrastructurally, its cells, the adipocytes, presented varied morphology and contained organelles indicating that they are cells that mainly produce and store lipids and proteins. The presence of cells similar to the oenocytes found in insects was observed for the first time in diplopods, associated to the fat body of R. padbergi. Our observations suggest that this tissue probably maintains activity cycles, since the presence of cells undergoing apoptosis was detected.

Fatty acid delta9-desaturation in the Triatoma infestans fat body: response to food and trehalose administrations

The effects of food intake and carbohydrate administration on fatty acid delta9-desaturation were investigated in isolated microsomes from Triatoma infestans fat body. Fifth instar nymphs, which were solely blood-fed just after the molt and then fasted, were used as controls and for determination of optimal assay conditions. Both [1-14C]palmitic and [1-14C]stearic acids in a medium containing ATP, CoA, MgCl2, NADH, NaF, and O2 were tested. For the control group, optimal conditions were a pH of 6.8-7.2, an incubation temperature of 29 degrees C, and an incubation time of 10 min. delta9-Desaturation depended on the presence of reduced pyridine dinucleotides; NADH and NADPH were equally efficient. Stearic acid showed a higher apparent Vmax than palmitic acid, but the apparent Km were very similar. When fifth instar nymphs were blood-fed weekly, a marked increase of delta9-desaturation was observed for both acids. Higher desaturation activity was also induced by injection of the carbohydrate trehalose into the hemolymph of fasted nymphs. These results indicate that insect delta9-desaturation, like the mammalian counterpart, is sensitive to dietary changes and carbohydrate administration.

A yolk protein mutant leads to defects in the secretion machinery of Drosophila melanogaster

The three yolk proteins of Drosophila melanogaster are synthesized in the fat body and ovarian follicle cells. A mutation in yolk protein 3, YP3S1, has been described in which the leader sequence is not cleaved from the protein. We describe here ultrastructural and molecular studies on the YP3S1 mutant and show that the mutant protein enters the secretory pathway and forms precipitates, often as electron dense material in excessive elaborations of the plasma membrane. Females homozygous for YP3S1 lay fewer eggs than wild type flies and these embryos are less viable. The abnormal ultrastructure of the yolk spheres observed suggests that whilst YP3 is not completely essential for viability, it is required for normal yolk sphere morphogenesis.

Secretory and internalization pathways of mosquito yolk protein precursors

The vitellogenic female fat body of the mosquito Aedes aegypti produces three yolk protein precursors that are deposited in the yolk bodies of developing oocytes: vitellogenin, vitellogenic carboxypeptidase (VCP), and 44-kDa protein (44KP). We have used gold immunocytochemistry to investigate the pathways of their secretion in fat body trophocytes and their internalization by oocytes. In fat body trophocytes, all three yolk protein precursors are co-localized in the Golgi complex and secretory granules, indicating that they proceed simultaneously through the secretory pathway. The lysosomal system plays an important role in the termination of vitellogenesis in mosquito trophocytes, by degrading biosynthetic organelles and secretory granules. At this time, VCP and 44KP are found together with vitellogenin in trophocyte autophagolysosomes, suggesting that all three yolk protein precusors are redirected from the secretory to the lysosomal degradative pathway. Localization of VCP and 44KP in developing mosquito oocytes clearly shows that the internalization of these yolk protein precursors by oocytes occurs via the same endocytotic route as vitellogenin: all three yolk protein precursors are found on the oocyte microvillus membrane, in coated vesicles, and early endosomes. They are observed intermixed with one another in the late endosomes or in transitional yolk bodies. In mature yolk bodies, however, 44KP and VCP are segregated from vitellin, the crystallized storage form of vitellogenin; 44KP and VCP reside in the non-crystalline cortex, surrounding the vitellin core in nature yolk bodies.

Fat body of the frog Rana esculenta: an ultrastructural study

In the frog, the fat body is the largest body lipid deposit and is associated with the gonad. The aim of the present work was to investigate the fine structure of the fat body at different periods of the annual cycle and during prolonged starvation. Results indicate that fat body cells of Rana esculenta caught in autumn and after winter hibernation resemble mammalian adipocytes of white adipose tissue and contain markers of adipose tissue, such as S-100 protein and lipoproteinlipase. However, unlike mammalian adipocytes, fat body adipocytes consistently show small lipid droplets associated with their single, large lipid deposits, a lack of a definite external lamina, and the presence of cellular prolongations and spicula at their surfaces. Transmission and scanning electron microscopy in association with lanthanum tracer experiments suggest that in fat body adipocytes a vesicular-tubular system connects the cytoplasm and the interstitial space. In June (i.e., during the reproductive period), fat body adipocytes appear to have lost much of their lipid deposit and adjacent adipocytes show interdigitation of their plasma membranes and prominent Golgi complexes. In starved frogs, fat body cells can be almost devoid of lipid and in regression to a near-mesenchymal state. Nevertheless, these fat bodies still contain lipoproteinlipase activity (approximately 45% of that found in lipid-filled ones), indicating persistent adipose differentiation of the cells therein. Results presented here show that the R. esculenta fat body is an adipose organ undergoing reversible extreme changes in adipocyte fat content, which are associated with definite ultrastructural features. The fat body represents a suitable model for studying adipose tissue under different and extreme physiological conditions.

EPR spectroscopic characterization of the iron-sulphur proteins and cytochrome P-450 in mitochondria from the insect Spodoptera littoralis (cotton leafworm)

EPR spectroscopy was used to investigate the cytochrome P-450-dependent steroid hydroxylase ecdysone 20-mono-oxygenase of the cotton leafworm (Spodoptera littoralis) and the redox centres associated with membranes from the fat-body mitochondrial fraction. Intense features at g = 2.42, 2.25 and 1.92 from oxidized mitochondrial membranes have been assigned to the low-spin haem form of ferricytochrome P-450, probably of ecdysone 20-mono-oxygenase. High-spin cytochrome P-450 (substrate-bound) was tentatively assigned to a signal at g = 8.0, which was detectable from membranes as prepared. An EPR signal characteristic of a [2Fe-2S] cluster detected from the soluble mitochondrial matrix fraction has been shown to be distinct from the signals associated with mitochondrial NADH dehydrogenase and succinate dehydrogenase, and has therefore been attributed to a ferredoxin. We conclude that the S. littoralis fat-body mitochondrial electron-transport system involved in steroid 20-hydroxylation comprises both ferredoxin and cytochrome P-450 components, and thus resembles the enzyme systems of adrenocortical mitochondria. EPR signals characteristic of the respiratory chain were also observed from fat-body mitochondria and assigned to the iron-sulphur clusters associated with Complex I (Centres N1, N2), Complex II (Centres S1, S3), Complex III (the Rieske centre), and the copper centre of Complex IV, demonstrating similarities to mammalian mitochondria. The reduced membrane fraction also yielded a major resonance at g = 2.09 and 1.88 characteristic of the [4Fe-4S] cluster of electron-transferring flavoprotein: ubiquinone oxidoreductase. As the fat-body is the major metabolic organ of insects, this protein is presumably required for the beta-oxidation of fatty acids in mitochondria. High-spin haem signals in the low-field region of spectra also demonstrated that the mitochondrial fraction contains relatively high concentrations of catalase.

The toxicities of short-chain primary alcohols and the accumulation of storage bodies in the larval fat body of Drosophila melanogaster

In terms of the LD50 values for alcohols, third-instar wild-type larvae of Drosophila melanogaster had a greater tolerance to ethanol, n-propanol and n-butanol than alcohol dehydrogenase (ADH)-deficient larvae. The tolerances of the two strains to methanol were similar. Methanol, ethanol, n-propanol and n-butanol all induced higher ADH activity in wild-type larvae. Ethanol, n-propanol, methanol and n-butanol slowed the growth for ADH-deficient larvae, whereas only methanol had this effect on wild-type larvae. The proportion of wild-type pupae to eclose was increased by n-butanol, n-propanol and ethanol. Cytometric methods to measure the densities of storage bodies--glycogen rosettes, protein bodies and lipid droplets--in fat body cells indicated that all of the test alcohols exerted some negative influence on the accumulation of at least one type of storage body. Analyses of total protein, glycogen and acylglycerols indicated that ethanol and n-butanol were associated with an accumulation of acylglycerols in both wild-type and ADH-deficient larvae; whereas, the other test alcohols resulted in low glycogen and protein concentrations in both test strains. The short-chain primary alcohols may in part be toxic to larvae because of disruptions in metabolism that lead to reductions in one or more kinds of storage bodies in the larval fat body.

Storage protein uptake in Helicoverpa zea. Purification of the very high density lipoprotein receptor from perivisceral fat body

In prepupae of the corn earworm, Helicoverpa zea, storage proteins are taken up by perivisceral fat body, a specialized storage tissue. In this study, the receptor protein for one of these storage proteins, a very high density lipoprotein, was identified, extracted, and purified to homogeneity. The very high density lipoprotein receptor is a glycosylated basic protein with a pI of 8.2 and an apparent molecular weight of 80,000. Binding requires the presence of Ca2+ and has a pH optimum of 7.0. Electron micrographs of immunogold labeled sections show that the receptor is located in the plasma membrane of perivisceral fat body. No receptor is detectable in peripheral fat body which does not sequester storage proteins.

Mitotic and polytene chromosome analysis in Dacus oleae (Diptera: Tephritidae)

The present study constitutes the first attempt to construct a photographic map of the polytene chromosomes of Dacus oleae, a pest of the olive tree that causes serious financial damage in all olive oil producing countries. The map was constructed by using the larval fat body cells, the chromosomes of which are representative of the polytene chromosomes of other polytene tissues. In addition, the mitotic chromosomes of brain ganglia were examined, permitting tentative correlations between mitotic and polytene elements. This investigation shows that D. oleae is suitable for cytogenetic analysis in both mitotic and polytene chromosomes, a fact that may prove very useful for obtaining more detailed genetic information on the pest's natural populations.

An overview of gene activity in the fat body of Drosophila gibberosa

In the larval fat body of Drosophila gibberosa, polytene chromosome structure and activity exhibit cytological differences from chromosomes of midgut and salivary glands. These differences include long-persisting puffs, transient puffs and long-persisting band modulations. Some early ecdysteroid-induced puffs are present in all three organs but few late puffs are present in the fat body. Comparative studies reveal, therefore, that late larval-early pupal puffing is enhanced in salivary glands relative to gut, fat body and Malpighian tubules. After the fat body breaks up in the prepupa, the rate of programmed cell death and the corresponding slow decline of chromosomal activity also differ from cell to cell and from other organs.

Mammalian genes expressed in Drosophila: a transgenic model for the study of mechanisms of chemical mutagenesis and metabolism

Mammalian cytochrome P450s provide our first line of defence against the toxic effects of environmental chemicals. Ironically these enzymes also convert some compounds to their ultimate toxic or mutagenic species. Our knowledge of these mammalian enzymes and the role they play in chemical toxicity and mutagenesis has stemmed mostly from in vitro studies. In order to establish the role of specific enzymes in the toxicological response in vivo we have generated transgenic Drosophila which express mammalian cytochrome CYP2B1, which is a member of a large gene family encoding several important drug metabolising enzymes. The gene was fused to a Drosophila promoter which confers expression in the larval fat body. Using the Somatic Mutation And Recombination Test (SMART) we have demonstrated that transgenic larvae expressing the P450 are hypersensitive to the anticancer drug cyclophosphamide, a procarcinogenic substrate which is activated by the enzyme. This work demonstrates the potential of such transgenic Drosophila strains as an in vivo model for studying the role of specific mammalian drug metabolising enzymes in the pathways and metabolic cascades associated with the action of cytotoxic and carcinogenic chemicals, and also the chemical properties of specific classes of mutagen to be determined.

Mixed Rickettsia-virus infection in Dermacentor reticulatus imago

Electron microscopic examination revealed replication and accumulation of Rickettsia sibirica in the fat body of experimentally infected Dermacentor reticulatus ticks. Rickettsia are released from the fat body cells by budding being surrounded with cytoplasm and plasmalemma of the host cell. Eukaryotic cell structures have been detected consisting of lamella layers whirled around the intact rickettsiae. In addition to rickettsia, microorganisms morphologically resembling Francisella tularensis and an orbivirus were found in tick tissues at morphological examination. The morphology of the virus and stages of its morphogenesis are described. Mixed viral and rickettsial infection has been shown to develop in the same ticks and even in the same fat body cells in a very close association.

Genetically modified yolk proteins precipitate in the adult Drosophila fat body

Ultrastructural and genetic studies were carried out on the fat body of a female sterile mutant fs(1)1163 to ascertain why yolk protein 1 (YP1) is not secreted from this tissue. Earlier molecular studies demonstrated that (a) normally yolk protein is synthesized in the fat body, secreted into the hemolymph and taken up by the ovary, (b) the 1163 mutation causes a single amino acid substitution in YP1, and (c) females homozygous for the mutation, or heterozygous females raised at 29 degrees C, retain YP1 in the fat body. Ultrastructural analysis in this paper shows that the fat body of these females contains masses of electron-dense material deposited in the subbasement membrane space. This subbasement membrane material (SBMM), which occasionally has a crystalline-like, fibrous component, is found in females whose genotypes include at least one copy of the mutant 1163 gene. These strains include a deletion strain that is hemizygous for the 1163 gene and two strains that are transgenic for the mutant gene. Immunogold studies indicate that SBMM contains yolk protein. We propose that the mutant protein is secreted into the subbasement membrane space, but because of the amino acid substitution in YP1, the oligomers containing YP1 condense into SBMM, which cannot penetrate the basement membrane. The similarity of SBMM and deoxyhemoglobin S fibers is discussed.