Hormonal control of uric acid storage in the fat body during last-larval instar of Manduca sexta

In the last-larval instar of the tobacco hornworm, Manduca sexta, a switch from excretion of uric acid to storage in the fat body occurs during transition from the feeding to the wandering stage. Neuroendocrine control of this change from excretion to storage was demonstrated by neck-ligation experiments with synchronously reared larvae. Results indicate that a neurohormone is released from the head 24–30 hr before the initiation of wandering and coincident with the first release of ecdysone that initiates metamorphosis. Direct involvement of the moulting hormone was shown by the effects of multiple injections of 20-hydroxyecdysone into the abdomen of larvae that had been ligated before the release of hormone. Urate levels in the fat body were 20- to 100-fold higher from hormone-injected larvae as from saline inject controls. Topically applied juvenile hormone or methoprene reversed the 20-hydroxyecdysone-induced storage of urate. Increased levels of uric acid in the haemolymph during pupal development result from the presence of juvenile hormone, and the abrupt decrease in uric acid concentration in the haemolymph just prior to pupal ecdysis results from a decreased titre of juvenile hormone. Applications of methoprene prevented the decrease in uric acid levels in the haemolymph.     

Uric acid levels during last larval instar of Manduca sexta, an abrupt transition from excretion to storage in fat body

Levels of uric acid in the whole body of the tobacco hornworm, Manduca sexta increased steadily for the 9 days of the fifth instar. However, concentrations in the haemolymph were lowest during the transition from the feeding stage to the wandering stage (days 3, 4), the time when there was a switch from uric acid excretion by the Malpighian tubule-hindgut system to storage in the fat body. Haemolymph volumes, determined for larvae between 2 and 6 days into the fifth instar by isotope dilution with [¹⁴C]-inulin, were used to calculate rates of incorporation of uric acid into Malpighian tubules and fat body of larvae injected with [¹⁴C]-uric acid. These labelling studies indicated that the Malpighian tubules ceased to remove uric acid from the haemolymph some time between the last 6 hr of day 3 of the fifth instar and the first 18 hr of day 4. At the same period, fat body removed significant quantities of uric acid from the haemolymph. The times of initial decreases and increases in levels of uric acid in haemolymph and fat body, respectively, indicated that storage in the fat body started before cessation of elimination via the Malpighian tubule-hindgut system.     

Roles of fat body trophocytes,mycetocytes and urocytes in the American cockroach,Periplaneta americana under starvation conditions: An ultrastructural study

In insects, trophocytes (adipocytes) are major cells of a storage organ, the fat body, from which stored glycogen and lipids are mobilized under starvation. However, cockroaches have 2 additional types of cell in the fat body: mycetocytes harboring an endosymbiont, Blattabacterium cuenoti, and urocytes depositing uric acid in urate vacuoles. These cells have not been investigated in terms of their roles under starvation conditions. To gain insight into the roles of trophocytes, mycetocytes and urocytes in cockroaches, structural changes were first investigated in the cells associated with starvation in the American cockroach, Periplaneta americana, by light and electron microscopy. The area of lipid droplets in trophocytes, the endosymbiont population and mitotic activity in mycetocytes, and the area of urate vacuoles in urocytes were analyzed in association with survival rates of the starved cockroaches. After 2 weeks of starvation, trophocytes lost glycogen rosettes and their area of lipid droplets decreased, but almost all cockroaches survived this period. However, further starvation did not reduce the area, but the survival rates dropped rapidly and all cockroaches died in 7 weeks. Endosymbionts were not affected in terms of population size and mitotic activity, even if the cockroaches were dying. The area of urate vacuoles rapidly decreased in a week of starvation and did not recover upon further starvation. These results indicate that starved cockroaches mobilize glycogen and lipids stored in trophocytes to survive for 2 weeks and then die after the exhaustion of nutrients in these cells. Endosymbionts are not digested for the recycling of nutrients, but uric acid is reused under starvation.     

Cloning of PaAtg8 and roles of autophagy in adaptation to starvation with respect to the fat body and midgut of the Americana cockroach,Periplaneta americana

Starvation, in particular amino acid deprivation, induces autophagy in trophocytes (adipocytes), the major component of the fat body cell types, in the larvae of Drosophila melanogaster. However, the fat body of cockroach has two additional cell types: urocytes depositing uric acid in urate vacuoles as a nitrogen resource and mycetocytes harboring an endosymbiont, Blattabacterium cuenoti, which can synthesize amino acids from the metabolites of the stored uric acid. These cells might complement the roles of autophagy in recycling amino acids in the fat body or other organs of cockroaches under starvation. We investigate the presence of autophagy in tissues such as the fat body and midgut of the American cockroach, Periplaneta americana, under starvation by immunoblotting with antibody against Atg8, a ubiquitin-like protein required for the formation of autophagosomes and by electron microscopy. Corresponding changes in acid phosphatase activity were also investigated as representing lysosome activity. Starvation increased the level of an autophagic marker, Atg8-II, in both the tissues, extensively stimulating the formation of autophagic compartments in trophocytes of the fat body and columnar cells of the midgut for over 2 weeks. Acid phosphatase showed no significant increase in the fat body of the starved cockroaches but was higher in the midgut of the continuously fed animals. Thus, a distinct autophagic mechanism operates in these tissues under starvation of 2 weeks and longer. The late induction of autophagy implies exhaustion of the stored uric acid in the fat body. High activity of acid phosphatase in the midgut of the fed cockroaches might represent enhanced assimilation and not an autophagy-related function.     

Histochemical studies of uric acid in some insects. 2. Uric acid and polyphenols in the fat body

It is recalled that in the larva of Aedes aegypti, starved after a rich protein diet, uric acid is formed and accumulates in the fat body, not as solid spheres but in high concentration in aqueous vacuoles. In the mature larva of Celliphora vicina which has finished feeding and is settling down to form the puparium, the fat body at first contains no argentaffin deposits. During the following 2 or 3 days, argentaffin material appears in the form of amber or brown vesicles and black granules of all sizes. Some of this material remains in the fat body cells; but a large part, presumably polyphenols, is discharged from the cells so that finally all the amber staining disappears and only black granules remain. During this transfer the epidermal cells become charged with sclerotin precursors, which are transferred into the outer part of the cuticle to form the puparium. The stored uric acid remains in the fat body and is dispersed during adult development and ultimately excreted.     

Uric acid metabolism during pupal-adult development of Pieris brassicae

Uric acid metabolism has been investigated during the pupal and adult stages of Pieris brassicae. Uric acid and its main metabolite, allantoic acid, have been quantified in various organs (fat body, gut, wings) during development, in order to determine synthesis, degradation, and transport phenomena. Both labelling experiments (using 2-¹⁴C uric acid, guanine, and guanosine) and enzymatic studies (xanthine dehydrogenase, guanine deaminase, and uricase) were performed.Labelled uric acid, when injected into a young pupa, accumulates preferentially into the fat body, and its degradation leads to an increase in allantoic acid, which is found chiefly in imaginal structures (wings, heads, body wall). Since uricase is present only in low levels through the pupal stage, only a small fraction of uric acid is metabolized.In the developing pharate adult, uric acid is transported via the haemolymph from fat body to the wings and gut. Male wings accumulate more uric acid than female wings. At emergence, a large amount of uric acid and most of the allantoic acid are excreted into the meconium, but not together; uric acid is excreted into the so-called ‘meconium 1’ containing ommochromes, whereas its metabolite is eliminated only after wing expansion into ‘meconium 2’, a colourless fluid. Shortly before emergence, the fat body recovers its ability to synthesize uric acid, a fraction of which is excreted within ‘meconium 1’.During adult life, the synthesis of uric acid occurs in the fat body and ovaries, where it is especially abundant. Ageing organs (wings, heads, testes) accumulate it markedly. A small fraction is excreted together with allantoic acid by the butterfly.Purine catabolism pathways have been investigated, showing that in guanine derivatives, the freebase state of guanine leads quickly to uric acid (and its metabolites), whereas ¹⁴C-guanosine may be transformed into nucleotide and incorporated efficiently into wing pteridines when it is injected at the time of adult pigmentation.Another purine derivative, identified as adenosine, has been shown to accumulate in male fat body just before adult emergence. Its amount increases during the first days of emerged adult life, and it corresponds to an alternative pathway of purine catabolism. Its absence in females is related to development of the ovaries.     

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.     

Cell death and tissue reorganization in Rhynchosciara americana (Sciaridae: Diptera) metamorphosis and their relation to molting hormone titers

Programmed cell death (PCD) is a focal topic for understanding processes underlying metamorphosis in insects, especially so in holometabolous orders. During adult morphogenesis it allows for the elimination of larva-specific tissues and the reorganization of others for their functionalities in adult life. In Rhynchosciara, this PCD process could be classified as autophagic cell death, yet the expression of apoptosis-related genes and certain morphological aspects suggest that processes, autophagy and apoptosis may be involved. Aiming to reveal the morphological changes that salivary gland and fat body cells undergo during metamorphosis we conducted microscopy analyses to detect chromatin condensation and fragmentation, as well as alterations in the cytoplasm of late pupal tissues of Rhynchosciara americana. Transmission electron microscopy and confocal microscopy revealed cells in variable stages of death. By analyzing the morphological structure of the salivary gland we observed the presence of cells with autophagic vacuoles and apoptotic bodies and DNA fragmentation was confirmed with the TUNEL assay in salivary gland. The reorganization of fat body occurs with discrete detection of cell death by TUNEL assay. However, both salivary gland histolysis and fat body reorganization occur under control of the hormone ecdysone.     

Changes in the fat body during the post-embryonic development of the predator Toxorhynchites theobaldi (Dyar & Knab) (Diptera: Culicidae)

Several studies have focused on understanding the biochemistry and morphology of the fat body of the hematophagous mosquito Aedes aegypti (L.) (Diptera: Culicidae). In contrast, few studies, if any, have focused on morphological characters of the fat body in other mosquitoes, especially non-hematophagous taxa such as the culicid Toxorhynchites. Larvae of Toxorhynchites prey upon the larvae of other mosquito species and are used in vector mosquito control. We investigated aspects of the fat body trophocytes, including the morphometric analyses of the lipid droplets, protein granules and nuclei, during Toxorhynchites theobaldi (Dyar & Knab) post-embryonic development. Following the body weight increase from larval stage L2 to L4, the size of lipid droplets within the trophocytes also increase, and are likely the result of lipogenesis. Lipid droplets decrease in size during L4 to the female pupal stage and increase once again during the period from newly-emerged to mature adult females. Protein granules are observed for the first time in female pupae, and their appearance might be related to protein storage during metamorphosis. The size of the nucleus of trophocytes also increases during larval development, followed by a decrease during metamorphosis and an additional increase as adult female ages. In conclusion, the morphology of the fat body of T. theobaldi changes according to the developmental stage. Our study provides for the first time important insights into T. theobaldi fat body development and contributes to understand this species biology.     

Histochemical studies of uric acid in some insects. 3. Excretion of uric acid by the malpighian tubules in Calliphora vicina and Rhodnius prolixus

In adult Calliphora uric acid is excreted throughout the Malpighian tubules. Histochemical preparations for the light microscope show uric acid passing through the cells and forming crystalline spheres in immediate contact with the microvilli. Uric acid appears to be synthesized and discharged into the haemolymph by the fat body cells. In Rhodnius there is no visible uric acid in the cells or lumen of the upper segment of the tubule (two-thirds of the total length of the tubule) apart from occasional deposits in the basal lamina. All uric acid excretion depends on the lower segment. Electron micrographs after argentaffin staining show high concentration of uric acid in the cytoplasm below the basal lamina (which also contains uric acid deposits). Uric acid is visible throughout the cell, particularly aroand the mitochondria; it is absent from the infolded plasma membrane and from all vacuoles. At the lumen there is a concentrated deposit of uric acid immediately beyond the plasma membrane. The uric acid particles unite with particles of unstained matrix material to form crystalline spheres. The fat body shows active synthesis of uric acid which is discharged by the cells into the intercellular channels and so to the basal lamina through which it passes into the haemolymph. As judged by histochemical preparations the haemolymph contains a high concentration of uric acid, very variable in different sites. Likewise large variations in uric acid secretion occur in different parts of the fat body.     

Ultrastructure of fat body cells of the velvetbean caterpillar infected with a nuclear polyhedrosis virus

During a study of the ultrastructure of a nuclear polyhedrosis virus of the velvetbean caterpillar, Anticarsia gemmatalis, various types of nuclear and cytoplasmic inclusions were found in fat body tissue heavily infected with the virus. Virogenic stroma was present in the nuclei of most infected cells. Bundles of fibrous material were observed in the nuclei and cytoplasm of cells containing polyhedral bodies. Other nuclear inclusions included concentric multilayered material, vacuoles, and membrane structures.     

Allantoin and allantoic acid titre in the faeces and tissues of the developing larva of the moth, Orthaga exvinacea Hampson

Allantoin and allantoic acid are investigated in the faeces and tissues of the developing sixth instar larva of the moth, Orthaga exvinacea. The nitrogen excreted as allantoin and allantoic acid is compared with nitrogen excreted as uric acid and ammonia. The larva excretes 2.35–5.14 μmol/g allantoin and 0.74–1.34 μmol/g allantoic acid which account for 0.83 to 2.39% and 0.23 to 0.53%, respectively, of the excreted total nitrogen. Allantoin and allantoic acid are found to be minor nitrogenous end-products of the larva. Allantoin and allantoic acid are also present in the haemolymph and fat body of the larva in varying concentrations. The level of allantoin in the haemolymph shows a negative correlation with the allantoin concentration of faeces and fat body. The allantoin is found to be stored in the fat body at a low level. The results of the present study also indicate the coexistence of uric acid storage and uricolysis.     

Expression and localization of storage protein 1 (SP1) in differentiated fat body tissues of red hairy caterpillar, Amsacta albistriga Walker

The accumulation and utilization of storage proteins are prominent events linked to the metamorphosis of holometabolous insects. The female-specific storage protein 1 (SP1) is the major storage protein found in the hemolymph and fat body of female larvae of the groundnut pest, Amsacta albistriga. Here we show SP1 expression and localization in differentiated fat body tissues using biochemical and immunohistochemistry scrutiny. Comparison of A. albistriga SP1 with that of other species with respect to amino acid composition and N-terminal sequences show that SP1 is a methonine-rich protein and its identity was confirmed by means of immunoblot analysis. Northern blot studies revealed that the SP1 gene demonstrates stage- and tissue-specific expression in the peripheral fat body cells during the mid-larval period of fifth instar of A. albistriga. During the larval pupal transformation, SP1 are sequestered mainly by the perivisceral fat body tissues, until they serve the purpose of supplying amino acids for the production of egg yolk proteins. Further, electron microscopic studies using immunogold tracer techniques confirmed the localization of crystalline SP1 reserves, stored in the perivisceral fat body tissues. Hence, the peripheral fat body is responsible for biosynthesis of storage proteins, whereas the perivisceral fat body is a specialized storage organ.     

The fat body of bullfrog (Lithobates catesbeianus) tadpoles during metamorphosis: changes in mass, histology, and melatonin content and effect of food deprivation

The fat body of Lithobates catesbeianus (formerly Rana catesbeiana) tadpoles was studied during metamorphosis and after food deprivation in order to detect changes in its weight, adipocyte size, histology, and melatonin content. Bullfrog tadpoles have large fat bodies throughout their long larval life. Fat bodies increase in absolute weight, and weight relative to body mass, during late stages of prometamorphosis, peaking just before climax, and then decreasing, especially during the latter stages of transformation into the froglet. The climax decrease is accompanied by a reduction in size of adipocytes and a change in histology of the fat body such that interstitial tissue becomes more prominent. Food deprivation for a month during early prometamorphosis significantly decreased fat body weight and adipocyte size but did not affect the rate of development. However, food restriction just before climax retarded development, suggesting that the increased nutrient storage in the fat body before climax is necessary for metamorphic progress. Melatonin, which might be involved in the regulation of seasonal changes in fat stores, stayed approximately at the same level during most of larval life, but increased sharply in the fat body during the late stages of climax. The findings show that the rate of development of these tadpoles is not affected by starvation during larval life as long as they can utilize fat body stores for nourishment. They also suggest that the build up of fat body stores just before climax is necessary for progress during the climax period when feeding stops.     

The Role of Storage Lipids in the Relation between Fecundity,Locomotor Activity,and Lifespan of Drosophila melanogaster Longevity-Selected and Control Lines

The contribution of insect fat body to multiple processes, such as development, metamorphosis, activity, and reproduction results in trade-offs between life history traits. In the present study, age-induced modulation of storage lipid composition in Drosophila melanogaster longevity-selected (L) and non-selected control (C) lines was studied and the correlation between total body fat mass and lifespan assessed. The trade-offs between fecundity, locomotor activity, and lifespan were re-evaluated from a lipid-related metabolic perspective. Fewer storage lipids in the L lines compared to the C lines supports the impact of body fat mass on extended lifespan. The higher rate of fecundity and locomotor activity in the L lines may increase the lipid metabolism and enhance the lipolysis of storage lipids, reducing fat reserves. The correlation between neutral lipid fatty acids and fecundity, as well as locomotor activity, varied across age groups and between the L and C lines. The fatty acids that correlated with egg production were different from the fatty acids that correlated with locomotor activity. The present study suggests that fecundity and locomotor activity may positively affect the lifespan of D. melanogaster through the inhibition of fat accumulation.     

The induction of autophagy in isolated insect fat body by β-ecdysone

The fat body in Calpodes undergoes sequential organelle specific autophagy as a first step in the cell remodeling process necessary for metamorphosis to the pupa. This autophagy begins at about 36 hr before pupation and coincides with a critical period after which an isolated abdomen will pupate without further influence from the prothoracic glands. This suggested that autophagy might be induced by ecdysone. Fat body taken before the critical period and cultured in a medium containing β-ecdysone undergoes autophagy. Fat body from the same animal maintained in hormone-free medium retains the pre-critical period morphology with no autophagy. Autophagy is therefore directly induced by β-ecdysone. Fat body taken soon after the critical period continues with the autophagic sequence in hormone-free medium. Therefore the entire autophagic sequence is induced and does not require the continuing presence of hormone. Protein storage granule formation and cell dissociation, which occur in fat body at metamorphosis, are also induced by β-ecdysone.     

Ultrastructure and cytochemistry of glycogen-containing vacuoles in gastrodermal cells in developing hydranths of a hydromedusan coelenterate

Hydranth buds from the colonial hydroid Sertularia pumila (Hydromedusae) were observed by electron microscopy during their development. Before hydranth expansion, the gastrodermal columnar digestive cells had large numbers of vacuoles. These vacuoles contained many membranous components as well as α-glycogen and dense ring- and crescent-shaped bodies. The rings and crescents were not osmiophilic, but did react to periodic acid oxidation in the PA-TSC-SP test for carbohydrate. These structures were digestible by α-amylase and pullulanase. The chemical analyses and the close association of the rings and crescents to α-glycogen particles showed that they may be a highly condensed form of glycogen. Golgi bodies in association with the gastrodermal vacuoles had acid phosphatase activity. This enzyme was only slightly active in the vacuoles. It is suggested that the vacuoles arc primarily storage organelles with a potential for digestion.     

The control of lipid metabolism by mRNA splicing in Drosophila

The storage of lipids is an evolutionarily conserved process that is important for the survival of organisms during shifts in nutrient availability. Triglycerides are stored in lipid droplets, but the mechanisms of how lipids are stored in these structures are poorly understood. Previous in vitro RNAi screens have implicated several components of the spliceosome in controlling lipid droplet formation and storage, but the in vivo relevance of these phenotypes is unclear. In this study, we identify specific members of the splicing machinery that are necessary for normal triglyceride storage in the Drosophila fat body. Decreasing the expression of the splicing factors U1-70K, U2AF38, U2AF50 in the fat body resulted in decreased triglyceride levels. Interestingly, while decreasing the SR protein 9G8 in the larval fat body yielded a similar triglyceride phenotype, its knockdown in the adult fat body resulted in a substantial increase in lipid stores. This increase in fat storage is due in part to altered splicing of the gene for the β-oxidation enzyme CPT1, producing an isoform with less enzymatic activity. Together, these data indicate a role for mRNA splicing in regulating lipid storage in Drosophila and provide a link between the regulation of gene expression and lipid homeostasis.