Detection of haemocyte proteins in the integument of the developing Mediterranean fruit flyCeratitis capitata

Summary Studies of the synthesis of integumental proteins during the feeding and non-feeding stages ofCeratitis capitata demonstrated stage specificity. The synthetic profile changed dramatically, showing a maximum of protein synthesis just before the larval wandering stage, followed by an abrupt decline. The comparison between synthetic and accumulation profiles indicated that some polypeptides must be internalized into the integument from the haemolymph. The major haemolymph proteins or arylphorins have already been documented to be incorporated into the integument. In the present work, we demonstrated the interalization of some haemocyte proteins into the integument. For that purpose, polyclonal antibodies were raised against total haemocyte proteins. Immunoblot analysis of haemocyte salt extractable proteins revealed that the protein bands at 36, 54, 58, 84, 110 and 130 kDa were immunoreactive with the total haemocyte antibodies. Cell-free protein synthesis, organ culture experiments and immunoblot analysis indicated that the 36-, 54- and 58-kDa polypeptides were synthesized only in the haemocytes and were probably internalized into the integument from the serum. The 36-kDa polypeptide was also demonstrated to be internalized into the fat body of white puparia. The immunofluorescence experiments suggested that the internalization of haemocyte proteins first occurs into the epidermal cells and then into the cuticle. The presence of haemocyte proteins in the integument was also demonstrated by immunofluorescence experiments in twoC. capitata mutants. These mutations affect the darkening and stiffening of the cuticle. The demonstration of 36-, 54- and 58-kDa haemocyte polypeptides in the integument reveals a hitherto unknown function of this cell type. Moreover, the demonstration of tyrosine binding to the 54- and 58-kDa polypeptides points to their potential involvement in the sclerotization process in the cuticle.     

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.     

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.     

Effects of methoprene,a juvenile hormone analogue,on the larval and pupal stages of the yellow fever mosquito, Aedes aegypti

Exposure of early fourth-instar larvae of Aedes aegypti to the juvenile hormone analogue Altosid ZR15^® (methoprene) significantly increased the concentration of carbohydrates in the haemolymph of late fourth-instar larvae and reduced the haemolymph carbohydrate concentration of 24-h-old pupae relative to controls. Such treatment also effected a decline in haemolymph amino nitrogen levels of the pupal stage and a depletion of haemolymph proteins in late fourth-instar larvae as well as pupae. Two of nine protein fractions in the haemolymph of larvae were significantly depleted following methoprene treatment. Fourteen soluble protein fractions were present in the haemolymph of control pupae; two of these were missing from the pupae which were treated as larvae with methoprene. A further protein fraction, common to the haemolymph of both treated and control pupae, was significantly reduced in concentration as a consequence of exposure to methoprene. The juvenile hormone analogue impaired the capacity of the fat bodies of late fourth-instar larvae and pupae to synthesise proteins, resulting in a lowered concentration of fat body proteins. Glycogen levels in the fat bodies of treated larvae were significantly lower than in controls and glycogenolysis was suppressed due to an overall depletion of glycogen phosphorylase and, in pupae, a lowered ratio of active: inactive enzyme. The data are consistent with the proposition that the juvenile hormone analogue elicits neuroendocrinological changes in the target insect.     

Diapause phenomena in non-diapausing last instar larvae,pupae, and pharate adults of the Colorado beetle

From the first day of the last (fourth) larval instar no trace of juvenile hormone (JH) can be detected in the haemolymph by Galleria bioassay. Three specific diapause proteins, which are also found in diapausing adults, appear in the haemolymph. These proteins disappear towards the end of the pupal stage. Study of the ultrastructure of the fat body revealed the formation from lysosomes of proteinaceous bodies which are also characteristic for adult diapause. The behaviour of last instar larvae and pupae resembles that of prediapausing and diapausing adults respectively. Injection of synthetic JH delays the appearance of the diapause proteins in the haemolymph and of proteinaceous bodies in the fat body for 2 to 3 days. The absence of JH seems to trigger off these diapause phenomena.     

Tryptophan metabolism during development of the stick insect,Carausius morosus Br. tissue distribution and interrelationships of metabolites of the kynurenine pathway

Summary During larval development ofCarausius morosus kynurenic acid is the major end product of tryptophan metabolism. Tryptophan and kynurenic acid have been found in the fat body, haemolymph and gut contents but only traces of kynurenine have been detected. The ommochromes ommin and xanthommatin are formed in relatively small amounts in the epidermis during larval development. 3-hydroxykynurenine was found only in the epidermis, the site of ommochrome deposition.During larval development, the amount of free tryptophan increases with body dry weight. The amount of kynurenic acid excreted also corresponds to the increase of body weight but is significantly reduced in the faeces of adults. This is related to a high tryptophan content of yolk proteins. The concentration of tryptophan in the haemolymph decreases immediately before ecdysis, whereas that in the gut increases during this time and falls sharply at the start of ecdysis.     

Protein metabolism by the salivary glands and other organs of the larva of the blowfly, Calliphora erythrocephala

Protein metabolism in salivary glands, gut, haemolymph, and fat body during the last larval instar of the blowfly, Calliphora erythrocephala, has been investigated. In salivary glands, protein release, protein synthesis, amylase, and pepsin-like protease activity were maximal in 6 day larvae, this being at a time when the larvae had finished feeding. All these functions declined in glands from the rounded-off white puparial stage (R.O.) while acid phosphatase activity rose throughout the third instar to a maximum at the R.O. stage, Glands from 6 and 7 day larvae released protein which on disk gel electrophoresis separated into four minor bands and two major bands one of the latter possessing protease activity.In the gut, pepsin-like protease activity was maximal in 4 day larvae after which it fell rapidly thus following the feeding pattern of the larva in contrast to that in the salivary glands which did not.In vitro experiments showed that protease was released from 6 day glands through the basal membrane of the cells and not via the duct. A pepsin-like protease was also found in the haemolymph and fat body, the activity in the fat body rising rapidly during the latter part of the third instar, a rise which is attributed to the fat body sequestering protease from the haemolymph. Acid phosphatase activity in the fat body was maximal in 5 day larvae indicating that this enzyme was synthesized early in the third instar. It was shown that fat body sequestered ¹⁴C-labelled protein synthesized by and released from the salivary glands, most of the ¹⁴C activity being associated with a 600 g precipitable, acid-phosphatase rich fraction.It is proposed that in late third instar larvae the salivary glands function as glands of internal secretion, releasing protease into the haemolymph, which is then sequestered by the fat body (and perhaps other tissues) and is subsequently used in the lysis of the tissues at the time of metamorphosis.     

Hormonal control of storage protein synthesis and uptake by the fat body in the silkworm, Bombyx mori

The female silkworm, Bombyx mori, rapidly accumulates two storage proteins, that are synthesized by the fat body, in the haemolymph during the feeding stage of the last-larval instar, and then sequesters them from the haemolymph into fat body during the larval-pupal transformation.The rapid synthesis and uptake of storage proteins by the fat body are shown to be induced by allatectomy in the early-penultimate larval instar. A juvenile hormone analogue, methoprene, is highly effective in inhibiting the allatectomy-induced synthesis, and, in a higher dosage, further blocks the uptake. Allatectomy in the late-penultimate larval instar shortly before moulting does not enhance the storage protein synthesis, but causes the uptake to occur two days earlier in the last-larval instar. Injection of 20-hydroxyecdysone is not stimulatory for synthesis of the proteins, but is effective to induce their uptake. Starvation during the early last-larval instar completely blocks the synthesis.From these results, it is suggested that storage protein synthesis is induced in the absence of juvenile hormone by some supplementary stimulus, possibly the supply of nutrient after feeding, and uptake is induced by ecdysteroids after a decline in the juvenile hormone level.     

Hormonal and nutritional regulation of insect fat body development and function

The insect fat body is an organ analogue to vertebrate adipose tissue and liver and functions as a major organ for nutrient storage and energy metabolism. Similar to other larval organs, fat body undergoes a developmental “remodeling” process during the period of insect metamorphosis, with the massive destruction of obsolete larval tissues by programmed cell death and the simultaneous growth and differentiation of adult tissues from small clusters of progenitor cells. Genetic ablation of Drosophila fat body cells during larval‐pupal transition results in lethality at the late pupal stage and changes sizes of other larval organs indicating that fat body is the center for pupal development and adult formation. Fat body development and function are largely regulated by several hormonal (i.e. insulin and ecdysteroids) and nutritional signals, including oncogenes and tumor suppressors in these pathways. Combining silkworm physiology with fruitfly genetics might provide a valuable system to understand the mystery of hormonal regulation of insect fat body development and function. © 2009 Wiley Periodicals, Inc.     

Heat shock response in mulberry silkworm races with different thermotolerances

The thermal sensitivity and heat shock response of the different races of the mulberry silkwormBombyx mori have been analysed. The multivoltine race, strainsC. Nichi andPure Mysore showed better survival rates than the bivoltine race, strainNB4D2 exposed to 41°C and above. In general, the fifth instar larvae and the pupae exhibited maximum tolerance compared to the early larval instars, adult moths or the eggs. Exposure up to 39°C for 1 or 2 h was tolerated equally whereas temperatures above 43°C proved to be lethal for all. Treatment of larvae at 41°C for 1 h resulted in a variety of physiological alterations including increased heart beat rates, differential haemocyte counts, enlargement of granulocytes and the presence of additional protein species in the tissues and haemolymph. The appearance of a 93 kDa protein in the haemolymph, fat bodies and cuticle, following the heat shocking of larvaein vivo was a characteristic feature in all the three strains examined although the kinetics of their appearance itself was different. In haemolymph, the protein appeared immediately in response to heat shock inC. Nichi reaching the maximal levels in 2–4 h whereas its presence was noticeable only after 2–4 h recovery time inPure Mysore and bivoltine races. The fat body from bothC. Nichi andNB4D2 showed the presence of 93 kDa, 89 kDa and 70 kDa proteins on heat shock. The haemocytes, on the other hand, expressed only a 70 kDa protein consequent to heat shock. The 93 kDa protein in the haemolymph, therefore could have arisen from some other tissue, possibly the fat body. The 93 kDa protein was detected after heat shock in pupae and adult moths as well, although the presence of an additional (56 kDa) protein was also apparent in the adults. The presence of 46 kDa and 28 kDa bands in addition to the 93 kDa band in the cuticular proteins immediately following heat shock was clearly discernible. The 70 kDa band did not show much changes in the cuticular proteins on heat shock. In contrast to the changes in protein profiles seen in tissues and haemolymph following heat shockin vivo, the heat treatment of isolated fat body or haemolymphin vitro resulted in protein degradation.     

Properties,synthesis, and accumulation of storage proteins in Pieris rapae L.

Two kinds of storage proteins (SP-1, SP-2) were confirmed in hemolymph and fat body of Pieris rapae during metamorphosis. Both proteins were present in high concentrations in the hemolymph during the last larval instar. Hemolymph concentrations of SP-1 and SP-2 dropped after pupation as the proteins were being deposited in fat bodies. SP-2 is present in a larger amount than SP-1. Detailed studies on storage proteins determined their properties, mode of synthesis, and accumulation in the fat body. SP-1 has a molecular weight of 500,000 and consists of one type of subunit (M_r 77,000), while SP-2 has a molecular weight of 460,000 and is composed of two types of subunits (M_r 80,000 and 69,000). The pl values of SP-1 and SP-2 were determined to be 6.97 and 7.06, respectively. Fat body cells from 1-day-old fifth instar larvae synthesized storage proteins in large amounts, whereas those from late prepupae exhibited high protein sequestration. Proteins taken up in fat body accumulated in dense granules during the pupal stage but sharply decreased at the adult stage. Morphological changes in the fat body tissues were observed during the larval-pupal transformation; the nuclei of fat body cells became irregularly shaped, and the boundaries between cells seemed to be obscure. Synthesis, storage, or degradation of storage proteins in fat body during development is closely associated with morphological changes in the tissues.     

Developmental changes of storage proteins and biliverdin-binding proteins in the haemolymph and fat body of the common cutworm,Spodoptera litura

The concentrations of three storage proteins (SL-1,SL-2 and SL-3, hexamers of 70-80kDa subunits) and two biliverdin-binding proteins (BP-A and BP-B, dimers of 165kDa) in the haemolymph and fat body during larval and pupal development of Spodoptera litura were determined by immunodiffusion tests using polyclonal antisera. SL-1 and SL-2 (methionine-rich) first appeared in the haemolymph of one-day-old sixth (final) instar larvae, prominently increased in the haemolymph during the later feeding period and were almost totally sequestered by the fat body after gut purge. SL-3 (arylphorin) was first detected in the haemolymph during the molting period to the final larval ecdysis, increased in concentration throughout the entire feeding period of the final larval instar and was partly sequestered by the fat body several hours later than the other storage proteins. BP-A showed nearly the same pattern in the haemolymph as SL-3: BP-B increased during feeding period and decreased during molting period and attained a maximum level during the penultimate larval instar, however its concentration decreased considerably and remained low in the final larval instar. BP-A was partly and BP-B was almost totally sequestered by the fat body 8 h after sequestration of SL-1 and SL-2, rendering the fat body blue in colour. These facts suggest an additional function of biliverdin-binding proteins as amino acid storage proteins and the results show a differential uptake mechanism for these proteins by the fat body.     

20-Hydroxyecdysone mediated activation of larval haemolymph protein uptake by fat body cells of Corcyra cephalonica (Insecta)

Evidence is presented here to show that 20-hydroxyecdysone is essential for the activation of the larval fat body for differential uptake of larval haemolymph proteins (LHPs). By using radiolabelled LHPs it is shown that the fat body cells of Corcyra cephalonica selectively incorporate LHPs during late-larval and prepupal development. Fluorographic analysis of the labelled fat body proteins from prepupal stage separated on sodium dodecyl-sulphate polyacrylamide gels suggests that the LHPs are sequestered without any degradation. Although, during the last larval instar the uptake of all the three LHPs (LHP 1, LHP 2 and LHP 3) by the fat body cells is very low, 20-hydroxyecdysone treatment of early, mid or late-last instars causes a significant increase in uptake of all the three LHPs. However, the response to hormone treatment was more pronounced in late-last instar when compared to early and mid-last instar.     

Effect of metamorphosis on the major hemolymph proteins of the silkworm

During the metamorphosis of the silkworm, Bombyx mori, three major hemolymph proteins (MHPs) (molecular weights 17,000, 25,000, 27,000) were detected and found to be distributed in the hemolymph and in the tissues of several organs, such as the fat body, midgut, ovary, testis, and even eggs. The MHPs in eggs gradually decreased and disappeared during embryogenesis. The formation, distribution, and utilization of MHPs in tissues other than the gonad, however, were not affected by sex. Radioisotope experiments in vivo revealed that the MHPs were synthesized at an early period of the fifth larval instar. The synthesis of at least two of them occurred in the fat body. MHPs in the hemolymph entered the tissues at the onset of the larval-pupal transformation. On the basis of their appearance, distribution, and depletion, the MHPs may be classified as reserve proteins which are synthesized in the larval stage and utilized later in the developmental stages.     

Immunological analysis of lipophorin in the haemolymph,ovaries, and testes of the fall webworm,Hyphantria cunea (Drury)

Lipophorin (LP) was purified from haemolymph in last instar larvae of Hyphantria cunea (Drury) by KBr density gradient ultracentrifugation and gel filtration. LP is composed of Apo-LP I and Apo-LP II with molecular weights of 230 kDa and 80 kDa, respectively. The level of haemolymph LP in early pupae was somewhat greater than in last instar larvae. In males, this LP concentration is maintained throughout pupal development, whereas the level of haemolymph LP decreases in female pupae beginning at day 7, coincident with the onset of vitellogenesis in the fall webworm. In both male and female adults, haemolymph LP concentrations were dramatically increased in comparison to their pre-adult levels. Actually, LP was found in the ovary by immunodiffusion, tandem-crossed immunoelectrophoresis, and Western blotting. Location of LP in the ovary was also traced by immunogold labelling. Also, LP appeared in small amounts in protein yolk bodies of the ovary at an early stage of vitellogenesis, when nurse cells are bigger than the oocyte, but in greater amounts at those stages when the oocyte is larger than nurse cells—that is, when vitellogenesis is actively taking place. This fact clearly reveals that LP is synthesized by fat body and released into the haemolymph, and then taken up by the growing ovary during vitellogenesis. Also, LP was detected in testes by immunological analysis. Western blotting showed that LP was present in testicular fluid but not in the peritoneal sheath and cysts. To test whether LP is also synthesized in testes, testes and fat body tissues were cultured in vitro, indicating that fat body synthsizes LP but testes do not. The result showed that the haemolymph LP itself is taken up into the testes. © 1994 Wiley-Liss, Inc.     

The fate of vicilins, 7S storage globulins, in larvae and adult Callosobruchus maculatus (Coleoptera: Chrysomelidae: Bruchinae)

The fate of vicilins ingested by Callosobruchus maculatus and the physiological importance of these proteins in larvae and adults were investigated. Vicilins were quantified by ELISA in the haemolymph and fat body during larval development (2nd to 4th instars), in pupae and adults, as well as in ovaries and eggs. Western blot analysis demonstrated that the majority of absorbed vicilins were degraded in the fat body. Tracing the fate of vicilins using FITC revealed that the FITC-vicilin complex was present inside cells of the fat body of the larvae and in the fat bodies of both male and female adult C. maculatus. Labelled vicilin was also detected in ovocytes and eggs. Based on the results presented here, we propose that following absorption, vicilins accumulate in the fat body, where they are partially degraded. These peptides are retained throughout the development of the insects and eventually are sequestered by the eggs. It is possible that accumulation in the eggs is a defensive strategy against pathogen attack as these peptides are known to have antimicrobial activity. Quantifications performed on internal organs from larvae of C. maculatus exposed to extremely dry seeds demonstrated that the vicilin concentration in the haemolymph and fat body was significantly higher when compared to larvae fed on control seeds. These results suggest that absorbed vicilins may also be involved in the survival of larvae in dry environments.     

Biosynthesis of major plasma proteins in the primary culture of fat body cells from the silkworm, Bombyx mori

Plasma proteins termed "SP1" and "30K proteins" are synthesized by the fat body cells of the silkworm, Bombyx mori, in a sex- and stage-specific manner during larval development. We successfully established a primary culture of the fat body cells in order to investigate the regulatory mechanisms of plasma protein gene expression. The primary cultures of fat body cells contained at least two cell types: small oval cells, and large spherical cells. The cells adhered to and migrated on the cultured dish after plating. By the 7th day of cultivation, the cells clustered to form fat body-like structures, which were maintained for at least 3 months. Plasma proteins were actively synthesized in the primary cultures of the fat body cells isolated from the final instar larvae only when the cells tightly adhered to and clustered on the cultured dish. Immunocytochemical analysis revealed that only 10-15% of the clustered cells synthesized plasma proteins in our culture system, indicating that the primary culture comprises heterogeneous cells that are morphologically and functionally distinct. The patterns of SP1 syntheses in primary cultures faithfully reproduced their sex-dependency in vivo.     

Immunocytochemical and electrophoretic studies on the localization of the major haemolymph proteins (ceratitins) inCeratitis capitata during development

Summary The developmental profile of the major haemolymph proteins (ceratitins) inCeratitis capitata was studied. Ceratitin concentration in the haemolymph decreases dramatically during the last days of pupal life, while the amounts of ceratitins in whole organism extracts remain unchanged. By electrophoretic, immunological and immunofluorescence techniques it was revealed that ceratitins are reabsorbed by the fat body and a fraction of them is deposited in the cuticle. The possible role of ceratitins is discussed.     

PROTEIN AND NUCLEIC ACID METABOLISM IN INSECT FAT BODY

1. The appearance of larval fat body as seen under the light or electron microscope depends on the nutritional state of the larva and on the stage of larval development at which the fat body is observed. 2. Early in the last larval instar the cells usually possess a well-developed endo-plasmic reticulum rich in ribosomes, numerous mitochondria, glycogen granules, a Golgi complex and fat droplets, while later in the instar the endoplasmic reticulum is much reduced and mitochondria are few, but glycogen and fat droplets are present in greater amount together with the appearance of large numbers of proteinaceous spheres. 3. Early in the last instar the fat body synthesizes proteins and exports them into the blood, while later in the instar proteins are sequestered from the blood into the fat body. 4. The rate of protein synthesis by the fat body is high in the early to mid part of the last instar, but then falls off rapidly to a low level, at which it remains until the larva pupates. In diapausing pupae, protein synthesis remains at this low level. 5. The similarity between the electrophoretic patterns of proteins from the fat body and those from the blood provides strong evidence that the fat body is the site of synthesis of many of the blood proteins. 6. Some of the blood proteins have been shown to possess enzymic properties, while others are thought to play a role in the transportation of various types of compounds. 7. Ecdysone and juvenile hormone both stimulate the rate of protein synthesis by larval fat body. Protein synthesis in fat body from diapausing pupae is stimulated after injury to the pupae. 8. The appearance of adult fat body and the amount of protein it contains is often closely linked with the nutritional and reproductive states of the insect. 9. An important role of the fat body in the adult female insect is the synthesis of yolk proteins, which are released into the blood and then taken up by the developing oocytes. This synthesis and uptake are under the control of hormones secreted by the corpora allata and by the median neurosecretory cells of the pars intercerebralis. 10. The RNA content of fat body in final-instar larvae is not constant throughout the instar. In some larvae it is at its highest level early in the instar, falling to a low level as the instar progresses, while in other larvae (e.g. Calliphora) the level of RNA in fat body does not decrease as the instar progresses. 11. In some dipterous insects the base composition of total RNA is DNA-like in that the guanine + cytosine content is low, accounting for 40 % of the bases. A similar composition is seen in rapidly labelled RNA isolated from insects of other orders (Coleoptera and Lepidoptera), but the base content of total RNA from these latter insects resembles ribosomal RNA from vertebrate tissues in that it has a high (ca. 60 %) guanine + cytosine content. 12. The RNA/DNA ratios in blowfly larval tissues are high compared with those found in any vertebrate tissue. 13. In larval fat body, RNA synthesis is low at the time of a moult, increases during the early and mid-instar period and subsequently falls during the latter part of the instar. During the pupal period, especially during pupal diapause, the rate of RNA synthesis is very low and then increases during the subsequent development of the pharate adult. Injury to diapausing pupae results in an increased rate of RNA synthesis in most of their tissues. 14. Ecdysone and juvenile hormone both stimulate RNA and DNA synthesis in larval and adult fat body and in other tissues, although there is evidence that in some tissues these two hormones may act antagonistically to each other. The insecticide DDT also has been shown to stimulate RNA synthesis in tissues of adult insects.     

Accumulation and degradation of three major yolk proteins in Drosophila melanogaster.

In contrast to previous findings, three major yolk proteins have been identified in the oocytes and eggs of Drosophila melanogaster. They are also present as major proteins in the haemolymph of mature females and in trace amounts in the haemolymph of young females; the male haemolymph lacked all three proteins. Female fat body contained the three proteins and, surprisingly, trace amounts were also present in the male fat body. The accumulation and degradation of the three yolk proteins by oocytes and embryos was asynchronous suggesting that independent controls may exist.