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.     

Changes of acid phosphatase content and activity in the fat body and the hemolymph of the flesh fly Neobellieria (sarcophaga) bullata during metamorphosis

Changes in the specific and total activity of the lysosomal marker enzyme acid phosphatase (Acph) and in the amount of enzyme protein were examined in the fat body and the hemolymph from the last larval molt to the larval-pupal apolysis. The specific activity showed minor changes during the last larval period. In contrast, the total activity of the enzyme was low during the feeding period and higher during the wandering stage and strikingly increased at the time of puparium formation. We purified a protein having para-nitrophenyl phosphate phosphatase (Acph) activity and raised antisera against it. The amount of Acph protein in the fat body and hemolymph was examined using an ELISA. The specific Acph content showed little variation, but the total amount of the enzyme protein showed a stepwise increase in both organs during last larval stage and was markedly elevated in the pupal stage in the fat body. In contrast, a considerable decrease in the amount of Acph protein was observed in the hemolymph during this period. These data were in agreement with immunohistochemical observations showing an accumulation of the enzyme protein in fat body cells during the prepupal stage with a concomitant disappearance of the enzyme from the hemolymph. Inhibition of ecdysteroid secretion by water stress prevented the changes both in total enzyme activity and in the amount of Acph protein. However, Acph protein content and enzyme activity could be restored when the water stress was followed by a 20-hydroxyecdysone (20-HE) treatment. Taken together, our data show that Acph is secreted by fat body cells into the hemolymph during the larval stage, where it is stored in an inactive form. Increase in the 20-HE titer at the end of last larval stage reverses this process, and the enzyme is taken up by the fat body cells, where it becomes activated and appears in auto- and heterophagic vacuoles. Arch. Insect Biochem. Physiol. 34:369–390, 1997. © 1997 Wiley-Liss, Inc.     

The effect of ecdysone on the fat body cells of the penultimate larvae of Mamestra brassicae

Summary The capability of -ecdysterone to induce autophagocytosis in the fat body cells of penultimate larvae of Mamestra brassicae was investigated both in vivo and in vitro. The hormone proved ineffective when applied for 3 h on the first 3 days of the instar, but it induced the formation of autophagic vacuoles on the 4th day (24 h before ecdysis). This effect became more pronounced when the hormone was administered 10 h before ecdysis. Cells incubated in vitro reacted to ecdysterone more sensitively than cells of similar age treated in vivo. It was concluded that the responsiveness of the fat body cells to ecdysterone as evaluated on the basis of autophagy depends on the age of the larvae. The increased sensitivity of the cells to ecdysterone at the end of the penultimate stage may be related to the decrease of juvenile hormone titre during this period.     

Autophagocytosis in the larval midgut cells of Pieris brassicae during metamorphosis

Summary We observed three types of cells in the epithelial layer of the midgut of last instars of Pieris brassicae. The columnar and goblet cells degenerate during the second part of the last larval stage while the undifferentiated basal cells proliferate during this period and create the epithelium of the pupal midgut. The first morphological sign of involution is the formation of autophagic vacuoles and dense bodies in the cytoplasm of columnar and goblet cells which begins on day 4 of the stage. The number and size of autophagic vacuoles and dense bodies increase during the spinning period (85–96 h). Finally, at the end of the stage, the columnar and goblet cells become displaced by the growing pupal epithelium and reach the lumen where they disintegrate.Autophagocytosis was not seen in the cells during the feeding period (0–72 h). However, we observed many autophagic vacuoles in the columnar and goblet cells of 50-h-old instars 3 h after the administration of 30 g/g body weight of 20-hydroxyecdysone. The hormone treatment elevated by 100% the incorporation of ³H-leucine into the proteins of the midgut. Inhibitors of protein synthesis, cycloheximide and puromycin, in doses that supressed the incorporation of the amino acid by 60–70% either in hormone treated or untreated larvae, exerted diverse effects on the autophagic process. Puromycin did not block the hormone-induced formation of autophagic vacuoles while cycloheximide prevented it. Possible explanations for this diversity are discussed.     

Modes of cell death in the pupal perivisceral fat body tissue of the silkworm Bombyx mori L.

Cell death is a scheduled event during animal development and tissue turnover. Here, we affirm the presence of two major pathways of programmed cell death (PCD), viz. apoptotic and autophagic cell death, in the disintegrated pupal perivisceral (PV) fat body during pupal-adult metamorphosis. The acridine orange (a vital stain for apoptosis) staining pattern and DNA fragmentation assay have revealed the exact day (6th day of the pupal stage) of disintegration in the PV fat body as represented by chromatin condensation and DNA laddering. Electron microscopy and scanning electron microscopy have demonstrated the presence of cytoplasmic budding and giant autophagic vacuoles and the low numbers of mitochondria, all of which are attributes of autophagic cell death. Immunoblot analysis of proteosomal subunits 20S and 26S has established the involvement of proteolytic activity during PCD of PV tissue. Lysosomal participation during the PCD of PV tissues has been confirmed by the elevated level of the marker enzyme, acid phosphatase, which is distinct on day 6 of the pupal period. The results of the present study have thus ascertained the co-existence of both autophagic and apoptotic cell death in PV fat body tissue.     

The corpus luteum of the guinea pig. IV. Fine structure of macrophages during pregnancy and postpartum luteolysis, and the phagocytosis of luteal cells.

Little information is available on the ultrastructure of macrophages in the corpus luteum or their importance in the regression of luteal tissue. In the present study, the fine structure of activated luteal macrophages during pregnancy and the postpartum period was examined by electron microscopy of guinea pig ovaries fixed by vascular perfusion. In these corpora lutea, macrophages can readily be distinguished from luteal cells. Activated macrophages typically display three prominent inclusions in their cytoplasm: (1) heterophagic vacuoles, (2) distinctive large dense inclusions, and (3) large and small electron-lucent vacuoles. In addition, they contain numerous smaller lysosome-like dense bodies. Activated macrophages in corpora lutea also characteristically show many surface protrusions, such as processes, folds or pseudopodia, which often occur in close contact with nearby luteal cells. Generally, nuclei of macrophages are irregular in shape and display a dense border of heterochromatin, thus differing from those of luteal cells. Macrophages seem to be most abundant in regressing corpora lutea, where they commonly display heterophagic vacuoles containing recognizable luteal cell fragments, evidence that these phagocytes ingest senescent luteal cells. The digestion of luteal cell components in heterophagic vacuoles presumably gives rise to the distinctive large dense inclusions typically seen in macrophages. The findings of this study indicate that macrophages play a central role in luteolysis by phagocytizing luteal cells or their remnants. They therefore appear to bring about the reduction in volume of the corpus luteum that occurs as this tissue regresses. These results taken together with those previously published (Paavola, '78) further indicate that breakdown of the corpus luteum during postpartum luteolysis in guinea pigs involves both autophagy and heterophagy.     

SNF4Agamma, the Drosophila AMPK gamma subunit is required for regulation of developmental and stress-induced autophagy

In holometabolous insects including Drosophila melanogaster a wave of autophagy triggered by 20-hydroxyecdysone is observed in the larval tissues during the third larval stage of metamorphosis. We used this model system to study the genetic regulation of autophagy. We performed a genetic screen to select P-element insertions that affect autophagy in the larval fat body. Light and electron microscopy of one of the isolated mutants (l(3)S005042) revealed the absence of autophagic vesicles in their fat body cells during the third larval stage. We show that formation of autophagic vesicles cannot be induced by 20-hydroxyecdysone in the tissues of mutant flies and represent evidence demonstrating that the failure to form autophagic vesicles is due to the insertion of a P-element into the gene coding SNF4Agamma, the Drosophila homologue of the AMPK (AMP-activated protein kinase) gamma subunit. The ability to form autophagic vesicles (wild-type phenotype) can be restored by remobilization of the P-element in the mutant. Silencing of SNF4Agamma by RNAi suppresses autophagic vesicle formation in wild-type flies. We raised an antibody against SNF4Agamma and showed that this gene product is constitutively present in the wild-type larval tissues during postembryonal development. SNF4Agamma is nearly absent from the cells of homozygous mutants. SNF4Agamma translocates into the nuclei of fat body cells at the onset of the wandering stage concurrently with the beginning of the autophagic process. Our results demonstrate that SNF4Agamma has an essential role in the regulation of autophagy in Drosophila larval fat body cells.     

Regulation of hemoglobin synthesis by ecdysterone and juvenile hormone during development of Chironomus thummi (Diptera)

Chironomus thummi contains nine soluble hemoglobins (Hbs) in the larval hemolymph which can be resolved by 12.7% acrylamide gel electrophoresis (pH 8.65). Hemoglobins 2 and 3 are stage specific for the 4th instar and are first detected by day 4 of this stage in vivo, being absent in the 3rd instar. Fat-body cultures in the presence of 3H-delta-aminolevulinic acid and 14C-amino acids synthesize and secrete labelled Hbs, as was assayed by acrylamide gel electrophoresis and immunoprecipitation of Hbs recovered from the culture medium. During development from 3rd instar to pupa, Chironomus fat body undergoes functional changes, being actively involved in Hb synthesis in intermolt periods and inactive with respect to Hb production during molting. The repression of Hb synthesis is reversed following the molt from the 3rd instar to the 4th instar. Metamorphosis is related to a gradual and irreversible loss of Hb synthesis and secretion by the fat body. The treatment of fat body in vitro with ecdysterone inhibits Hb synthesis in tissue from intermolt animals, even in the presence of excess methoprene, a potent juvenile hormone analogue. In contrast, immunoprecipitation of the translation products from a wheat-germ cell-free system, using mRNA from ecdysterone-treated 4th-instar fat body as a template, shows significant synthesis of globins, suggesting that ecdysterone does not affect the amount or template activity of globin messages. Methoprene induces the precocious in vitro synthesis of Hbs 2 and 3 in day-2 4th-instar fat body and enhances all Hb synthesis in the absence of ecdysterone. In vitro treatment with methoprene activates newly molted fat body to synthesize Hbs 2 and 3 in vitro. The process of Hb induction by this analogue is completely inhibited by actinomycin D or ecdysterone. Fat body from animals already exposed to high endogeneous ecdysterone titer are insensitive to treatment with this juvenile hormone analogue. Intermolt larvae normally possess stable Hb mRNA molecules, because actinomycin-D administration in vitro does not affect Hb synthesis for as long as 30 h, whereas it effectively inhibits all RNA synthesis in the fat body. Immunoprecipitation of globin translated in vitro from mRNA from 2-day-old 4th-instar larvae treated in vivo with methoprene shows enhanced synthesis of globins 2 and 3, as compared to controls with no treatment. It is suggested that both juvenile hormone and ecdysterone regulate Hb synthesis in Chironomus; juvenile hormone affecting the activity of Hb genes, and ecdysterone modulating the level of Hb gene expression.     

Inhibition of the formation of protein storage granules by glutaurine in the larval fat body cells of Mamestra brassicae (Insecta, Lepidoptera)

Correlative changes in the protein contents of haemolymph and fat body and the accumulation of protein storage granules in the fat body cells of Mamestra brassicae were investigated during the last larval stage in normally developing larvae and following administration of glutaurine (1 X 10(-4) mg/g body weight). The protein content of the haemolymph of untreated larvae increased up to the 4th day of the stage, declined during days 5 and 6, and increased again before pupation. In the glutaurine-treated larvae the amount of proteins in the haemolymph was as high as in the controls during the first four days but continued to rise up to the end of the stage. The protein content of the fat body started to increase from the 3rd day and heavy accumulation of protein storage granules in the cells of fat body was observed on the 5th and following days. The protein content of the fat body of glutaurine-treated larvae remained at a low level and the protein storage granules were absent in the cells. The inhibition of the selective uptake of haemolymphatic storage proteins by fat body following glutaurine treatment is suggested.     

A novel role for the Drosophila epsin (lqf): Involvement in autophagy

Screening P-element-induced mutant collections, 52 lines were selected as potentially defected ones in endocytosis or autophagy. After excluding those which were rescued by 20-hydroxyecdosone treatment, the exact position of the inserted P-element was determined in the remaining lines. In the case of l(3)S011027 stock, that liquid facets (lqf) gene was affected which codes an epsin-homolog protein in Drosophila. We reveal that Lqf is essential to the receptor-mediated endocytosis of larval serum proteins (LSPs) in the larval fat body cells of Drosophila. In l(3)S011027 line, lack of Lqf fails the formation of autophagosomes thus leading to the arrest of destroying of trophocytes. Transgenic larvae carrying Lqf-RNAi construct were unable to generate endocytic and autophagic vacuoles and led to a prolonged larval stage. On the other hand, GFP-tagged Lqf protein showed an exclusively co-localization with the LysoTracker Red- or GFP-Atg8a labeled autophagosomes. By using the antiserum generated against the fifth exon of lqf, we demonstrated that prior to the onset of developmental autophagy the Lqf protein was present in the nucleus of fat body cell, but thereafter the protein was localized in the territory of endocytic and autophagic vacuoles. The fact that the inhibition of the target of rapamycin (TOR) did not restore the autophagic process and the normal development in the case of lqf mutant larvae points to that the Lqf is downstream to the TOR, the central kinase of the autophagy pathway.     

Age-dependent changes of fat body stores and the regulation of fat body lipid synthesis and mobilisation by adipokinetic hormone in the last larval instar of the cricket, Gryllus bimaculatus

Data on the hormonal regulation of the formation and mobilisation of fat body stores are presented and discussed in relation to general parameters of last instar larval development such as growth, food intake, and moulting. Crickets feed voraciously during the first half of the last larval stage. With the onset of feeding, fat body lipid synthesis increases, leading to increasing lipid stores in the fat body with a maximum reached on day 5. Lipid (42% of fat body fresh mass) is the main constituent of the fat body stores, followed by protein (6%) and glycogen (2%). During the second half of the last larval stage, feeding activity dramatically decreases, the glycogen reserves are depleted but lipid and protein reserves in the fat body remain at a high level except for the last day of the last larval stage when lipid and protein in the fat body are also largely depleted. The process of moulting consumes almost three quarters of the caloric equivalents that were acquired during the last larval stage. Adipokinetic hormone (AKH) inhibits effectively the synthesis of lipids in the larval fat body. Furthermore, AKH stimulates lipid mobilisation by activating fat body triacylglycerol lipase (TGL) in last larval and adult crickets. Both effects of AKH are weaker in larvae than in adults. This is the first report on the age-dependent basal activity of TGL in larval and adult insects. In addition, for the first time, an activation of TGL by AKH in a larval insect is shown.     

Regional differentiation of fat bodies in larvae of the indianmeal moth,Plodia interpunctella

Larvae of the Indianmeal moth, Plodia interpunctella, contain two morphologically distinct fat bodies. Tan-colored, highly tracheated fat body located posteriorly in the abdomen was the predominant fat body tissue during the early larval instars. White, sheet fat body located more anteriorly became the predominant type during the fifth (last) larval instar and eventually occupied most of the space of the hemocoel. Ultrastructural morphology of tan fat body showed the tissue to be composed of cells containing numerous, large, spherical mitochondria, with only few lipid, glycogen, or protein storage structures. In contrast, white fat body was composed of cells that in later larval stages had organelles typical of storage functions. Both fat bodies produced storage proteins during the late fifth instar, whereas only white fat body accumulated the storage proteins. Tan fat body dispersed and apparently autolyzed in pharate pupae, whereas the white fat body metamorphosed and persisted into the adult stage. These observations indicate that fat body of the Indianmeal moth is functionally and morphologically differentiated along the anterior-posterior axis into two regional subgroups of cells.     

Ultrastructural aspects of histolytic processes in the salivary gland cells during metamorphic stages in Rhynchosciara hollaenderi (Diptera, Sciaridae).

The cytoplasm of Rhynchosciara hollaenderi late larval, prepupal and pupal salivary gland cells was studied at the ultrastructural level. In the second half of the 4th instar, evidence of an intensive secretory activity is visible in the form of numerous secretory granules in the apical area of the cells. At the same stage, the endoplasmic reticulum cisternae adjacent to Golgi groups are active in the transfer of vesicular elements. At later stages this activity rapidly diminishes. Before the appearance of the DNA puffs, i.e. at the end of the 4th instar, mitochondria begin to show a granular deposit and normal mitochondria decrease in number. These with the granular deposit form clusters and initiate formation of single autophagic vacuoles before the appearance of the DNA puffs. Later, at the time, when the 2B puff opens, the autophagic vacuoles appear in great number. Simultaneously with the formation of the autophagic vacuoles the presence of acid phosphatase in the Golgi vesicles and in autophagic vacuoles was shown. In the last stages investigated (late pupae) acid phosphatase is present free in the cytoplasm and at the same time disappearance of free ribosomes, pycnosis of polytene chromosomes and breakage of nuclear membranes occur. It is concluded that the histolysis of the salivary gland cells begins before the large DNA puffs appear, then it becomes very intensive and continues after these puffs undergo regression.     

Ecdysterone induced protein synthesis in salivary glands and in fat body of Drosophila melanogaster larvae

Salivary glands of 3rd instar larvae of Drosophila melanogaster were labeled with ³H-leucine in the presence and absence of ecdysterone. Twentysix ecdysterone inducible proteins were detected. Their induction was correlated with puff stage. Synthesis of fifteen proteins commenced during early puff stage (PS2); synthesis of seven others at late puff stages (PS8–10). Synthesis of four proteins was induced between puff stage 3/4 and 7/8. Thus, the hormonal induction of protein synthesis generally reflected the appearance of early and of late puffs as described by Ashburner (1972). Eleven ecdysterone inducible proteins were detected in larval fat body in vitro. Comparison of the fat body to the salivary gland proteins revealed that one of the ecdysterone induced fat body proteins was identical in molecular weight and charge to one of the proteins induced by ecdysterone in salivary glands.     

The ontogeny of the alimentary tract of coregonid larvae: normal development

The development of the alimentary tract in larvae of Coregonus fera fed with Anemia nauplii has been examined histologically from the 4th to the 24th day after hatching.
Buccal cavity and oesophagus are nearly completely developed before the start of feeding. The stomach exists only as an 'anlage', but starts to store food during the study period. The intestinal absorptive cells are stuffed with fat vacuoles between the 7th and 13th day after the start of feeding. During this time the rectal absorptive cells contain one large supranuclear body consisting of protein. The occurrence of large vacuoles in the intestinal and rectal absorptive cells may be caused by a partial non-functioning of the larval digestion; after two weeks of feeding this restriction seems to be overcome.     

Moulting hormone,juvenile hormone and the ultrastructure of the fat body of adult Sarcophaga bullata (Diptera)

Summary In the ovoviviparous fly, Sarcophaga bullata, vitellogenesis is cyclic; a process reflected in ultrastructural changes in the fat body cells and oenocytes. At eclosion the larval fat body has not yet completely disappeared. During vitellogenesis the fat body cells are specialized for intensive protein synthesis showing a very extensive RER and numerous invaginations of the plasma membrane. These features disappear when the eggs descend into the oviducts to complete embryogenesis. The predominant feature of the oenocytes is their very prominent SER. The fat body cells of the males are never as specialized for protein synthesis as those of the females. Feeding of ecdysterone to males for 3 or more days induces a rather extensive subcellular apparatus for protein synthesis, i.e., invaginations of the plasma membrane and an extensive RER. Juvenile hormone is completely ineffective in this respect. Both ecdysterone and juvenile hormone have pronounced but different effects on the oenocytes of males.     

Cell differentiation during the ontogeny of larval salivary glands of the fly, Telmatoscopus albipunctatus

Using the larvae, pharate pupa, and pharate adults of the moth fly, Telmatoscopus albipunctatus, histological and ultrastructural features of the salivary glands were investigated. The gland lumen contains a milky secretion from the first instar. This secretion continues to ccur at all subsequent developmental stages; with the onset of the pharate pupal stage, however, the secretion becomes transparent and rather viscous. Histochemical tests revealed that it is mainly proteinaceous. Glands from the same developmental stage may respond differently to PAS-reaction.Various cell organelles were compared at consecutive stages of larval development and of secretory activity of the salivary glands. In first and second instar larvae autophagic vacuoles are virtually absent in the salivary gland cells. They were occasionally found in the third instar, when they appear to be engaged in the process of organelle turnover. Histolysis of the larval glands is initiated towards the close of the fourth instar when the number of autophagic vacuoles starts to increase. Simultaneously, the cytoplasm, previously full of ribosomes and endoplasmic reticulum, starts losing these structures. At the beginning of the pharate adult stage, the cytoplasm becomes practically devoid of all structures other than those engaged in autophagy.Polyteny of the chromosomes during ontogeny of the larval salivary glands is also discussed.     

A fine structural survey of the development of the adult fat body of Leptinotarsa decemlineata

The fat body of a female Colorado potato beetle, Leptinotarsa decemlineata, at adult ecdysis, contains a large number of protein granules which are composed of light and dark zones. Part of the light zone in some of these granules is believed to be urate. During the first two days after adult ecdysis, fat body development is not essentially different in females reared either under long- or short-day conditions. Protein granules and large vacuoles disappear and the first cell organelles are regenerated. The effect of the photoperiod on the histological structure of the fat is expressed after these events. In females reared under long-day conditions, the fat body becomes specialized for vitellogenin synthesis. Under short-day conditions, the fat body stores massive amounts of lipid until day 6 after adult ecdysis. Then the first electron-dense protein granules develop near the nucleus, and on day 10 the first autophagic vacuoles are seen. These structure changes are discussed in connection with the known biochemical properties of the adult faty body of Leptinotarsa.     

Tyrosine storage vacuoles in insect fat body

The watery vacuoles first described from larval insect fat body (Chironomus, Voinov, 1927; Aedes, Wigglesworth, 1942; Rhodnius, Wigglesworth, 1967) have been studied in 4th and 5th stage Calpodes larvae. The vacuoles arise at the beginning (E+6–24 hr) of the 4th stadium from plasma membrane infolds that separate from the cell surface as provacuoles less than 1 μm in diameter. These provacuoles grow and fuse with one another through the intermolt until about half the volume of each fat body cell is occupied by a single, large vacuole. The vacuoles begin to disappear at molting. Their membrane is either incorporated into the plasma membrane by exocytosis or fragmented into vesicles that fuse to become lamellar bodies where the membranes are presumably digested. All the vacuoles have gone by a few hours after ecdysis.The tyrosine content of the fat body increases and decreases in proportion to the size of the vacuoles. As the vacuoles decrease at molting the titre of tyrosine in the hemolymph is transiently elevated at the time when there is most demand for phenolics for cuticle stabilization. Crystals having the form of tyrosine crystallize out from vacuoles separated from the fat body. In fat body extracts separated by thin layer chromatography, similar crystals occur only in the eluates from spots corresponding to tyrosine. The vacuoles are therefore presumed to be tyrosine stores used in cuticle stabilization at molting. They correspond to a type of aqueous storage compartment that is well known in plants but hitherto little recognized in animal cells.     

The effects of actinomycin D,cycloheximide and puromycin on the 20-hydroxyecdysone induced autophagocytosis in larval fat body cells of Pieris brassicae

The effects of 20-hydroxyecdysone (5 μg/g body weight), cycloheximide (5 μg/g body weight), puromycin (30 μg/g body weight) and actinomycin D (30 μg/g body weight) were investigated on the larval fat body cells of 48–70-hours-old last instar larvae of Pieris brassicae.20-Hydroxyecdysone was found to induce the formation of autophagic vacuoles 3 hr after its administration, but this was, however, prevented by simultaneous cycloheximide treatment in a parallel experiment. On the contrary, puromycin proved to induce autophagocytosis. These diverse effects of the two translational inhibitors on hormone-induced autophagocytosis may be explained by differences in their modes of action.Actinomycin D, when administered 21 hr prior to the hormone, exerted a preventive effect on induced autophagocytosis, but was ineffective when applied 3 hr before the injection of 20-hydroxyecdysone.It was concluded that the presence of RNA synthesized several hours prior to the hormone treatment was a prerequisite for induction of autophagocytosis by 20-hydroxyecdysone.